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COM20019I Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Datasheet
Product Features
New Features:
- Data Rates up to 312.5 Kbps - Programmable Reconfiguration Times
Eight, 256 Byte Pages Allow Four Pages TX and RX Plus Scratch-Pad Memory Next ID Readable Internal Clock Scaler for Adjusting Network Speed Operating Temperature Range of -40oC to +85oC Self-Reconfiguration Protocol Supports up to 255 Nodes Supports Various Network Topologies (Star, Tree, Bus...) CMOS, Single +5V Supply Duplicate Node ID Detection Powerful Diagnostics Receive All Packets Mode Flexible Media Interface:
- RS485 Differential Driver Interface For Low Cost, Low Power, High Reliability
28 Pin PLCC and 48 Pin TQFP Packages; Leadfree RoHS Compliant Packages also Available Ideal for Industrial/Factory/Building Automation and Transportation Applications Deterministic, (ANSI 878.1), Token Passing ARCNET Protocol Minimal Microcontroller and Media Interface Logic Required Flexible Interface For Use With All Microcontrollers or Microprocessors Automatically Detects Type of Microcontroller Interface 2Kx8 On-Chip Dual Port RAM Command Chaining for Packet Queuing Sequential Access to Internal RAM Software Programmable Node ID
ORDERING INFORMATION
Order Numbers:
COM20019ILJP for 28 pin PLCC package; COM20019I-DZD for 28 pin PLCC lead-free RoHS Compliant package COM20019I-HD for 48 pin TQFP package; COM20019I-HT for 48 pin TQFP lead-free RoHS Compliant package
SMSC COM20019I
Page 1
Rev. 09-25-07
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
80 ARKAY DRIVE, HAUPPAUGE, NY 11788 (631) 435-6000, FAX (631) 273-3123 Copyright (c) 2007 SMSC or its subsidiaries. All rights reserved. Circuit diagrams and other information relating to SMSC products are included as a means of illustrating typical applications. Consequently, complete information sufficient for construction purposes is not necessarily given. Although the information has been checked and is believed to be accurate, no responsibility is assumed for inaccuracies. SMSC reserves the right to make changes to specifications and product descriptions at any time without notice. Contact your local SMSC sales office to obtain the latest specifications before placing your product order. The provision of this information does not convey to the purchaser of the described semiconductor devices any licenses under any patent rights or other intellectual property rights of SMSC or others. All sales are expressly conditional on your agreement to the terms and conditions of the most recently dated version of SMSC's standard Terms of Sale Agreement dated before the date of your order (the "Terms of Sale Agreement"). The product may contain design defects or errors known as anomalies which may cause the product's functions to deviate from published specifications. Anomaly sheets are available upon request. SMSC products are not designed, intended, authorized or warranted for use in any life support or other application where product failure could cause or contribute to personal injury or severe property damage. Any and all such uses without prior written approval of an Officer of SMSC and further testing and/or modification will be fully at the risk of the customer. Copies of this document or other SMSC literature, as well as the Terms of Sale Agreement, may be obtained by visiting SMSC's website at http://www.smsc.com. SMSC is a registered trademark of Standard Microsystems Corporation ("SMSC"). Product names and company names are the trademarks of their respective holders. SMSC DISCLAIMS AND EXCLUDES ANY AND ALL WARRANTIES, INCLUDING WITHOUT LIMITATION ANY AND ALL IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND AGAINST INFRINGEMENT AND THE LIKE, AND ANY AND ALL WARRANTIES ARISING FROM ANY COURSE OF DEALING OR USAGE OF TRADE. IN NO EVENT SHALL SMSC BE LIABLE FOR ANY DIRECT, INCIDENTAL, INDIRECT, SPECIAL, PUNITIVE, OR CONSEQUENTIAL DAMAGES; OR FOR LOST DATA, PROFITS, SAVINGS OR REVENUES OF ANY KIND; REGARDLESS OF THE FORM OF ACTION, WHETHER BASED ON CONTRACT; TORT; NEGLIGENCE OF SMSC OR OTHERS; STRICT LIABILITY; BREACH OF WARRANTY; OR OTHERWISE; WHETHER OR NOT ANY REMEDY OF BUYER IS HELD TO HAVE FAILED OF ITS ESSENTIAL PURPOSE, AND WHETHER OR NOT SMSC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.
Rev. 09-25-07
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SMSC COM20019I
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
TABLE OF CONTENTS
Chapter 1 Chapter 2 Chapter 3 Chapter 4 GENERAL DESCRIPTION..................................................................................................... 5 PIN CONFIGURATIONS........................................................................................................ 6 DESCRIPTION OF PIN FUNCTIONS.................................................................................... 8 PROTOCOL DESCRIPTION ............................................................................................... 11
4.1 NETWORK PROTOCOL............................................................................................................................11 4.2 DATA RATES.............................................................................................................................................11 4.3 NETWORK RECONFIGURATION .............................................................................................................11 4.4 BROADCAST MESSAGES........................................................................................................................12 4.5 EXTENDED TIMEOUT FUNCTION ...........................................................................................................12 4.5.1 Response Time ...................................................................................................................................12 4.5.2 Idle Time .............................................................................................................................................12 4.5.3 Reconfiguration Time ..........................................................................................................................13 4.6 LINE PROTOCOL ......................................................................................................................................13 4.6.1 Invitations To Transmit........................................................................................................................13 4.6.2 Free Buffer Enquiries ..........................................................................................................................13 4.6.3 Data Packets.......................................................................................................................................13 4.6.4 Acknowledgements .............................................................................................................................14 4.6.5 Negative Acknowledgements ..............................................................................................................14
Chapter 5
SYSTEM DESCRIPTION ..................................................................................................... 15
5.1 MICROCONTROLLER INTERFACE..........................................................................................................15 5.1.1 High Speed CPU Bus Timing Support ................................................................................................18 5.2 TRANSMISSION MEDIA INTERFACE ......................................................................................................19 5.2.1 Backplane Configuration .....................................................................................................................19 5.2.2 Differential Driver Configuration ..........................................................................................................20 5.2.3 Programmable TXEN Polarity .............................................................................................................20
Chapter 6
FUNCTIONAL DESCRIPTION............................................................................................. 23
6.1 MICROSEQUENCER.................................................................................................................................23 6.2 INTERNAL REGISTERS............................................................................................................................24 6.2.1 Interrupt Mask Register (IMR) .............................................................................................................24 6.2.2 Data Register ......................................................................................................................................24 6.2.3 Tentative ID Register ..........................................................................................................................25 6.2.4 Node ID Register.................................................................................................................................25 6.2.5 Next ID Register..................................................................................................................................25 6.2.6 Status Register....................................................................................................................................25 6.2.7 Diagnostic Status Register ..................................................................................................................26 6.2.8 Command Register .............................................................................................................................26 6.2.9 Address Pointer Registers ..................................................................................................................26 6.2.10 Configuration Register.....................................................................................................................26 6.2.11 Sub-Address Register .....................................................................................................................26 6.2.12 Setup 1 Register..............................................................................................................................26 6.2.13 Setup 2 Register..............................................................................................................................27 6.3 INTERNAL RAM ........................................................................................................................................35 6.3.1 Sequential Access Memory.................................................................................................................35 6.3.2 Access Speed .....................................................................................................................................35 6.4 SOFTWARE INTERFACE..........................................................................................................................35 6.4.1 Selecting RAM Page Size ...................................................................................................................36 6.4.2 Transmit Sequence .............................................................................................................................37 6.4.3 Receive Sequence ..............................................................................................................................38 6.5 COMMAND CHAINING..............................................................................................................................39 6.5.1 Transmit Command Chaining .............................................................................................................40 6.5.2 Receive Command Chaining ..............................................................................................................40 6.6 RESET DETAILS .......................................................................................................................................41 6.6.1 Internal Reset Logic ............................................................................................................................41 6.7 INITIALIZATION SEQUENCE ....................................................................................................................41 6.7.1 Bus Determination...............................................................................................................................41 6.8 IMPROVED DIAGNOSTICS ......................................................................................................................42 6.8.1 Normal Results:...................................................................................................................................43
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
6.8.2 Abnormal Results:...............................................................................................................................43 6.9 OSCILLATOR ............................................................................................................................................43
Chapter 7
7.1 7.2
OPERATIONAL DESCRIPTION .......................................................................................... 45
MAXIMUM GUARANTEED RATINGS*......................................................................................................45 DC ELECTRICAL CHARACTERISTICS ....................................................................................................45
Chapter 8 Chapter 9
9.1 9.2 10.1 10.2
TIMING DIAGRAMS............................................................................................................. 48 Package Outlines ................................................................................................................. 60
28 Pin PLCC Package Outline and Parameters.........................................................................................60 48 Pin TQFP Package Outline and Parameters.........................................................................................61
Chapter 10 Chapter 11
APPENDIX A........................................................................................................................ 62
NOSYNC Bit ...........................................................................................................................................62 EF Bit......................................................................................................................................................62
APPENDIX B:....................................................................................................................... 65
LIST OF FIGURES
Figure 3.1 - COM20019I OPERATION ........................................................................................................................10 Figure 5.1 - MULTIPLEXED, 8051-LIKE BUS INTERFACE WITH RS-485 INTERFACE ............................................16 Figure 5.2 - NON-MULTIPLEXED, 6801-LIKE BUS INTERFACE WITH RS-485 INTERFACE...................................17 Figure 5.3 - HIGH SPEED CPU BUS TIMING - INTEL CPU MODE............................................................................18 Figure 5.4 - COM20019I NETWORK USING RS-485 DIFFERENTIAL TRANSCEIVERS...........................................20 Figure 5.5 - INTERNAL BLOCK DIAGRAM ..................................................................................................................21 Figure 6.1 - SEQUENTIAL ACCESS OPERATION ......................................................................................................35 Figure 6.2 - RAM BUFFER PACKET CONFIGURATION .............................................................................................37 Figure 6.3 - COMMAND CHAINING STATUS REGISTER QUEUE..............................................................................39 Figure 7.1 - AC MEASUREMENTS ..............................................................................................................................47 Figure 8.1 - MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE .................................................48 Figure 8.2 - MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE .................................................49 Figure 8.3 - MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; WRITE CYCLE................................................50 Figure 8.4 - MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; WRITE CYCLE................................................51 Figure 8.5 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE ........................................52 Figure 8.6 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE ........................................53 Figure 8.7 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE ........................................54 Figure 8.8 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE ........................................55 Figure 8.9 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; WRITE CYCLE ......................................56 Figure 8.10 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; WRITE CYCLE ....................................57 Figure 8.11 - BACKPLANE MODE TRANSMIT OR RECEIVE TIMING.......................................................................58 Figure 8.12 - TTL INPUT TIMING ON XTAL1 PIN .......................................................................................................59 Figure 8.13 - RESET AND INTERRUPT TIMING ........................................................................................................59 Figure 10.1 - EFFECT OF THE EB BIT ON THE TA/RI BIT ........................................................................................63 Figure 11.1 - EXAMPLE OF INTERFACE CIRCUIT DIAGRAM TO ISA BUS .............................................................65
LIST OF TABLES
Table 5.1 - Typical Media .............................................................................................................................................22 Table 6.1 - Read Register Summary.............................................................................................................................23 Table 6.2 - Write Register Summary ............................................................................................................................24 Table 6.3 - Status Register ...........................................................................................................................................27 Table 6.4 - Diagnostic Status Register..........................................................................................................................28 Table 6.5 - Command Register.....................................................................................................................................29 Table 6.6 - Address Pointer High Register ....................................................................................................................30 Table 6.7 - Address Pointer Low Register.....................................................................................................................30 Table 6.8 - Sub Address Register .................................................................................................................................31 Table 6.9 - Configuration Register ................................................................................................................................31 Table 6.10 - Setup 1 Register .......................................................................................................................................32 Table 6.11 - Setup 2 Register .......................................................................................................................................33
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SMSC COM20019I
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 1
GENERAL DESCRIPTION
SMSC's COM20019I is a member of the family of Embedded ARCNET Controllers from Standard Microsystems Corporation. The device is a general purpose communications controller for networking microcontrollers and intelligent peripherals in industrial, automotive, and embedded control environments using an ARCNET protocol engine. The flexible microcontroller and media interfaces, eight- page message support, and extended temperature range of the COM20019I make it the only true network controller optimized for use in industrial, embedded, and automotive applications. Using an ARCNET protocol engine is the ideal solution for embedded control applications because it provides a deterministic tokenpassing protocol, a highly reliable and proven networking scheme, and a data rate of up to 312.5 Kbps when using the COM20019I. A token-passing protocol provides predictable response times because each network event occurs within a predetermined time interval, based upon the number of nodes on the network. The deterministic nature of ARCNET is essential in real time applications. The integration of the 2Kx8 RAM buffer on-chip, the Command Chaining feature, the maximum data rate, and the internal diagnostics make the COM20019I the highest performance embedded communications device available. With only one COM20019I and one microcontroller, a complete communications node may be implemented.
For more details on the ARCNET protocol engine and traditional dipulse signaling schemes, please refer to the ARCNET Local Area Network Standard, available from Standard Microsystems Corporation or the ARCNET Designer's Handbook, available from Datapoint Corporation. For more detailed information on cabling options including RS485, transformer-coupled RS-485 and Fiber Optic interfaces, please refer to the following technical note which is available from Standard Microsystems Corporation: Technical Note 7-5 - Cabling Guidelines for the COM20020 ULANC.
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 2
A0/nMUX
PIN CONFIGURATIONS
nRESET IN nTXEN nINTR
VDD nRD/nDS nWR/DIR
1 2 3 4 5 6 7 8 9 10 11 12
A1 A2/ALE AD0 AD1 AD2 D3 D4 D5 D6 D7 VSS
23 22 21 20 19 18 17 16 15 14 13
25 nWR/DIR 26 27 28 1 2 3 4 5
24
23
22
VSS
nCS
24
21
RXIN
20
nPULSE2
19 18 17 16 15 14 13 12 nPULSE 1 XTAL2 XTAL1 VDD VSS N/C D7
nCS nINTR nRESET IN nTXEN RXIN nPULSE2
nRD/nDS VDD A0/nMUX A1 A2/ALE
nPULSE1
AD0
XTAL2 XTAL1
6
7
8
9
10
11
D3
AD1
AD2
Packages: 28-Pin PLCC 28-Pin PLCC Package: 24-Pin DIP or Ordering Information: COM20019 I P PACKAGE TYPE: P = Plastic, LJP = PLCC TEMP RANGE: (Blank) = Commercial: 0C to +70C I = Industrial: -40C to +85C
DEVICE TYPE: 20019 = Universal Local Area Network Controller (with 2K x 8 RAM)
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VSS
D4
D5
D6
SMSC COM20019I
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
N/C N/C A2/ALE A1 A0/nMUX VDD N/C 48 47 46 45 44 43 42 AD0 AD1 N/C AD2 N/C VSS D3 VDD D4 D5 VSS D6 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
41 40 39 38 37 36 35 34
VSS N/C nRD/nDS VDD nWR/DIR
nCS VDD nINTR N/C VDD nRESET VSS nTXEN RXIN N/C BUSTMG nPULSE2
COM20019I 48 PIN TQFP
33 32 31 30 29 28 27 26 25
SMSC COM20019I
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VDD XTAL1 XTAL2 VSS nPULSE1
D7 N/C N/C N/C N/C VSS N/C
20 21 22 23 24
Rev. 09-25-07
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 3
PLCC PIN NO. 1-3
DESCRIPTION OF PIN FUNCTIONS
NAME SYMBOL DESCRIPTION
4-6,8-12
27
26
23 24
25
MICROCONTROLLER INTERFACE A0/nMUX, Input. On a non-multiplexed mode, A0-A2 are address input bits. (A0 is the LSB) On a A1,A2/ALE multiplexed address/data bus, nMUX tied Low, A1 is left open, and ALE is tied to the Address Latch Enable signal. A1 is connected to an internal pull-up resistor. Data 0-7 AD0-AD2, D3- Input/Output. On a non-multiplexed bus, these D7 signals are used as the data lines for the device. On a multiplexed address/data bus, AD0-AD2 act as the address lines (latched by ALE) and as the low data lines for the device. D3-D7 are always used for data only. These signals are connected to internal pull-up resistors. nRead/nData nRD/nDS Input. On a 68XX-like bus, nDS is an active low signal issued by the microcontroller as the Strobe data strobe signal to strobe the data onto the bus. On a 80XX-like bus, nRD is an active low signal issued by the microcontroller to indicate a read operation. nWrite/ nWR/DIR Input. On a 68XX-like bus, DIR is issued by the microcontroller as the Read/nWrite signal Direction to determine the direction of data transfer. In this case, a logic "1" selects a read operation, while a logic "0" selects a write operation. In this case, data is actually strobed by the nDS signal. On an 80XX-like bus, nWR is an active low signal issued by the microcontroller to indicate a write operation. In this case, a logic "0" on this pin, when the COM20019I is accessed, enables data from the data bus to be written to the device. nReset in nRESET Input. This active low signal executes a hardware reset. nInterrupt nINTR Output. This active low signal is generated by the COM20019I when an enabled interrupt condition occurs. nChip Select nCS Input. This active low signal selects the COM20019I for an access. Address 0-2
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SMSC COM20019I
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
PLCC PIN NO. 19,18
NAME
SYMBOL
DESCRIPTION
nPulse 2, nPulse 1
20 21
Receive In nTransmit nEnable
16,17
Crystal Oscillator
15,28 7,14,22
Power Supply Ground
TRANSMISSION MEDIA INTERFACE nPULSE2, Output (nPULSE1), Input/Output (nPULSE2). In Normal Mode, these active low signals carry nPULSE1 the transmit data information, encoded in pulse format, as DIPULSE waveform. When the device is in Backplane Mode, the nPULSE1 signal driver is programmable (push/pull or open-drain), while the nPULSE2 signal provides a clock with frequency of double the data rate. nPULSE1 is connected to a weak internal pull-up resistor on the open/drain driver in backplane mode. The COM20019I does not support the Normal Mode. Use only in the Backplane Mode. RXIN Input. This signal carries the receive data information from the line transceiver. nTXEN Output. This signal is used prior to the Powerup to enable the line drivers for transmission. The polarity of the signal is programmable through the nPULSE2 pin. nPULSE2 floating before Power-up: nTXEN active low (Default option) nPULSE2 grounded before Power-up: nTXEN active high (This option is only available in Backplane Mode) XTAL1, An external crystal should be connected to these pins. Oscillation frequency range is from XTAL2 10 to 20 MHz. If an external TTL clock is used instead, it must be connected to XTAL1 with a 390 pull-up resistor, and XTAL2 should be left floating. VDD +5 Volt Power Supply pin. VSS Ground pin.
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Power On Reconfigure Timer has Timed Out Send Reconfigure Burst
Read Node ID
Write ID to RAM Buffer 1 Set NID=ID
Start Reconfiguration Timer (6.72 S)*
Y
Invitation to Transmit to this ID?
N
N TA?
Y
Y
Free Buffer Enquiry to this ID? N
N Y Y N Write SID to Buffer N
Transmit NAK Transmit ACK N
Y RI?
SOH?
RI?
Broadcast? Y Send Packet
Transmit Free Buffer Enquiry N Y ACK? Y N
No Activity for 656 uS? Y Broadcast Enabled? Y N Set NID=ID Start Timer: T=(255-ID) x 1.168 mS Activity On Line? N Y
N
No Activity for 597.6 us? N
Y
DID =0? N
Y
Was Packet Broadcast? N No Activity Y for 597.6 us? N N Y
Y
NAK? 1
Set TA
DID =ID? N Y Write Buffer with Packet
Set TA
Pass the Token No Activity for 597.6 us? CRC OK? Y LENGTH N OK? Y DID =0? N DID =ID? Y SEND ACK N Y Set RI N N
Increment NID Set TMA
Y
N
T=0? Y
ACK?
- ID refers to the identification number of the ID assigned to this node. - NID refers to the next identification number that receives the token after this ID passes it. - SID refers to the source identification. - DID refers to the destination identification. - SOH refers to the start of header character; preceeds all data packets. * Reconfig timer is programmable via setup2 register bits 1, 0. Note - All time values are valid for 312.5 Kbps.
Figure 3.1 - COM20019I OPERATION
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SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 4
4.1
PROTOCOL DESCRIPTION
NETWORK PROTOCOL
Communication on the network is based on a token passing protocol. Establishment of the network configuration and management of the network protocol are handled entirely by the COM20019I's internal microcoded sequencer. A processor or intelligent peripheral transmits data by simply loading a data packet and its destination ID into the COM20019I's internal RAM buffer, and issuing a command to enable the transmitter. When the COM20019I next receives the token, it verifies that the receiving node is ready by first transmitting a FREE BUFFER ENQUIRY message. If the receiving node transmits an ACKnowledge message, the data packet is transmitted followed by a 16-bit CRC. If the receiving node cannot accept the packet (typically its receiver is inhibited), it transmits a Negative AcKnowledge message and the transmitter passes the token. Once it has been established that the receiving node can accept the packet and transmission is complete, the receiving node verifies the packet. If the packet is received successfully, the receiving node transmits an ACKnowledge message (or nothing if it is not received successfully) allowing the transmitter to set the appropriate status bits to indicate successful or unsuccessful delivery of the packet. An interrupt mask permits the COM20019I to generate an interrupt to the processor when selected status bits become true. Figure 3.1 - COM20019I OPERATION is a flow chart illustrating the internal operation of the COM20019I connected to a 20 MHz crystal oscillator.
4.2
DATA RATES
The COM20019I is capable of supporting data rates from 156.25 Kbps to 312.5 Kbps. The following protocol description assumes a 312.5 Kbps data rate. For slower data rates, an internal clock divider scales down the clock frequency. Thus all timeout values are scaled as shown in the following table: Example: IDLE LINE Timeout @ 312.5 Kbps = 656 s. IDLE LINE Timeout for 156.2 Kbps is 656 s * 2 = 1.3 ms INTERNAL CLOCK FREQUENCY 20 MHz CLOCK PRESCALER Div. by 64 Div. by 128 DATA RATE 312.5 Kbps 156.25 Kbps TIMEOUT SCALING FACTOR (MULTIPLY BY) 1 2
4.3
NETWORK RECONFIGURATION
A significant advantage of the COM20019I is its ability to adapt to changes on the network. Whenever a new node is activated or deactivated, a NETWORK RECONFIGURATION is performed. When a new COM20019I is turned on (creating a new active node on the network), or if the COM20019I has not received an INVITATION TO TRANSMIT for 6.72S, or if a software reset occurs, the COM20019I causes a NETWORK RECONFIGURATION by sending a RECONFIGURE BURST consisting of eight marks and one space repeated 765 times. The purpose of this burst is to terminate all activity on the network. Since this burst is longer than any other type of transmission, the burst will interfere with the next INVITATION TO TRANSMIT, destroy the token and keep any other node from assuming control of the line. When any COM20019I senses an idle line for greater than 656S, which occurs only when the token Is lost, each COM20019I starts an internal timeout equal to 1.168mS times the quantity 255 minus its own ID. The COM20019I starts network reconfiguration by sending an invitation to transmit first to itself and then to all other nodes by decrementing the destination Node ID. If the timeout expires with no line
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
activity, the COM20019I starts sending INVITATION TO TRANSMIT with the Destination ID (DID) equal to the currently stored NID. Within a given network, only one COM20019I will timeout (the one with the highest ID number). After sending the INVITATION TO TRANSMIT, the COM20019I waits for activity on the line. If there is no activity for 597.6 S, the COM20019I increments the NID value and transmits another INVITATION TO TRANSMIT using the NID equal to the DID. If activity appears before the 597.6 S timeout expires, the COM20019I releases control of the line. During NETWORK RECONFIGURATION, INVITATIONS TO TRANSMIT are sent to all NIDs (1-255). Each COM20019I on the network will finally have saved a NID value equal to the ID of the COM20019I that it released control to. At this point, control is passed directly from one node to the next with no wasted INVITATIONS TO TRANSMIT being sent to ID's not on the network, until the next NETWORK RECONFIGURATION occurs. When a node is powered off, the previous node attempts to pass the token to it by issuing an INVITATION TO TRANSMIT. Since this node does not respond, the previous node times out and transmits another INVITATION TO TRANSMIT to an incremented ID and eventually a response will be received. The NETWORK RECONFIGURATION time depends on the number of nodes in the network, the propagation delay between nodes, and the highest ID number on the network, but is typically within the range of 192 to 488 mS.
4.4
BROADCAST MESSAGES
Broadcasting gives a particular node the ability to transmit a data packet to all nodes on the network simultaneously. ID zero is reserved for this feature and no node on the network can be assigned ID zero. To broadcast a message, the transmitting node's processor simply loads the RAM buffer with the data packet and sets the DID equal to zero. Figure 4 illustrates the position of each byte in the packet with the DID residing at address 0X01 or 1 Hex of the current page selected in the "Enable Transmit from Page fnn" command. Each individual node has the ability to ignore broadcast messages by setting the most significant bit of the "Enable Receive to Page fnn" command to a logic "0".
4.5
EXTENDED TIMEOUT FUNCTION
There are three timeouts associated with the COM20019I operation. The values of these timeouts are controlled by bits 3 and 4 of the Configuration Register and bit 5 of the Setup 1 Register.
4.5.1
Response Time
The Response Time determines the maximum propagation delay allowed between any two nodes, and should be chosen to be larger than the round trip propagation delay between the two furthest nodes on the network plus the maximum turn around time (the time it takes a particular COM20019I to start sending a message in response to a received message) which is approximately 101.6 S. The round trip propagation delay is a function of the transmission media and network topology. For a typical system using RG62 coax in a baseband system, a one way cable propagation delay of 248 S translates to a distance of about 32 miles. The flow chart in Figure 3.1 uses a value of 597.6 S (248 + 248 + 101.6) to determine if any node will respond.
4.5.2
Idle Time
The Idle Time is associated with a NETWORK RECONFIGURATION. Figure 3.1 illustrates that during a NETWORK RECONFIGURATION one node will continually transmit INVITATIONS TO TRANSMIT until it encounters an active node. All other nodes on the network must distinguish between this operation and an entirely idle line. During NETWORK RECONFIGURATION, activity will appear on the line every 656 S.
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DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
This 656 S is equal to the Response Time of 597.6 S plus the time it takes the COM20019I to start retransmitting another message (usually another INVITATION TO TRANSMIT).
4.5.3
Reconfiguration Time
If any node does not receive the token within the Reconfiguration Time, the node will initiate a NETWORK RECONFIGURATION. The ET2 and ET1 bits of the Configuration Register allow the network to operate over longer distances than the 32 miles stated earlier. Thelogic levels on these bits control the maximum distances over which the COM20019I can operate by controlling the three timeout values described above. For proper network operation, all COM20019I's connected to the same network must have the same Response Time, Idle Time, and Reconfiguration Time.
4.6
LINE PROTOCOL
The ARCNET line protocol is considered isochronous because each byte is preceded by a start interval and ended with a stop interval. Unlike asynchronous protocols, there is a constant amount of time separating each data byte. On a 312.5 Kbps network, each byte takes exactly 11 clock intervals of 3.2 S each. As a result, one byte is transmitted every 35.2 S and the time to transmit a message can be precisely determined. The line idles in a spacing (logic "0") condition. A logic "0" is defined as no line activity and a logic "1" is defined as a negative pulse of 1.6 S duration. A transmission starts with an ALERT BURST consisting of 6 unit intervals of mark (logic "1"). Eight bit data characters are then sent, with each character preceded by 2 unit intervals of mark and one unit interval of space. Five types of transmission can be performed as described below:
4.6.1
Invitations To Transmit
An Invitation To Transmit is used to pass the token from one node to another and is sent by the following sequence: An ALERT BURST An EOT (End Of Transmission: ASCII code 04H) Two (repeated) DID (Destination ID) characters ALERT BURST EOT DID DID
4.6.2
Free Buffer Enquiries
A Free Buffer Enquiry is used to ask another node if it is able to accept a packet of data. It is sent by the following sequence: An ALERT BURST An ENQ (ENQuiry: ASCII code 85H) Two (repeated) DID (Destination ID) characters ALERT BURST ENQ DID DID
4.6.3
Data Packets
A Data Packet consists of the actual data being sent to another node. It is sent by the following sequence:
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An ALERT BURST An SOH (Start Of Header--ASCII code 01H) An SID (Source ID) character Two (repeated) DID (Destination ID) characters A single COUNT character which is the 2's complement of the number of data bytes to follow if a short packet is sent, or 00H followed by a COUNT character if a long packet is sent. N data bytes where COUNT = 256-N (or 512-N for a long packet) Two CRC (Cyclic Redundancy Check) characters. The CRC polynomial used is: X16 + X15 + X2 + 1.
ALERT BURST
SOH
SID
DID
DID
COUNT
data
data
CRC
CRC
4.6.4
Acknowledgements
An Acknowledgement is used to acknowledge reception of a packet or as an affirmative response to FREE BUFFER ENQUIRIES and is sent by the following sequence: An ALERT BURST An ACK (ACKnowledgement--ASCII code 86H) character ALERT BURST ACK
4.6.5
Negative Acknowledgements
A Negative Acknowledgement is used as a negative response to FREE BUFFER ENQUIRIES and is sent by the following sequence: An ALERT BURST A NAK (Negative Acknowledgement--ASCII code 15H) character ALERT BURST NAK
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Chapter 5
5.1
SYSTEM DESCRIPTION
MICROCONTROLLER INTERFACE
The top halves of Figure 5.1 and Figure 5.2 illustrate typical COM20019I interfaces to the microcontrollers. The interfaces consist of a 8-bit data bus, an address bus and a control bus. In order to support a wide range of microcontrollers without requiring glue logic and without increasing the number of pins, the COM20019I automatically detects and adapts to the type of microcontroller being used. Upon hardware reset, the COM20019I first determines whether the read and write control signals are separate READ and WRITE signals (like the 80XX) or DIRECTION and DATA STROBE (like the 68XX). To determine the type of control signals, the device requires the software to execute at least one write access to external memory before attempting to access the COM20019I. The device defaults to 80XX-like signals. Once the type of control signals are determined, the COM20019I remains in this interface mode until the next hardware reset occurs. The second determination the COM20019I makes is whether the bus is multiplexed or nonmultiplexed. To determine the type of bus, the device requires the software to write to an odd memory location followed by a read from an odd location before attempting to access the COM20019I. The signal on the A0 pin during the odd location access tells the COM20019I the type of bus. Since multiplexed operation requires A0 to be active low, activity on the A0 line tells the COM20019I that the bus is nonmultiplexed. The device defaults to multiplexed operation. Both determinations may be made simultaneously by performing a WRITE followed by a READ operation to an odd location within the COM20019I Address space 20020D registers. Once the type of bus is determined, the COM20019I remains in this interface mode until hardware reset occurs. Whenever nCS and nRD are activated, the preset determinations are assumed as final and will not be changed until hardware reset. Refer to Description of Pin Functions section for details on the related signals. All accesses to the internal RAM and the internal registers are controlled by the COM20019I. The internal RAM is accessed via a pointer-based scheme (refer to the Sequential Access Memory section), and the internal registers are accessed via direct addressing. Many peripherals are not fast enough to take advantage of high-speed microcontrollers. Since microcontrollers do not typically have READY inputs, standard peripherals cannot extend cycles to extend the access time. The access time of the COM20019I, on the other hand, is so fast that it does not need to limit the speed of the microcontroller. The COM20019I is designed to be flexible so that it is independent of the microcontroller speed. The COM20019I provides for no wait state arbitration via direct addressing to its internal registers and a pointer based addressing scheme to access its internal RAM. The pointer may be used in auto-increment mode for typical sequential buffer emptying or loading, or it can be taken out of auto-increment mode to perform random accesses to the RAM. The data within the RAM is accessed through the data register. Data being read is prefetched from memory and placed into the data register for the microcontroller to read. It is important to notice that only by writing a new address pointer (writing to an address pointer low), one obtains the contents of COM20019I internal RAM. Performing only read from the Data Register does not load new data from the internal RAM. During a write operation, the data is stored in the data register and then written into memory. Whenever the pointer is loaded for reads with a new value, data is immediately prefetched to prepare for the first read operation.
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
XTAL1 XTAL2 AD0-AD7 ALE A15 RESET nRD nWR nINT1
COM20019I
AD0-AD2, D3-D7 A2/BALE nCS nRESET nRD/nDS nWR/DIR nINTR nTXEN nPULSE1 nPULSE2 GND Differential Driver Configuration 75176B or Equiv. RXIN
8051
A0/nMUX XTAL1 XTAL2
* Media Interface may be replaced with Figure A or B.
27 pF
20 MHz XTAL
27 pF
+5V
2
RXIN
+5V
RXIN
6 7
Receiver HFD3212-002
100 Ohm TXEN nPULSE1 nPULSE2 GND nPULSE1 +5V
2 6 7 Transmitter 3 HFE4211-014
2 Fiber Interface (ST Connectors)
BACKPLANE CONFIGURATION
NOTE: COM20019 must be in backplane mode
FIGURE A
FIGURE B
Figure 5.1 - MULTIPLEXED, 8051-LIKE BUS INTERFACE WITH RS-485 INTERFACE
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XTAL1 XTAL2 D0-D7 A0 A1 A2 A7 nRES nIOS R/nW nIRQ1 D0-D7 A0/nMU A1 A2/BAL nCS nRESE nRD/nD nWR/nDI nINTR
COM20019I
RXIN 75176B or Equiv.
TXEN nPULSE nPULSE GND
Differential Configuratio * Media may be with Figure A or 27 pF
6801
XTAL1 XTAL2
27 pF
20MHz XTAL
Figure 5.2 - NON-MULTIPLEXED, 6801-LIKE BUS INTERFACE WITH RS-485 INTERFACE
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5.1.1
High Speed CPU Bus Timing Support
High speed CPU bus support was added to the COM20019I. The reasoning behind this is as follows: With the Host interface in Non-multiplexed Bus mode, I/O address and Chip Select signals must be stable before the read signal is active and remain after the read signal is inactive. But the High Speed CPU bus timing doesn't adhere to these timings. For example, a RISC type single chip microcontroller (like the HITACHI SH-1 series) changes I/O address at the same time as the read signal. Therefore, several external logic ICs would be required to connect to this microcontroller. In addition, the Diagnostic Status (DIAG) register is cleared automatically by reading itself. The internal DIAG register read signal is generated by decoding the Address (A2-A0), Chip Select (nCS) and Read (nRD) signals. The decoder will generate a noise spike at the above tight timing. The DIAG register is cleared by the spike signal without reading itself. This is unexpected operation. Reading the internal RAM and Next Id Register have the same mechanism as reading the DIAG register. Therefore, the address decode and host interface mode blocks were modified to fit the above CPU interface to support high speed CPU bus timing. In Intel CPU mode (nRD, nWR mode), 3 bit I/O address (A2-A0) and Chip Select (nCS) are sampled internally by Flip-Flops on the falling edge of the internal delayed nRD signal. The internal real read signal is the more delayed nRD signal. But the rising edge of nRD doesn't delay. By this modification, the internal real address and Chip Select are stable while the internal real read signal is active. Refer to Figure 5.3 below.
A2-A0, nCS
VALID
nRD
Delayed nRD (nRD1)
Sampled A2-A0, nCS More delayed nRD (nRD2)
VALID
Figure 5.3 - HIGH SPEED CPU BUS TIMING - INTEL CPU MODE The I/O address and Chip Select signals, which are supplied to the data output logic, are not sampled. Also, the nRD signal is not delayed, because the above sampling and delaying paths decrease the data access time of the read cycle. The above sampling and delaying signals are supplied to the Read Pulse Generation logic which generates the clearing pulse for the Diagnostic register and generates the starting pulse of the RAM Arbitration. Typical delay time between nRD and nRD1 is around 15nS and between nRD1 and nRD2 is around 10nS. Longer pulse widths are needed due to these delays on nRD signal. However, the CPU can insert some wait cycles to extend the width without any impact on performance. The RBUSTMG bit was added to Disable/Enable the High Speed CPU Read function. It is defined as: RBUSTMG=0, Disabled (Default); RBUSTMG=1, Enabled.
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In the MOTOROLA CPU mode (DIR, nDS mode), the same modifications apply. RBUSTMG BIT 0 1 BUS TIMING MODE Normal Speed CPU Read and Write High Speed CPU Read and Normal Speed CPU Write
5.2
TRANSMISSION MEDIA INTERFACE
The bottom halves of Figures 2 and 3 illustrate the COM20019I interface to the transmission media used to connect the node to the network. Table 1 lists different types of cable which are suitable for ARCNET applications. (Refer to Note 5.1) The user may interface to the cable of choice in one of three ways:
Note 5.1
Please refer to TN7-5 - Cabling Guidelines for the COM20020 ULANC, available from SMSC, for recommended cabling distance, termination, and node count for ARCNET nodes.
5.2.1
Backplane Configuration
The Backplane Open Drain Configuration is recommended for cost-sensitive, short-distance applications like backplanes and instrumentation. This mode is advantageous because it saves components, cost, and power. Since the Backplane Configuration encodes data differently than the traditional Hybrid Configuration, nodes utilizing the Backplane Configuration cannot communicate directly with nodes utilizing the Traditional Hybrid Configuration. The Backplane Configuration does not isolate the node from the media nor protects it from Common Mode noise, but Common Mode Noise is less of a problem in short distances. The COM20019I supplies a programmable output driver for Backplane Mode operation. Apush/pull or open drain driver can be selected by programming the P1MODE bit of the Setup 1 Register (see register descriptions for details). The COM20019I defaults to an open drain output. The Backplane Configuration provides for direct connection between the COM20019I and the media. Only one pull-up resistor (in open drain configuration of the output driver) is required somewhere on the media (not on each individual node). The nPULSE1 signal, in this mode, is an open drain or push/pull driver and is used to directly drive the media. It issues a 1.6S negative pulse to transmit a logic "1". Note that when used in the open-drain mode, the COM20019I does not have a fail/safe input on the RXIN pin. The nPULSE1 signal actually contains a weak pull-up resistor. This pull-up should not take the place of the resistor required on the media for open drain mode.
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RT +VCC +VCC RBIAS 75176B or Equiv. RBIAS +VCC RBIAS
RT
COM20019I
COM20019I
COM20019I
Figure 5.4 - COM20019I NETWORK USING RS-485 DIFFERENTIAL TRANSCEIVERS In typical applications, the serial backplane is terminated at both ends and a bias is provided by the external pull-up resistor. The RXIN signal is directly connected to the cable via an internal Schmitt trigger. A negative pulse on this input indicates a logic "1". Lack of pulse indicates a logic "0". For typical single-ended backplane applications, RXIN is connected to nPULSE1 to make the serial backplane data line. A ground line (from the coax or twisted pair) should run in parallel with the signal. For applications requiring different treatment of the receive signal (like filtering or squelching), nPULSE1 and RXIN remain as independent pins. External differential drivers/receivers for increased range and common mode noise rejection, for example, would require the signals to be independent of one another. When the device is in Backplane Mode, the clock provided by the nPULSE2 signal may be used for encoding the data into a different encoding scheme or other synchronous operations needed on the serial data stream.
5.2.2
Differential Driver Configuration
The Differential Driver Configuration is a special case of the Backplane Mode. It is a dc coupled configuration recommended for applications like car-area networks or other cost-sensitive applications which do not require direct compatibility with existing ARCNET nodes and do not require isolation. The Differential Driver Configuration cannot communicate directly with nodes utilizing the Traditional Hybrid Configuration. Like the Backplane Configuration, the Differential Driver Configuration does not isolate the node from the media. The Differential Driver interface includes a RS485 Driver/Receiver to transfer the data between the cable and the COM20019I. The nPULSE1 signal transmits the data, provided the Transmit Enable signal is active. The nPULSE1 signal issues a 1.6S negative pulse to transmit a logic "1". Lack of pulse indicates a logic "0". The RXIN signal receives the data, the transmitter portion of the COM20019I is disabled during reset and the nPULSE1, nPULSE2 and nTXEN pins are inactive.
5.2.3
Programmable TXEN Polarity
To accommodate transceivers with active high ENABLE pins, the COM20019I contains a programmable TXEN output. To program the TXEN pin for an active high pulse, the nPULSE2 pin should be connected to ground. To retain the normal active low polarity, nPULSE2 should be left open. The polarity determination is made at power on reset and is valid only for Backplane Mode operation. The nPULSE2 pin should remain grounded at all times if an active high polarity is desired.
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A0/nMUX A1 A2/BALE
ADDRESS DECODING CIRCUITRY
2K x 8 RAM ADDITIONAL REGISTERS
AD0-AD2, D3-D7 STATUS/ COMMAND REGISTER
nINTR
nRESET
RESET LOGIC
MICROSEQUENCER AND WORKING REGISTERS
TX/RX LOGIC
nPULSE1 nPULSE2 nTXEN RXIN
OSCILLATOR nRD/nDS nWR/DIR nCS BUS ARBITRATION CIRCUITRY
XTAL1 XTAL2
RECONFIGURATION TIMER
NODE ID LOGIC
Figure 5.5 - INTERNAL BLOCK DIAGRAM
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Table 5.1 - Typical Media CABLE TYPE RG-62 Belden #86262 RG-59/U Belden #89108 RG-11/U Belden #89108 IBM Type 1 (See Note 5.2) Belden #89688 IBM Type 3 (See Note 5.2) Telephone Twisted Pair Belden #1155A COMCODE 26 AWG Twisted Pair Part #105-064-703 Note 5.2 Note: NOMINAL IMPEDANCE 93 75 75 150 100 ATTENUATION PER 1000 FT. AT 5 MHZ 5.5dB 7.0dB 5.5dB 7.0dB 17.9dB
105
16.0dB
Non-plenum-rated cables of this type are also available. For more detailed information on Cabling options including RS-485, transformer-coupled RS-485 and Fiber Optic interfaces, please refer to TN7-5 - Cabling Guidelines for the COM20020 ULANC, available from Standard Microsystems Corporation.
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Chapter 6
6.1
FUNCTIONAL DESCRIPTION
MICROSEQUENCER
The COM20019I contains an internal microsequencer which performs all of the control operations necessary to carry out the ARCNET protocol. It consists of a clock generator, a 544 x 8 ROM, a program counter, two instruction registers, an instruction decoder, a no-op generator, jump logic, and reconfiguration logic. The COM20019I derives a 625 kHz and a 312.5 kHz clock from the output clock of the Clock Multiplier. These clocks provide the rate at which the instructions are executed within the COM20019I. The 625 kHz clock is the rate at which the program counter operates, while the 312.5 kHz clock is the rate at which the instructions are executed. The microprogram is stored in the ROM and the instructions are fetched and then placed into the instruction registers. One register holds the opcode, while the other holds the immediate data. Once the instruction is fetched, it is decoded by the internal instruction decoder, at which point the COM20019I proceeds to execute the instruction. When a no-op instruction is encountered, the microsequencer enters a timed loop and the program counter is temporarily stopped until the loop is complete. When a jump instruction is encountered, the program counter is loaded with the jump address from the ROM. The COM20019I contains an internal reconfiguration timer which interrupts the microsequencer if it has timed out. At this point the program counter is cleared and the MYRECON bit of the Diagnostic Status Register is set. Table 6.1 - Read Register Summary
REGISTER STATUS DIAG. STATUS ADDRESS PTR HIGH ADDRESS PTR LOW DATA SUB ADR CONFIGURATION TENTID NODE ID SETUP1 NEXT ID SETUP2
MSB RI/TRI MYRECON RDDATA A7 D7 X RESET TID7 NID7 P1 MODE NXT ID7 RBUSTMG
READ X/RI DUPID AUTOINC A6 D6 X CCHEN TID6 NID6 FOUR NAKS NXT ID6 X X/TA RCVACT X A5 D5 X TXEN TID5 NID5 X NXT ID5 X POR TOKEN X A4 D4 X ET1 TID4 NID4 RCVALL NXT ID4 X TEST EXCNAK X A3 D3 X ET2 TID3 NID3 CKP3 NXT ID3 EF RECON TENTID A10 A2 D2 SUB-AD2 BACKPLANE TID2 NID2 CKP2 NXT ID2 NOSYNC TMA NEW NEXTID A9 A1 D1 SUB-AD1 SUB-AD1 TID1 NID1 CKP1 NXT ID1 RCNTM1
LSB TA/ TTA X A8 A0 D0 SUBAD0 SUBAD0 TID0 NID0 SLOWARB NXT ID0 RCMTM2
ADDR 00 01 02 03 04 05 06 07-0 07-1 07-2 07-3 07-4
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Table 6.2 - Write Register Summary ADDR 00 01 02 03 04 05 06 07-0 07-1 07-2 07-3 07-4 MSB RI/TR1 C7 RDDATA A7 D7 0 RESET TID7 NID7 P1MODE 0 RBUSTMG WRITE EXCNAK C3 0 A3 D3 0 ET2 TID3 NID3 CKP3 0 EF LSB TA/ TTA C0 A8 A0 D0 SUBAD0 SUBAD0 TID0 NID0 SLOWARB 0 RCNTM0 REGISTER INTERRUPT MASK COMMAND ADDRESS PTR HIGH ADDRESS PTR LOW DATA SUBADR CONFIGURATION TENTID NODEID SETUP1 TEST SETUP2
0 C6 AUTOINC A6 D6 0 CCHEN TID6 NID6 FOUR NAKS 0 0
0 C5 0 A5 D5 0 TXEN TID5 NID5 0 0 0
0 C4 0 A4 D4 0 ET1 TID4 NID4 RCVALL 0 0
RECON C2 A10 A2 D2 SUB-AD2 BACKPLANE TID2 NID2 CKP2 0 NOSYNC
NEW NEXTID C1 A9 A1 D1 SUBAD1 SUBAD1 TID1 NID1 CKP1 0 RCNTM1
6.2
INTERNAL REGISTERS
The COM20019I contains 14 internal registers. Tables 2 and 3 illustrate the COM20019I register map. All undefined bits are read as undefined and must be written as logic "0".
6.2.1
Interrupt Mask Register (IMR)
The COM20019I is capable of generating an interrupt signal when certain status bits become true. A write to the IMR specifies which status bits will be enabled to generate an interrupt. The bit positions in the IMR are in the same position as their corresponding status bits in the Status Register and Diagnostic Status Register. A logic "1" in a particular position enables the corresponding interrupt. The Status bits capable of generating an interrupt include the Receiver Inhibited bit, New Next ID bit, Excessive NAK bit, Reconfiguration Timer bit, and Transmitter Available bit. No other Status or Diagnostic Status bits can generate an interrupt. The six maskable status bits are ANDed with their respective mask bits, and the results are ORed to produce the interrupt signal. An RI or TA interrupt is masked when the corresponding mask bit is reset to logic "0", but will reappear when the corresponding mask bit is set to logic "1" again, unless the interrupt status condition has been cleared by this time. A RECON interrupt is cleared when the "Clear Flags" command is issued. An EXCNAK interrupt is cleared when the "POR Clear Flags" command is issued. A New Next ID interrupt is cleared by reading the Next ID Register. The Interrupt Mask Register defaults to the value 0000 0000 upon hardware reset.
6.2.2
Data Register
This read/write 8-bit register is used as the channel through which the data to and from the RAM passes. The data is placed in or retrieved from the address location presently specified by the address pointer. The contents of the Data Register are undefined upon hardware reset. In case of READ operation, the
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Data Register is loaded with the contents of COM20019I Internal Memory upon writing Address Pointer low only once.
6.2.3
Tentative ID Register
The Tentative ID Register is a read/write 8-bit register accessed when the Sub Address Bits are set up accordingly (please refer to the Configuration Register and SUB ADR Register). The Tentative ID Register can be used while the node is on-line to build a network map of those nodes existing on the network. It minimizes the need for operator interaction with the network. The node determines the existence of other nodes by placing a Node ID value in the Tentative ID Register and waiting to see if the Tentative ID bit of the Diagnostic Status Register gets set. The network map developed by this method is only valid for a short period of time, since nodes may join or depart from the network at any time. When using the Tentative ID feature, a node cannot detect the existence of the next logical node to which it passes the token. The Next ID Register will hold the ID value of that node. The Tentative ID Register defaults to the value 0000 0000 upon hardware reset only.
6.2.4
Node ID Register
The Node ID Register is a read/write 8-bit register accessed when the Sub Address Bits are set up accordingly (please refer to the Configuration Register and SUB ADR Register). The Node ID Register contains the unique value which identifies this particular node. Each node on the network must have a unique Node ID value at all times. The Duplicate ID bit of the Diagnostic Status Register helps the user find a unique Node ID. Refer to the Initialization Sequence section for further detail on the use of the DUPID bit. The core of the COM20019I does not wake up until a Node ID other than zero is written into the Node ID Register. During this time, no microcode is executed, no tokens are passed by this node, and no reconfigurations are caused by this node. Once a non-zero NodeID is placed into the Node ID Register, the core wakes up but will not join the network until the TXEN bit of the Configuration Register is set. While the Transmitter is disabled, the Receiver portion of the device is still functional and will provide the user with useful information about the network. The Node ID Register defaults to the value 0000 0000 upon hardware reset only.
6.2.5
Next ID Register
The Next ID Register is an 8-bit, read-only register, accessed when the sub-address bits are set up accordingly (please refer to the Configuration Register and SUB ADR Register). The Next ID Register holds the value of the Node ID to which the COM20019I will pass the token. When used in conjunction with the Tentative ID Register, the Next ID Register can provide a complete network map. The Next ID Register is updated each time a node enters/leaves the network or when a network reconfiguration occurs. Each time the microsequencer updates the Next ID Register, a New Next ID interrupt is generated. This bit is cleared by reading the Next ID Register. Default value is 0000 0000 upon hardware or software reset.
6.2.6
Status Register
The COM20019I Status Register is an 8-bit read-only register. All of the bits, except for bits 5 and 6, are software compatible with previous SMSC ARCNET devices. In previous SMSC ARCNET devices the Extended Timeout status was provided in bits 5 and 6 of the Status Register. In the COM20019I, the COM20020, the COM90C66, and the COM90C165, COM20020-5, COM20051 and COM20051+ these bits exist in and are controlled by the Configuration Register. The Status Register contents are defined as in Table 4, but are defined differently during the Command Chaining operation. Please refer to the Command Chaining section for the definition of the Status Register during Command Chaining operation. The Status Register defaults to the value 1XX1 0001 upon either hardware or software reset.
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6.2.7
Diagnostic Status Register
The Diagnostic Status Register contains seven read-only bits which help the user troubleshoot the network or node operation. Various combinations of these bits and the TXEN bit of the Configuration Register represent different situations. All of these bits, except the Excessive NAcK bit and the New Next ID bit, are reset to logic "0" upon reading the Diagnostic Status Register or upon software or hardware reset. The EXCNAK bit is reset by the "POR Clear Flags" command or upon software or hardware reset. The Diagnostic Status Register defaults to the value 0000 000X upon either hardware or software reset.
6.2.8
Command Register
Execution of commands are initiated by performing microcontroller writes to this register. Any combinations of written data other than those listed in Table 5 are not permitted and may result in incorrect chip and/or network operation.
6.2.9
Address Pointer Registers
These read/write registers are each 8-bits wide and are used for addressing the internal RAM. New pointer addresses should be written by first writing to the High Register and then writing to the Low Register because writing to the Low Register loads the address. The contents of the Address Pointer High and Low Registers are undefined upon hardware reset. Writing to Address Pointer low loads the address.
6.2.10 Configuration Register
The Configuration Register is a read/write register which is used to configure the different modes of the COM20019I. The Configuration Register defaults to the value 0001 1000 upon hardware reset only. SUBAD0 and SUBAD1 point to the selection in Register 7.
6.2.11 Sub-Address Register
The sub-address register is new to the COM20019I, previously a reserved register. Bits 2, 1 and 0 are used to select one of the registers assigned to address 7h. SUBAD1 and SUBAD0 already exist in the Configuration register on the COM20020B. They are exactly same as those in the Sub-Address register. If the SUBAD1 and SUBAD0 bits in the Configuration register are changed, the SUBAD1and SUBAD0 in the Sub-Address register are also changed. SUBAD2 is a new sub-address bit. It is used to access the 1 new Set Up register, SETUP2. This register is selected by setting SUBAD2=1. The SUBAD2 bit is cleared automatically by writing the Configuration register.
6.2.12 Setup 1 Register
The Setup 1 Register is a read/write 8-bit register accessed when the Sub Address Bits are set up accordingly (see the bit definitions of the Configuration Register). The Setup 1 Register allows the user to change the network speed (data rate) or the arbitration speed independently, invoke the Receive All feature and change the nPULSE1 driver type. The data rate may be slowed to 156.25Kbps and/or the arbitration speed may be slowed by a factor of two. The Setup 1 Register defaults to the value 0000 0000 upon hardware reset only.
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6.2.13 Setup 2 Register
The Setup 2 Register is new to the COM20019I. It is an 8-bit read/write register accessed when the Sub Address Bits SUBAD[2:0] are set up accordingly (see the bit definitions of the Sub Address Register). This register contains bits for various functions. The CKUP1,0 bits select the clock to be generated from the 20 MHz crystal. The RBUSTMG bit is used to Disable/Enable Fast Read function for High Speed CPU bus support. The EF bit is used to enable the new timing for certain functions in the COM20019I (if EF = 0, the timing is the same as in the COM20020 Rev. B). See Appendix "A". The NOSYNC bit is used to enable the NOSYNC function during initialization. If this bit is reset, the line has to be idle for the RAM initialization sequence to be written. If set, the line does not have to be idle for the initialization sequence to be written. See Appendix "A". The RCNTM[1,0] bits are used to set the time-out period of the recon timer. Programming this timer for shorter time periods has the benefit of shortened network reconfiguration periods. The time periods shown in the table on the following page are limited by a maximum number of nodes in the network. These timeout period values are for 312.5 Kbps. For other data rates, scale the time-out period time values accordingly; the maximum node count remains the same. MAX NODE COUNT Up to 255 nodes Up to 64 nodes Up to 32 nodes Up to 16 nodes (See Note 6.1)
RCNTM1 0 0 1 1 Note 6.1
RCNTM0 0 1 0 1
TIME-OUT PERIOD 6.72 S 1.68 S 840 mS 420 mS*
The node ID value 255 must exist in the network for the 420 mS time-out to be valid.
Table 6.3 - Status Register BIT BIT NAME 7 Receiver Inhibited SYMBOL DESCRIPTION RI This bit, if high, indicates that the receiver is not enabled because either an "Enable Receive to Page fnn" command was never issued, or a packet has been deposited into the RAM buffer page fnn as specified by the last "Enable Receive to Page fnn" command. No messages will be received until this command is issued, and once the message has been received, the RI bit is set, thereby inhibiting the receiver. The RI bit is cleared by issuing an "Enable Receive to Page fnn" command. This bit, when set, will cause an interrupt if the corresponding bit of the Interrupt Mask Register (IMR) is also set. When this bit is set and another station attempts to send a packet to this station, this station will send a NAK. (Reserved) These bits are undefined. Power On Reset POR This bit, if high, indicates that the COM20019I has been reset by either a software reset, a hardware reset, or writing 00H to the Node ID Register. The POR bit is cleared by the "Clear Flags" command. Test TEST This bit is intended for test and diagnostic purposes. It is a logic "0" under normal operating conditions.
6,5 4
3
SMSC COM20019I
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BIT BIT NAME 2 Reconfiguration
1
Transmitter Message Acknowledged
0
Transmitter Available
SYMBOL DESCRIPTION RECON This bit, if high, indicates that the Line Idle Timer has timed out because the RXIN pin was idle for 656 S. The RECON bit is cleared during a "Clear Flags" command. This bit, when set, will cause an interrupt if the corresponding bit in the IMR is also set. The interrupt service routine should consist of examining the MYRECON bit of the Diagnostic Status Register to determine whether there are consecutive reconfigurations caused by this node. TMA This bit, if high, indicates that the packet transmitted as a result of an "Enable Transmit from Page fnn" command has been acknowledged. This bit should only be considered valid after the TA bit (bit 0) is set. Broadcast messages are never acknowledged. The TMA bit is cleared by issuing the "Enable Transmit from Page fnn" command. TA This bit, if high, indicates that the transmitter is available for transmitting. This bit is set when the last byte of scheduled packet has been transmitted out, or upon execution of a "Disable Transmitter" command. The TA bit is cleared by issuing the "Enable Transmit from Page fnn" command after the node next receives the token. This bit, when set, will cause an interrupt if the corresponding bit in the IMR is also set.
Table 6.4 - Diagnostic Status Register BIT BIT NAME 7 My Reconfiguration SYMBOL DESCRIPTION MYThis bit, if high, indicates that a past reconfiguration was caused by this node. It is set when the Lost Token Timer times out, and RECON should be typically read following an interrupt caused by RECON. Refer to the Improved Diagnostics section for further detail. DUPID This bit, if high, indicates that the value in the Node ID Register matches both Destination ID characters of the token and a response to this token has occurred. Trailing zero's are also verified. A logic "1" on this bit indicates a duplicate Node ID, thus the user should write a new value into the Node ID Register. This bit is only useful for duplicate ID detection when the device is off line, that is, when the transmitter is disabled. When the device is on line this bit will be set every time the device gets the token. This bit is reset automatically upon reading the Diagnostic Status Register. Refer to the Improved Diagnostics section for further detail. RCVACT This bit, if high, indicates that data activity (logic "1") was detected on the RXIN pin of the device. Refer to the Improved Diagnostics section for further detail. TOKEN This bit, if high, indicates that a token has been seen on the network, sent by a node other than this one. Refer to the Improved Diagnostic section for further detail. EXCNAK This bit, if high, indicates that either 128 or 4 Negative Acknowledgements have occurred in response to the Free Buffer Enquiry. This bit is cleared upon the "POR Clear Flags" command. Reading the Diagnostic Status Register does not clear this bit. This bit, when set, will cause an interrupt if the corresponding bit in the IMR is also set. Refer to the Improved Diagnostics section for further detail.
6
Duplicate ID
5
Receive Activity Token Seen
4
3
Excessive NAK
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BIT BIT NAME 2 Tentative ID
1
New Next ID
1,0
(Reserved)
SYMBOL DESCRIPTION TENTID This bit, if high, indicates that a response to a token whose DID matches the value in the Tentative ID Register has occurred. The second DID and the trailing zero's are not checked. Since each node sees every token passed around the network, this feature can be used with the device on-line in order to build and update a network map. Refer to the Improved Diagnostics section for further detail. NEW This bit, if high, indicates that the Next ID Register has been updated and that a node has either joined or left the network. NXTID Reading the Diagnostic Status Register does not clear this bit. This bit, when set, will cause an interrupt if the corresponding bit in the IMR is also set. The bit is cleared by reading the Next ID Register. These bits are undefined.
Table 6.5 - Command Register DATA 0000 0000 COMMAND Clear Transmit Interrupt Disable Transmitter DESCRIPTION This command is used only in the Command Chaining operation. Please refer to the Command Chaining section for definition of this command. This command will cancel any pending transmit command (transmission that has not yet started) and will set the TA (Transmitter Available) status bit to logic "1" when the COM20019I next receives the token. This command will cancel any pending receive command. If the COM20019I is not yet receiving a packet, the RI (Receiver Inhibited) bit will be set to logic "1" the next time the token is received. If packet reception is already underway, reception will run to its normal conclusion. This command allows the COM20019I to receive data packets into RAM buffer page fnn and resets the RI status bit to logic "0". The values placed in the "nn" bits indicate the page that the data will be received into (page 0, 1, 2, or 3). If the value of "f" is a logic "1", an offset of 256 bytes will be added to that page specified in "nn", allowing a finer resolution of the buffer. Refer to the Selecting RAM Page Size section for further detail. If the value of "b" is logic "1", the device will also receive broadcasts (transmissions to ID zero). The RI status bit is set to logic "1" upon successful reception of a message. This command prepares the COM20019I to begin a transmit sequence from RAM buffer page fnn the next time it receives the token. The values of the "nn" bits indicate which page to transmit from (0, 1, 2, or 3). If "f" is logic "1", an offset of 256 bytes is the start of the page specified in "nn", allowing a finer resolution of the buffer. Refer to the Selecting RAM Page Size section for further detail. When this command is loaded, the TA and TMA bits are reset to logic "0". The TA bit is set to logic "1" upon completion of the transmit sequence. The TMA bit will have been set by this time if the device has received an ACK from the destination node. The ACK is strictly hardware level, sent by the receiving node before its microcontroller is even aware of message reception. Refer to Figure 1 for details of the transmit sequence and its relation to the TA and TMA status bits.
0000 0001
0000 0010
Disable Receiver
b0fn n100
Enable Receive to Page fnn
00fn n011
Enable Transmit from Page fnn
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DATA 0000 c101
COMMAND Define Configuration
000r p110
Clear Flags
0000 1000
Clear Receive Interrupt
DESCRIPTION This command defines the maximum length of packets that may be handled by the device. If "c" is a logic "1", the device handles both long and short packets. If "c" is a logic "0", the device handles only short packets. This command resets certain status bits of the COM20019I. A logic "1" on "p" resets the POR status bit and the EXCNAK Diagnostic status bit. A logic "1" on "r" resets the RECON status bit. This command is used only in the Command Chaining operation. Please refer to the Command Chaining section for definition of this command.
Table 6.6 - Address Pointer High Register BIT 7 BIT NAME Read Data SYMBOL RDDATA DESCRIPTION This bit tells the COM20019I whether the following access will be a read or write. A logic "1" prepares the device for a read, a logic "0" prepares it for a write. This bit controls whether the address pointer will increment automatically. A logic "1" on this bit allows automatic increment of the pointer after each access, while a logic "0" disables this function. Please refer to the Sequential Access Memory section for further detail. These bits are undefined. These bits hold the upper three address bits which provide addresses to RAM.
6
Auto Increment
AUTOINC
5-3 2-0
(Reserved) Address 10-8
A10-A8
Table 6.7 - Address Pointer Low Register BIT 7-0 BIT NAME Address 7-0 SYMBOL A7-A0 DESCRIPTION These bits hold the lower 8 address bits which provide the addresses to RAM.
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Table 6.8 - Sub Address Register BIT 7-3 2,1,0 BIT NAME Reserved Sub Address 2,1,0 SYMBOL SUBAD 2,1,0 DESCRIPTION These bits are undefined. These bits determine which register at address 07 may be accessed. The combinations are as follows: Register SUBAD2 SUBAD1 SUBAD0 0 0 0 Tentative ID \ (Same 0 0 1 Node ID \ as in 0 1 0 Setup 1 / Config 0 1 1 Next ID / Register) 1 0 0 Setup 2 1 0 1 Reserved 1 1 0 Reserved 1 1 1 Reserved SUBAD1 and SUBAD0 are exactly the same as exist in the Configuration Register. SUBAD2 is cleared automatically by writing the Configuration Register.
Table 6.9 - Configuration Register BIT 7 BIT NAME Reset SYMBOL RESET DESCRIPTION A software reset of the COM20019I is executed by writing a logic "1" to this bit. A software reset does not reset the microcontroller interface mode, nor does it affect the Configuration Register. The only registers that the software reset affect are the Status Register, the Next ID Register, and the Diagnostic Status Register. This bit must be brought back to logic "0" to release the reset. This bit, if high, enables the Command Chaining operation of the device. Please refer to the Command Chaining section for further details. A low level on this bit ensures software compatibility with previous SMSC ARCNET devices. When low, this bit disables transmissions by keeping nPULSE1, nPULSE2 if in non-Backplane Mode, and nTXEN pin inactive. When high, it enables the above signals to be activated during transmissions. This bit defaults low upon reset. This bit is typically enabled once the Node ID is determined, and never disabled during normal operation. Please refer to the Improved Diagnostics section for details on evaluating network activity.
6
Command Chaining Enable
CCHEN
5
Transmit Enable
TXEN
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BIT 4,3
BIT NAME Extended Timeout 1,2
SYMBOL ET1, ET2
DESCRIPTION These bits allow the network to operate over longer distances than the default maximum 32 miles by controlling the Response, Idle, and Reconfiguration Times. All nodes should be configured with the same timeout values for proper network operation. For the COM20019I with a 20 MHz crystal oscillator, the bit combinations follow: Response Idle Time Reconfig ET1 Time (mS) (mS) Time (S) ET2 0 0 9.548 10.496 13.44 0 1 4.774 5.248 13.44 1 0 2.387 2.624 13.44 1 1 0.597 0.656 6.72 Note: These values are for 312.5 Kbps and RCNTMR[1,0]=00. Reconfiguration time is changed by the RCNTMR1 and RCNTMR0 bits. A logic "1" on this bit puts the device into Backplane Mode signaling which is used for Open Drain and Differential Driver interfaces. This bit must be set to `1' at the COM20019I. These bits determine which register at address 07 may be accessed. The combinations are as follows: SUBAD0 Register SUBAD1 0 0 Tentative I 0 1 Node ID 1 0 Setup 1 1 1 Next ID See also the Sub Address Register.
2
Backplane
BACKPLANE
1,0
Sub Address 1,0
SUBAD 1,0
Table 6.10 - Setup 1 Register BIT 7 BIT NAME Pulse1 Mode SYMBOL P1MODE DESCRIPTION This bit determines the type of PULSE1 output driver used in Backplane Mode. When high, a push/pull output is used. When low, an open drain output is used. The default is open drain. This bit, when set, will cause the EXNACK bit in the Diagnostic Status Register to set after four NACKs to Free Buffer Enquiry are detected by the COM20019I. This bit, when reset, will set the EXNACK bit after 128 NACKs to Free Buffer Enquiry. The default is 128. Do not set. This bit, when set, allows the COM20019I to receive all valid data packets on the network, regardless of their destination ID. This mode can be used to implement a network monitor with the transmitter on- or off-line. Note that ACKs are only sent for packets received with a destination ID equal to the COM20019I's programmed node ID. This feature can be used to put the COM20019I in a 'listen-only' mode, where the transmitter is disabled and the COM20019I is not passing tokens. Defaults low.
6
Four NACKS
FOUR NACKS
5 4
Reserved Receive All
RCVALL
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BIT 3,2,1
BIT NAME Clock Prescaler Bits 3,2,1
SYMBOL CKP3,2,1
0
Slow Arbitration Select
SLOWARB
DESCRIPTION These bits are used to determine the data rate of the COM20019I. The following table is for a 20 MHz crystal: CKP3 CKP2 CKP1 DIVISOR SPEED 64 312.5 Kbs 1 1 0 128 156.25 Kbs 0 0 1 Note: The lowest data rate achievable by the COM20019I is 156.25 Kbs. Defaults to 011 or 312.5 Kbps. This bit, when set, will divide the arbitration clock by 2. Memory cycle times will increase when slow arbitration is selected. Defaults to low.
Table 6.11 - Setup 2 Register BIT 7 BIT NAME Read Bus Timing Select SYMBOL DESCRIPTION RBUSTMG This bit is used to Disable/Enable the High Speed CPU Read function for High Speed CPU bus support. RBUSTMG=0: Disable (Default), RBUSTMG=1: Enable. It does not influence write operation. High speed CPU Read operation is only for non-multiplexed bus. These bits are undefined. EF This bit is used to enable the new enhanced functions in the COM20019I. EF = 0: Disable (Default), EF = 1: Enable. If EF = 0, the timing and function is the same as in the COM20020, Revision B. See appendix "A". EF bit must be `1' if the data rate is over 5Mbps. EF bit should be `1' for new design customers. EF bit should be `0' for replacement customers. NOSYNC This bit is used to enable the SYNC command during initialization. NOSYNC= 0, Enable (Default) The line must be idle for the RAM initialization sequence to be written. NOSYNC= 1, Disable:) The line does not have to be idle for the RAM initialization sequence to be written. See appendix "A". RCNTM1, These bits are used to program the reconfiguration timer as 0 a function of maximum node count. These bits set the time out period of the reconfiguration timer as shown below. The time out periods shown are for 312.5 Kbps. RCNTM1 RCNTM0 Time Out Max Node Count Period 0 0 6.72 S Up to 255 nodes 0 1 1.68 S Up to 64 nodes 1 0 840 mS Up to 32 nodes 1 1 420 mS* Up to 16 nodes Note*: The node ID value 255 must exist in the network for 420 mS timeout to be valid.
6,5,4 3
Reserved Enhanced Functions
2
No Synchronous
1,0
Reconfiguration Timer 1, 0
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Data Register I/O Address 04H Memory Data Bus 8 2K x 8 INTERNAL RAM
D0-D7
Address Pointer Register I/O Address 02H High I/O Address 03H Low
Memory Address Bus 11-Bit Counter 11
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Figure 6.1 - SEQUENTIAL ACCESS OPERATION
6.3
INTERNAL RAM
The integration of the 2K x 8 RAM in the COM20019I represents significant real estate savings. The most obvious benefit is the 48 pin package in which the device is now placed (a direct result of the integration of RAM). In addition, the PC board is now free of the cumbersome external RAM, external latch, and multiplexed address/data bus and control functions which were necessary to interface to the RAM. The integration of RAM represents significant cost savings because it isolates the system designer from the changing costs of external RAM and it minimizes reliability problems, assembly time and costs, and layout complexity.
6.3.1
Sequential Access Memory
The internal RAM is accessed via a pointer-based scheme. Rather than interfering with system memory, the internal RAM is indirectly accessed through the Address High and Low Pointer Registers. The data is channeled to and from the microcontroller via the 8-bit data register. For example: a packet in the internal RAM buffer is read by the microcontroller by writing the corresponding address into the Address Pointer High and Low Registers (offsets 02H and 03H). Note that the High Register should be written first, followed by the Low Register, because writing to the Low Register loads the address. At this point the device accesses that location and places the corresponding data into the data register. The microcontroller then reads the data register (offset 04H) to obtain the data at the specified location. If the Auto Increment bit is set to logic "1", the device will automatically increment the address and place the next byte of data into the data register, again to be read by the microcontroller. This process is continued until the entire packet is read out of RAM. Refer to Figure 7 for an illustration of the Sequential Access operation. When switching between reads and writes, the pointer must first be written with the starting address. At least one cycle time should separate the pointer being loaded and the first read (see timing parameters).
6.3.2
Access Speed
The COM20019I is able to accommodate very fast access cycles to its registers and buffers. Arbitration to the buffer does not slow down the cycle because the pointer based access method allows data to be prefetched from memory and stored in a temporary register. Likewise, data to be written is stored in the temporary register and then written to memory. For systems which do not require quick access time, the arbitration clock may be slowed down by setting bit 0 of the Setup1 Register equal to logic "1". Since the Slow Arbitration feature divides the input clock by two, the duty cycle of the input clock may be relaxed.
6.4
SOFTWARE INTERFACE
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The microcontroller interfaces to the COM20019I via software by accessing the various registers. These actions are described in the Internal Registers section. The software flow for accessing the data buffer is based on the Sequential Access scheme. The basic sequence is as follows: Disable Interrupts Write to Pointer Register High (specifying Auto-Increment mode) Write to Pointer Register Low (this loads the address) Enable Interrupts Read or Write the Data Register (repeat as many times as necessary to empty or fill the buffer) The pointer may now be read to determine how many transfers were completed. The software flow for controlling the Configuration, Node ID, Tentative ID, and Next ID registers is generally limited to the initialization sequence and the maintenance of the network map. Additionally, it is necessary to understand the details of how the other Internal Registers are used in the transmit and receive sequences and to know how the internal RAM buffer is properly set up. The sequence of events that tie these actions together is discussed as follows.
6.4.1
Selecting RAM Page Size
During normal operation, the 2K x 8 of RAM is divided into four pages of 512 bytes each. The page to be used is specified in the "Enable Transmit (Receive) from (to) Page fnn" command, where "nn" specifies page 0, 1, 2, or 3. This allows the user to have constant control over the allocation of RAM. When the Offset bit "f" (bit 5 of the "Enable Transmit (Receive) from (to) Page fnn" command word) is set to logic "1", an offset of 256 bytes is added to the page specified. For example: to transmit from the second half of page 0, the command "Enable Transmit from Page fnn" (fnn=100 in this case) is issued by writing 0010 0011 to the Command Register. This allows a finer resolution of the buffer pages without affecting software compatibility. This scheme is useful for applications which frequently use packet sizes of 256 bytes or less, especially for microcontroller systems with limited memory capacity. The remaining portions of the buffer pages which are not allocated for current transmit or receive packets may be used as temporary storage for previous network data, packets to be sent later, or as extra memory for the system, which may be indirectly accessed. If the device is configured to handle both long and short packets (see "Define Configuration" command), then receive pages should always be 512 bytes long because the user never knows what the length of the receive packet will be. In this case, the transmit pages may be made 256 bytes long, leaving at least 512 bytes free at any given time. Even if the Command Chaining operation is being used, 512 bytes is still guaranteed to be free because Command Chaining only requires two pages for transmit and two for receive (in this case, two 256 byte pages for transmit and two 512 byte pages for receive, leaving 512 bytes free). Please note that it is the responsibility of software to reserve 512 bytes for each receive page if the device is configured to handle long packets. The COM20019I does not check page boundaries during reception. If the device is configured to handle only short packets, then both transmit and receive pages may be allocated as 256 bytes long, freeing at least 1KByte at any given time. Even if the Command Chaining operation is being used, 1KByte is still guaranteed to be free because Command Chaining only requires two pages for transmit and two for receive (in this case, a total of four 256 byte pages, leaving 1K free). The general rule which may be applied to determine where in RAM a page begins is as follows: Address = (nn x 512) + (f x 256).
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ADDRESS 0 1 2
SHORT PACKET FORMAT SID DID COUNT = 256-N NOT USED
ADDRESS 0 1 2 3
LONG PACKET FORMAT SID DID 0 COUNT = 512-N NOT USED
COUNT
DATA BYTE 1 DATA BYTE 2 COUNT DATA BYTE N-1
DATA BYTE 1 DATA BYTE 2
255
DATA BYTE N NOT USED DATA BYTE N-1 511 DATA BYTE N
511
N = DATA PACKET LENGTH SID = SOURCE ID DID = DESTINATION ID (DID = 0 FOR BROADCASTS)
Figure 6.2 - RAM BUFFER PACKET CONFIGURATION
6.4.2
Transmit Sequence
During a transmit sequence, the microcontroller selects a 256 or 512 byte segment of the RAM buffer and writes into it. The appropriate buffer size is specified in the "Define Configuration" command. When long packets are enabled, the COM20019I interprets the packet as either a long or short packet, depending on whether the buffer address 2 contains a zero or non-zero value. The format of the buffer is shown in Figure 8. Address 0 contains the Source Identifier (SID); Address 1 contains the Destination Identifier (DID); Address 2 (COUNT) contains, for short packets, the value 256-N, where N represents the number of information bytes in the message, or for long packets, the value 0, indicating that it is indeed a long packet. In the latter case, Address 3 (COUNT) would contain the value 512-N, where N represents the number of information bytes in the message. The SID in Address 0 is used by the receiving node to reply to the transmitting node. The COM20019I puts the local ID in this location, therefore it is not necessary to write into this location. Please note that a short packet may contain between 1 and 253 data bytes, while a long packet may contain between 257 and 508 data bytes. A minimum value of 257 exists on a long packet so that the COUNT is expressible in eight bits. This leaves three exception packet lengths which do not fit into either a short or long packet; packet lengths of 254, 255, or 256 bytes. If packets of these
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lengths must be sent, the user must add dummy bytes to the packet in order to make the packet fit into a long packet. Once the packet is written into the buffer, the microcontroller awaits a logic "1" on the TA bit, indicating that a previous transmit command has concluded and another may be issued. Each time the message is loaded and a transmit command issued, it will take a variable amount of time before the message is transmitted, depending on the traffic on the network and the location of the token at the time the transmit command was issued. The conclusion of the Transmit Command will generate an interrupt if the Interrupt Mask allows it. If the device is configured for the Command Chaining operation, please see the Command Chaining section for further detail on the transmit sequence. Once the TA bit becomes a logic "1", the microcontroller may issue the "Enable Transmit from Page fnn" command, which resets the TA and TMA bits to logic "0". If the message is not a BROADCAST, the COM20019I automatically sends a FREE BUFFER ENQUIRY to the destination node in order to send the message. At this point, one of four possibilities may occur. The first possibility is if a free buffer is available at the destination node, in which case it responds with an ACKnowledgement. At this point, the COM20019I fetches the data from the Transmit Buffer and performs the transmit sequence. If a successful transmit sequence is completed, the TMA bit and the TA bit are set to logic "1". If the packet was not transmitted successfully, TMA will not be set. A successful transmission occurs when the receiving node responds to the packet with an ACK. An unsuccessful transmission occurs when the receiving node does not respond to the packet. The second possibility is if the destination node responds to the Free Buffer Enquiry with a Negative AcKnowledgement. A NAK occurs when the RI bit of the destination node is a logic "1". In this case, the token is passed on from the transmitting node to the next node. The next time the transmitter receives the token, it will again transmit a FREE BUFFER ENQUIRY. If a NAK is again received, the token is again passed onto the next node. The Excessive NAK bit of the Diagnostic Status Register is used to prevent an endless sending of FBE's and NAK's. If no limit of FBE-NAK sequences existed, the transmitting node would continue issuing a Free Buffer Enquiry, even though it would continuously receive a NAK as a response. The EXCNAK bit generates an interrupt (if enabled) in order to tell the microcontroller to disable the transmitter via the "Disable Transmitter" command. This causes the transmission to be abandoned and the TA bit to be set to a logic "1" when the node next receives the token, while the TMA bit remains at a logic "0". Please refer to the Improved Diagnostics section for further detail on the EXCNAK bit. The third possibility which may occur after a FREE BUFFER ENQUIRY is issued is if the destination node does not respond at all. In this case, the TA bit is set to a logic "1", while the TMA bit remains at a logic "0". The user should determine whether the node should try to reissue the transmit command. The fourth possibility is if a non-traditional response is received (some pattern other than ACK or NAK, such as noise). In this case, the token is not passed onto the next node, which causes the Lost Token Timer of the next node to time out, thus generating a network reconfiguration. The "Disable Transmitter" command may be used to cancel any pending transmit command when the COM20019I next receives the token. Normally, in an active network, this command will set the TA status bit to a logic "1" when the token is received. If the "Disable Transmitter" command does not cause the TA bit to be set in the time it takes the token to make a round trip through the network, one of three situations exists. Either the node is disconnected from the network, or there are no other nodes on the network, or the external receive circuitry has failed. These situations can be determined by either using the improved diagnostic features of the COM20019I or using another software timeout which is greater than the worst case time for a round trip token pass, which occurs when all nodes transmit a maximum length message.
6.4.3
Receive Sequence
A receive sequence begins with the RI status bit becoming a logic "1", which indicates that a previous reception has concluded. The microcontroller will be interrupted if the corresponding bit in the Interrupt Mask Register is set to logic "1". Otherwise, the microcontroller must periodically check the Status Register. Once the microcontroller is alerted to the fact that the previous reception has concluded, it may issue the "Enable Receive to Page fnn" command, which resets the RI bit to logic "0" and selects a new page in the RAM buffer. Again, the appropriate buffer size is specified in the "Define Configuration"
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command. Typically, the page which just received the data packet will be read by the microcontroller at this point. Once the "Enable Receive to Page fnn" command is issued, the microcontroller attends to other duties. There is no way of knowing how long the new reception will take, since another node may transmit a packet at any time. When another node does transmit a packet to this node, and if the "Define Configuration" command has enabled the reception of long packets, the COM20019I interprets the packet as either a long or short packet, depending on whether the content of the buffer location 2 is zero or nonzero. The format of the buffer is shown in Figure 9. Address 0 contains the Source Identifier (SID), Address 1 contains the Destination Identifier (DID), and Address 2 contains, for short packets, the value 256-N, where N represents the message length, or for long packets, the value 0, indicating that it is indeed a long packet. In the latter case, Address 3 contains the value 512-N, where N represents the message length. Note that on reception, the COM20019I deposits packets into the RAM buffer in the same format that the transmitting node arranges them, which allows for a message to be received and then retransmitted without rearranging any bytes in the RAM buffer other than the SID and DID. Once the packet is received and stored correctly in the selected buffer, the COM20019I sets the RI bit to logic "1" to signal the microcontroller that the reception is complete.
MSB
LSB
TRI
RI
TA
POR
TEST
RECON
TMA
TTA
TRI
TMA
TTA
Figure 6.3 - COMMAND CHAINING STATUS REGISTER QUEUE
6.5
COMMAND CHAINING
The Command Chaining operation allows consecutive transmissions and receptions to occur without host microcontroller intervention. Through the use of a dual two-level FIFO, commands to be transmitted and received, as well as the status bits, are pipelined. In order for the COM20019I to be compatible with previous SMSC ARCNET device drivers, the device defaults to the non-chaining mode. In order to take advantage of the Command Chaining operation, the Command Chaining Mode must be enabled via a logic "1" on bit 6 of the Configuration Register. In Command Chaining, the Status Register appears as in Figure 6.3. The following is a list of Command Chaining guidelines for the software programmer. Further detail can be found in the Transmit Command Chaining and Receive Command Chaining sections. The device is designed such that the interrupt service routine latency does not affect performance. Up to two outstanding transmissions and two outstanding receptions can be pending at any given time. The commands may be given in any order. Up to two outstanding transmit interrupts and two outstanding receive interrupts are stored by the device, along with their respective status bits. The Interrupt Mask bits act on TTA (Rising Transition on Transmitter Available) for transmit operations and TRI (Rising Transition of Receiver Inhibited) for receive operations. TTA is set upon completion of a packet transmission only. TRI is set upon completion of a packet reception only. Typically there is no need to mask the TTA and TRI bits after clearing the interrupt.
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The traditional TA and RI bits are still available to reflect the present status of the device.
6.5.1
Transmit Command Chaining
When the processor issues the first "Enable Transmit to Page fnn" command, the COM20019I responds in the usual manner by resetting the TA and TMA bits to prepare for the transmission from the specified page. The TA bit can be used to see if there is currently a transmission pending, but the TA bit is really meant to be used in the non-chaining mode only. The TTA bits provide the relevant information for the device in the Command Chaining mode. In the Command Chaining Mode, at any time after the first command is issued, the processor can issue a second "Enable Transmit from Page fnn" command. The COM20019I stores the fact that the second transmit command was issued, along with the page number. After the first transmission is completed, the COM20019I updates the Status Register by setting the TTA bit, which generates an interrupt. The interrupt service routine should read the Status Register. At this point, the TTA bit will be found to be a logic "1" and the TMA (Transmit Message Acknowledge) bit will tell the processor whether the transmission was successful. After reading the Status Register, the "Clear Transmit Interrupt" command is issued, thus resetting the TTA bit and clearing the interrupt. Note that only the "Clear Transmit Interrupt" command will clear the TTA bit and the interrupt. It is not necessary, however, to clear the bit or the interrupt right away because the status of the transmit operation is double buffered in order to retain the results of the first transmission for analysis by the processor. This information will remain in the Status Register until the "Clear Transmit Interrupt" command is issued. Note that the interrupt will remain active until the command is issued, and the second interrupt will not occur until the first interrupt is acknowledged. The COM20019I guarantees a minimum of 200nS (at EF=1) interrupt inactive time interval between interrupts. The TMA bit is also double buffered to reflect whether the appropriate transmission was a success. The TMA bit should only be considered valid after the corresponding TTA bit has been set to a logic "1". The TMA bit never causes an interrupt. When the token is received again, the second transmission will be automatically initiated after the first is completed by using the stored "Enable Transmit from Page fnn" command. The operation is as if a new "Enable Transmit from Page fnn" command has just been issued. After the first Transmit status bits are cleared, the Status Register will again be updated with the results of the second transmission and a second interrupt resulting from the second transmission will occur. The COM20019I guarantees a minimum of 200ns (at EF=1) interrupt inactive time interval before the following edge. The Transmitter Available (TA) bit of the Interrupt Mask Register now masks only the TTA bit of the Status Register, not the TA bit as in the non-chaining mode. Since the TTA bit is only set upon transmission of a packet (not by RESET), and since the TTA bit may easily be reset by issuing a "Clear Transmit Interrupt" command, there is no need to use the TA bit of the Interrupt Mask Register to mask interrupts generated by the TTA bit of the Status Register. In Command Chaining mode, the "Disable Transmitter" command will cancel the oldest transmission. This permits canceling a packet destined for a node not ready to receive. If both packets should be canceled, two "Disable Transmitter" commands should be issued.
6.5.2
Receive Command Chaining
Like the Transmit Command Chaining operation, the processor can issue two consecutive "Enable Receive from Page fnn" commands. After the first packet is received into the first specified page, the TRI bit of the Status Register will be set to logic "1", causing an interrupt. Again, the interrupt need not be serviced immediately. Typically, the interrupt service routine will read the Status Register. At this point, the RI bit will be found to be a logic "1". After reading the Status Register, the "Clear Receive Interrupt" command should be issued, thus resetting the TRI bit and clearing the interrupt. Note that only the "Clear Receive Interrupt" command will clear the
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TRI bit and the interrupt. It is not necessary, however, to clear the bit or the interrupt right away because the status of the receive operation is double buffered in order to retain the results of the first reception for analysis by the processor, therefore the information will remain in the Status Register until the "Clear Receive Interrupt" command is issued. Note that the interrupt will remain active until the "Clear Receive Interrupt" command is issued, and the second interrupt will be stored until the first interrupt is acknowledged. A minimum of 200nS (at EF=1) interrupt inactive time interval between interrupts is guaranteed. The second reception will occur as soon as a second packet is sent to the node, as long as the second "Enable Receive to Page fnn" command was issued. The operation is as if a new "Enable Receive to Page fnn" command has just been issued. After the first Receive status bits are cleared, the Status Register will again be updated with the results of the second reception and a second interrupt resulting from the second reception will occur. In the COM20019I, the Receive Inhibit (RI) bit of the Interrupt Mask Register now masks only the TRI bit of the Status Register, not the RI bit as in the non-chaining mode. Since the TRI bit is only set upon reception of a packet (not by RESET), and since the TRI bit may easily be reset by issuing a "Clear Receive Interrupt" command, there is no need to use the RI bit of the Interrupt Mask Register to mask interrupts generated by the TRI bit of the Status Register. In Command Chaining mode, the "Disable Receiver" command will cancel the oldest reception, unless the reception has already begun. If both receptions should be canceled, two "Disable Receiver" commands should be issued.
6.6
6.6.1
RESET DETAILS
Internal Reset Logic
The COM20019I includes special reset circuitry to guarantee smooth operation during reset. Special care is taken to assure proper operation in a variety of systems and modes of operation. The COM20019I contains digital filter circuitry and a Schmitt Trigger on the nRESET signal to reject glitches in order to ensure fault-free operation. The COM20019I supports two reset options; software and hardware reset. A software reset is generated when a logic "1" is written to bit 7 of the Configuration Register. The device remains in reset as long as this bit is set. The software reset does not affect the microcontroller interface modes determined after hardware reset, nor does it affect the contents of the Address Pointer Registers, the Configuration Register, or the Setup1 Register. A hardware reset occurs when a low signal is asserted on the nRESET input. The minimum reset pulse width is 5TXTL. This pulse width is used by the internal digital filter, which filters short glitches to allow only valid resets to occur. Upon reset, the transmitter portion of the device is disabled and the internal registers assume those states outlined in the Internal Registers section. After the nRESET signal is removed the user may write to the internal registers. Since writing a non-zero value to the Node ID Register wakes up the COM20019I core, the Setup1 Register should be written before the Node ID Register. Once the Node ID Register is written to, the COM20019I reads the value and executes two write cycles to the RAM buffer. Address 0 is written with the data D1H and address 1 is written with the Node ID. The data pattern D1H was chosen arbitrarily, and is meant to provide assurance of proper microsequencer operation.
6.7
6.7.1
INITIALIZATION SEQUENCE
Bus Determination
Writing to and reading from an odd address location from the COM20019I's address space causes the COM20019I to determine the appropriate bus interface. When the COM20019I is powered on the internal
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registers may be written to. Since writing a non-zero value to the Node ID Register wakes up the core, the Setup1 Register should be written to before the Node ID Register. Until a non-zero value is placed into the NID Register, no microcode is executed, no tokens are passed by this node, and no reconfigurations are generated by this node. Once a non-zero value is placed in the register, the core wakes up, but the node will not attempt to join the network until the TX Enable bit of the Configuration Register is set. Before setting the TX Enable bit, the software may make some determinations. The software may first observe the Receive Activity and the Token Seen bits of the Diagnostic Status Register to verify the health of the receiver and the network. Next, the uniqueness of the Node ID value placed in the Node ID Register is determined. The TX Enable bit should still be a logic "0" until it is ensured that the Node ID is unique. If this node ID already exists, the Duplicate ID bit of the Diagnostic Status Register is set after a maximum of 6.72S (or 13.44S if the ET1 and ET2 bits are other than 1,1). To determine if another node on the network already has this ID, the COM20019I compares the value in the Node ID Register with the DID's of the token, and determines whether there is a response to it. Once the Diagnostic Status Register is read, the DUPID bit is cleared. The user may then attempt a new ID value, wait 6.72S before checking the Duplicate ID bit, and repeat the process until a unique Node ID is found. At this point, the TX Enable bit may be set to allow the node to join the network. Once the node joins the network, a reconfiguration occurs, as usual, thus setting the MYRECON bit of the Diagnostic Status Register. The Tentative ID Register may be used to build a network map of all the nodes on the network, even once the COM20019I has joined the network. Once a value is placed in the Tentative ID Register, the COM20019I looks for a response to a token whose DID matches the Tentative ID Register. The software can record this information and continue placing Tentative ID values into the register to continue building the network map. A complete network map is only valid until nodes are added to or deleted from the network. Note that a node cannot detect the existence of the next logical node on the network when using the Tentative ID. To determine the next logical node, the software should read the Next ID Register.
6.8
IMPROVED DIAGNOSTICS
The COM20019I allows the user to better manage the operation of the network through the use of the internal Diagnostic Status Register. A high level on the My Reconfiguration (MYRECON) bit indicates that the Token Reception Timer of this node expired, causing a reconfiguration by this node. After the Reconfiguration (RECON) bit of the Status Register interrupts the microcontroller, the interrupt service routine will typically read the MYRECON bit of the Diagnostic Status Register. Reading the Diagnostic Status Register resets the MYRECON bit. Successive occurrences of a logic "1" on the MYRECON bit indicates that a problem exists with this node. At that point, the transmitter should be disabled so that the entire network is not held down while the node is being evaluated. The Duplicate ID (DUPID) bit is used before the node joins the network to ensure that another node with the same ID does not exist on the network. Once it is determined that the ID in the Node ID Register is unique, the software should write a logic "1" to bit 5 of the Configuration Register to enable the basic transmit function. This allows the node to join the network. The Receive Activity (RCVACT) bit of the Diagnostic Status Register will be set to a logic "1" whenever activity (logic "1") is detected on the RXIN pin. The Token Seen (TOKEN) bit is set to a logic "1" whenever any token has been seen on the network (except those tokens transmitted by this node). The RCVACT and TOKEN bits may help the user to troubleshoot the network or the node. If unusual events are occurring on the network, the user may find it valuable to use the TXEN bit of the Configuration Register to qualify events. Different combinations of the RCVACT, TOKEN, and TXEN bits, as shown indicate different situations:
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6.8.1
Normal Results:
RCVACT=1, TOKEN=1, TXEN=0: The node is not part of the network. The network is operating properly without this node. RCVACT=1, TOKEN=1, TXEN=1: The node sees receive activity and sees the token. The basic transmit function is enabled. Network and node are operating properly. MYRECON=0, DUPID=0, RCVACT=1, TXEN=0, TOKEN=1: Single node network.
6.8.2
Abnormal Results:
RCVACT=1, TOKEN=0, TXEN=X: The node sees receive activity, but does not see the token. Either no other nodes exist on the network, some type of data corruption exists, the media driver is malfunctioning, the topology is set up incorrectly, there is noise on the network, or a reconfiguration is occurring. RCVACT=0, TOKEN=0, TXEN=1: No receive activity is seen and the basic transmit function is enabled. The transmitter and/or receiver are not functioning properly. RCVACT=0, TOKEN=0, TXEN=0: No receive activity and basic transmit function disabled. This node is not connected to the network. The Excessive NAK (EXCNAK) bit is used to replace a timeout function traditionally implemented in software. This function is necessary to limit the number of times a sender issues a FBE to a node with no available buffer. When the destination node replies to 128 FBEs with 128 NAKs or 4 FBEs with 4 NAKs, the EXCNAK bit of the sender is set, generating an interrupt. At this point the software may abandon the transmission via the "Disable Transmitter" command. This sets the TA bit to logic "1" when the node next receives the token, to allow a different transmission to occur. The timeout value for the EXNACK bit (128 or 4) is determined by the FOUR-NAKS bit on the Setup1 Register. The user may choose to wait for more NAK's before disabling the transmitter by taking advantage of the wraparound counter of the EXCNAK bit. When the EXCNAK bit goes high, indicating 128 or 4 NAKs, the "POR Clear Flags" command maybe issued to reset the bit so that it will go high again after another count of 128 or 4. The software may count the number of times the EXCNAK bit goes high, and once the final count is reached, the "Disable Transmitter" command may be issued. The New Next ID bit permits the software to detect the withdrawal or addition of nodes to the network. The Tentative ID bit allows the user to build a network map of those nodes existing on the network. This feature is useful because it minimizes the need for human intervention. When a value placed in the Tentative ID Register matches the Node ID of another node on the network, the TENTID bit is set, telling the software that this NODE ID already exists on the network. The software should periodically place values in the Tentative ID Register and monitor the New Next ID bit to maintain an updated network map.
6.9
OSCILLATOR
The COM20019I contains circuitry which, in conjunction with an external parallel resonant crystal or TTL clock, forms an oscillator. If an external crystal is used, two capacitors are needed (one from each leg of the crystal to ground). No external resistor is required, since the COM20019I contains an internal resistor. The crystal must have an accuracy of 0.020% or better. The oscillation frequency range is from 10 MHz to 20 MHz. The crystal must have an accuracy of 0.010% or better when the internal clock multiplier is turned on. The oscillation frequency must be 20MHz when the internal clock multiplier is turned on.
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The XTAL2 side of the crystal may be loaded with a single 74HC-type buffer in order to generate a clock for other devices. The user may attach an external TTL clock, rather than a crystal, to the XTAL1 signal. In this case, a 390 pull-up resistor is required on XTAL1, while XTAL2 should be left unconnected.
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Chapter 7
7.1
OPERATIONAL DESCRIPTION
MAXIMUM GUARANTEED RATINGS*
Operating Temperature Range .................................................................................................. 0oC to +70oC
o o Storage Temperature Range ................................................................................................-55 C to +150 C
Lead Temperature (soldering, 10 seconds) ....................................................................................... +325 oC Positive Voltage on any pin, with respect to ground ........................................................................VDD+0.3V Negative Voltage on any pin, with respect to ground ............................................................................. -0.3V Maximum VDD .......................................................................................................................................... +7V * Stresses above those listed may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other condition above those indicated in the operational sections of this specification is not implied. Note: When powering this device from laboratory or system power supplies, it is important that the Absolute Maximum Ratings not be exceeded or device failure can result. Some power supplies exhibit voltage spikes or "glitches" on their outputs when the AC power is switched on or off. In addition, voltage transients on the AC power line may appear on the DC output. If this possibility exists it is suggested that a clamp circuit be used.
7.2
DC ELECTRICAL CHARACTERISTICS
VDD=5.0V10% COM20019I: TA=0oC to +70oC, COM20019II: TA=-40oC to +85oC PARAMETER Low Input Voltage 1 (All inputs except A2, XTAL1, nRESET, nRD, nWR, and RXIN) High Input Voltage 1 (All inputs except A2, XTAL1, nRESET, nRD, nWR, and RXIN) Low Input Voltage 2 (XTAL1) High Input Voltage 2 (XTAL1) SYMBOL VIL1 MIN TYP MAX 0.8 UNIT V COMMENT TTL Levels
VIH1
2.0
V
TTL Levels
VIL2 VIH2 4.0
1.0
V V
TTL Clock Input
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PARAMETER Low to High Threshold Input Voltage (A2, nRESET, nRD, nWR, and RXIN) High to Low Threshold Input Voltage (A2, nRESET, nRD, nWR, and RXIN) Low Output Voltage 1 (nPULSE1 in Push/Pull Mode, nPULSE2, NTXEN) High Output Voltage 1 (nPULSE1 in Push/Pull Mode, nPULSE2, nTXEN) Low Output Voltage 2 (D0-D7) High Output Voltage 2 (D0-D7) Low Output Voltage 3 (nINTR) High Output Voltage 3 (nINTR) Low Output Voltage 4 (nPULSE1 in Open-Drain Mode) Dynamic VDD Supply Current Input Pull-up Current (nPULSE1 in Open-Drain Mode, A1, AD0-AD2, D3-D7) Input Leakage Current (All inputs except A1, AD0-AD2, D3-D7, XTAL1, XTAL2
SYMBOL VILH
MIN
TYP 1.8
MAX
UNIT V
COMMENT Schmitt Trigger, All Values at VDD = 5V
VIHL
1.2
V
VOL1
0.4
V
ISINK=4mA
VOH1 VOH1C VOL2 VOH2 VOL3 VOH3 VOL4
2.4 0.8 x VDD 0.4 2.4 0.8 2.4 0.5
V
ISOURCE=-2mA ISOURCE=-200A
V V V V V
ISINK=16mA ISOURCE=-12mA ISINK=24mA ISOURCE=-10mA ISINK=48mA Open Drain Driver 312.5 Kbps All Outputs Open VIN=0.0V
IDD IP
20 80 200
mA A
IL
10
A
VSS < VIN < VDD
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CAPACITANCE (TA = 25C; fC = 1MHz; VDD = 0V) Output and I/O pins capacitive load specified as follows: PARAMETER Input Capacitance Output Capacitance 1 (All outputs except XTAL2, nPULSE1 in Push/Pull Mode) Output Capacitance 2 (nPULSE1, in BackPlane Mode Only - Open Drain) SYMBOL CIN COUT1 MIN TYP MAX 5.0 45 UNIT pF pF COMMENT Maximum Capacitive Load which can be supported by each output.
COUT2
400
pF
AC Measurements are taken at the following points: Inputs: t t 2.4V 1.4V 0.4V t 2.4V 1.4V 0.4V 50% 0.8V t Inputs are driven at 2.4V for logic "1" and 0.4 V for logic "0" except XTAL1 pin. Outputs are measured at 2.0V min. for logic "1" and 0.8V max. for logic "0". 2.0V 50% 0.8V 2.0V Outputs:
Figure 7.1 - AC MEASUREMENTS
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Chapter 8
AD0-AD2, D3-D7 nCS
TIMING DIAGRAMS
VALID t1 t2, t4 t3
VALID DATA
t12 t6 t5 t7 t14 Note 2 t10
ALE nDS
t11
t13
t8 DIR t9
MUST BE: RBUSTMG bit = 0 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12 t13 t14 Address Setup to ALE Low Address Hold from ALE Low nCS Setup to ALE Low nCS Hold from ALE Low ALE Low to nDS Low nDS Low to Valid Data nDS High to Data High Impedance Cycle Time (nDS Low to Next Time Low) DIR Setup to nDS Active DIR Hold from nDS Inactive ALE High Width ALE Low Width nDS Low Width nDS High Width min 20 10 10 10 15 0 4TARB* 10 10 20 20 60 20 40 20 max units nS nS nS nS nS nS nS nS nS nS nS nS nS nS
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. Note 2: Read cycle for Address Pointer Low/High Registers occurring after an access to Data Register requires a minimum of 5TARB from the trailing edge of nDS to the leading edge of the next nDS.
Figure 8.1 - MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE
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AD0-AD2, D3-D7
VALID t1 t2, t4 t3
VALID DATA
nCS t10 t6 t5 t8 t12 Note 2 MUST BE: RBUSTMG bit = 0 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12 t13 Address Setup to ALE Low Address Hold from ALE Low nCS Setup to ALE Low nCS Hold from ALE Low ALE Low to nRD Low nRD Low to Valid Data nRD High to Data High Impedance Cycle Time (nRD Low to Next Time Low) ALE High Width ALE Low Width nRD Low Width nRD High Width nWR to nRD Low min 20 10 10 10 15 0 4TARB* 20 20 60 20 20 40 20 max units nS nS nS nS nS nS nS nS nS nS nS nS nS
ALE nRD
t9
t7
nWR
t13 Note 3
t11
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. Note 2: Read cycle for Address Pointer Low/High Registers occurring after a read from Data Register requires a minimum of 5TARB from the trailing edge of nRD to the leading edge of the next nRD. Note 3: Read cycle for Address Pointer Low/High Registers occurring after a write to Data Register requires a minimum of 5TARB from the trailing edge of nWR to the leading edge of nRD.
Figure 8.2 - MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE
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AD0-AD2, D3-D7 t1 nCS
VALID t2, t4 t3
VALID DATA
t12
ALE nDS
t11 t5 t7 t6 Note 2 t8** t13 t8
DIR t9
t14 t10
Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12 t13 t14 Address Setup to ALE Low Address Hold from ALE Low nCS Setup to ALE Low nCS Hold from ALE Low ALE Low to nDS Low Valid Data Setup to nDS High Data Hold from nDS High Cycle Time (nDS to Next DIR Setup to nDS Active DIR Hold from nDS Inactive ALE High Width ALE Low Width nDS Low Width nDS High Width
min 20 10 10 10 15 30 10 4TARB* 10 10 20 20 20 20
max
units nS nS nS nS nS nS nS nS nS nS nS nS nS nS
)**
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. The Microcontroller typically accesses the COM20019 on every other cycle. Note 1: Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. ** Note 2: Any cycle occurring after a write to Address Pointer Low Register requires a minimum of 4TARB from the trailing edge of nDS to the leading edge of the next nDS. Write cycle for Address Pointer Low Register occurring after an access to Data Register requires a minimum of 5TARB from the trailing edge of nDS to the leading edge of the next nDS.
Figure 8.3 - MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; WRITE CYCLE
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AD0-AD2, D3-D7 t1 nCS
VALID t2, t4 t3
VALID DATA
t10
ALE nWR
t9 t5 t7 t6 Note 2 t8**
nRD
t13
Note 3
t11
t12
t8
Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12 t13 Address Setup to ALE Low Address Hold from ALE Low nCS Setup to ALE Low nCS Hold from ALE Low ALE Low to nDS Low Valid Data Setup to nDS High Data Hold from nDS High Cycle Time (nWR to Next ALE High Width ALE Low Width nWR Low Width nWR High Width nRD to nWR Low
min 20 10 10 10 15 30 10 4TARB* 20 20 20 20 20
max
units nS nS nS nS nS nS nS nS nS nS nS nS nS
)**
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. The Microcontroller typically accesses the COM20019 on every other cycle. Note 1: Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. ** Note 2: Any cycle occurring after a write to Address Pointer Low Register requires a minimum of 4TARB from the trailing edge of nWR to the leading edge of the next nWR. Write cycle for Address Pointer Low Register occurring after a write to Data Register requires a minimum of 5TARB from the trailing edge of nWR to the leading edge of the next nWR. Note 3: Write cycle for Address Pointer Low Register occurring after a read from Data Register requires a minimum of 5TARB from the trailing edge of nRD to the leading edge of nWR.
Figure 8.4 - MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; WRITE CYCLE
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A0-A2 t1 nCS
VALID t2
t4 t3 nRD Note 3 t10 t6 VALID DATA CASE 1: RBUSTMG bit = 0 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 Address Setup to nRD Active Address Hold from nRD Inactive nCS Setup to nRD Active nCS Hold from nRD Inactive Cycle Time (nRD Low to Next Time Low) nRD Low to Valid Data nRD High to Data High Impedance nRD Low Width nRD High Width nWR to nRD Low min 15 10 5** 0 4TARB* 0 60 20 20 40** 20 max units nS nS nS nS nS nS nS nS nS nS t5 t8 t7 t9 Note 2
nWR D0-D7
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ** nCS may become active after control becomes active, but the access time (t6) will now be 45nS measured from the leading edge of nCS. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. ** Note 2: Read cycle for Address Pointer Low/High Registers occurring after a read from Data Register requires a minimum of 5TARB from the trailing edge of nRD to the leading edge of the next nRD. Note 3: Read cycle for Address Pointer Low/High Registers occurring after a write to Data Register requires a minimum of 5TARB from the trailing edge of nWR to the leading edge of nRD.
Figure 8.5 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE
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A0-A2 t1 nCS
VALID t2
t4 t3 nRD nWR D0-D7 Note 3 t10 t6 VALID DATA t5 t8 t7 t9 Note 2
CASE 2: RBUSTMG bit = 1 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 Address Setup to nRD Active Address Hold from nRD Inactive nCS Setup to nRD Active nCS Hold from nRD Inactive Cycle Time (nRD Low to Next Time Low) nRD Low to Valid Data nRD High to Data High Impedance nRD Low Width nRD High Width nWR to nRD Low min -5 0 -5 0 4TARB*+30 0 100 30 20 60** 20 max units nS nS nS nS nS nS nS nS nS nS
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ** t6 is measured from the latest active (valid) timing among nCS, nRD, A0-A2. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. Note 2: Read cycle for Address Pointer Low/High Registers occurring after a read from Data Register requires a minimum of 5TARB from the trailing edge of nRD to the leading edge of the next nRD. Note 3: Read cycle for Address Pointer Low/High Registers occurring after a write to Data Register requires a minimum of 5TARB from the trailing edge of nWR to the leading edge of nRD.
Figure 8.6 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; READ CYCLE
SMSC COM20019I
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A0-A2 t1 nCS t3 DIR nDS t8 D0-D7 t5
VALID t2
t4 t7 t6 t10 t9 VALID DATA CASE 1: RBUSTMG bit = 0 t11 Note 2
Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 Address Setup to nDS Active Address Hold from nDS Inactive nCS Setup to nDS Active nCS Hold from nDS Inactive DIR Setup to nDS Active Cycle Time (nDS Low to Next Time Low) DIR Hold from nDS Inactive nDS Low to Valid Data nDS High to Data High Impedence nDS Low Width nDS High Width
min 15 10 5** 0 10 4TARB* 10 0 60 20
max
units nS nS nS nS nS nS nS nS nS nS nS
40** 20
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ** nCS may become active after control becomes active, but the access time (t8) will now be 45nS measured from the leading edge of nCS. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. Note 2: Read cycle for Address Pointer Low/High Registers occurring after an access to Data Register requires a minimum of 5TARB from the trailing edge of nDS to the leading edge of the next nDS.
Figure 8.7 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE
Rev. 09-25-07
Page 54
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A0-A2 t1 nCS t3 DIR nDS t8 D0-D7 t5
VALID t2
t4 t7 t6 t10 t9 VALID DATA t11 Note 2
CASE 2: RBUSTMG bit = 1 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 Address Setup to nDS Active Address Hold from nDS Inactive nCS Setup to nDS Active nCS Hold from nDS Inactive DIR Setup to nDS Active Cycle Time (nDS Low to Next Time Low) DIR Hold from nDS Inactive nDS Low to Valid Data nDS High to Data High Impedence nDS Low Width nDS High Width min -5 0 -5 0 10 4TARB*+30 10 0 100 30 max units nS nS nS nS nS nS nS nS nS nS nS
60** 20
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ** t8 is measured from the latest active (valid) timing among nCS, nDS, A0-A2. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. Note 2: Read cycle for Address Pointer Low/High Registers occurring after an access to Data Register requires a minimum of 5TARB from the trailing edge of nDS to the leading edge of the next nDS.
Figure 8.8 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; READ CYCLE
SMSC COM20019I
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DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
A0-A2 t1 nCS
VALID t2
t4 nRD nWR t6 D0-D7 VALID DATA t7 Note 2 t5** Note 3 t10 t3 t8 t9 t5
t1 t2 t3 t4 t5 t6 t7 t8 t9 t10
Parameter Address Setup to nWR Active Address Hold from nWR Inactive nCS Setup to WR Active nCS Hold from nWR Inactive Cycle Time (nWR to Next )** Valid Data Setup to nWR High Data Hold from nWR High nWR Low Width nWR High Width nRD to nWR Low
min 15 10 5 0 4TARB* 30*** 10 20 20 20
max
units nS nS nS nS nS nS nS nS nS nS
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ***: nCS may become active after control becomes active, but the data setup time will now be 30 nS measured from the later of nCS falling or Valid Data available. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. **Note 2: Any cycle occurring after a write to the Address Pointer Low Register requires a minimum of 4TARB from the trailing edge of nWR to the leading edge of the next nWR. Write cycle for Address Pointer Low Register occurring after a write to Data Register requires a minimum of 5TARB from the trailing edge of nWR to the leading edge of the next nWR. Note 3: Write cycle for Address Pointer Low Register occurring after a read from Data Register requires a minimum of 5TARB from the trailing edge of nRD to the leading edge of nWR.
Figure 8.9 - NON-MULTIPLEXED BUS, 80XX-LIKE CONTROL SIGNALS; WRITE CYCLE
Rev. 09-25-07
Page 56
SMSC COM20019I
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
A0-A2 t1 nCS
VALID t2
t4 DIR t3 t5 nDS t10 t8 D0-D7 VALID DATA t9 t7 t11 Note 2 t6** t6
t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11
Parameter Address Setup to nDS Active Address Hold from nDS Inactive nCS Setup to nDS Active nCS Hold from nDS Inactive DIR Setup to nDS Active Cycle Time (nDS to Next Time DIR Hold from nDS Inactive Valid Data Setup to nDS High Data Hold from nDS High nDS Low Width nDS High Width
)**
min 15 10 5 0 10 4TARB* 10 30*** 10 20 20
max
units nS nS nS nS nS nS nS nS nS nS nS
* TARB is the Arbitration Clock Period TARB is identical to Topr if SLOW ARB = 0 TARB is twice Topr if SLOW ARB = 1 Topr is the period of operation clock. Same as the XTAL1 period. ***: nCS may become active after control becomes active, but the data setup time will now be 30 nS measured from the later of nCS falling or Valid Data available. Note 1: The Microcontroller typically accesses the COM20019 on every other cycle. Therefore, the cycle time specified in the microcontroller's datasheet should be doubled when considering back-to-back COM20019 cycles. **Note 2: Any cycle occurring after a write to the Address Pointer Low Register requires a minimum of 4TARB from the trailing edge of nDS to the leading edge of the next nDS. Write cycle for Address Pointer Low Registers occurring after an access to Data Register requires a minimum of 5TARB from the trailing edge of nDS to the leading edge of the next nDS.
Figure 8.10 - NON-MULTIPLEXED BUS, 68XX-LIKE CONTROL SIGNALS; WRITE CYCLE
SMSC COM20019I
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Rev. 09-25-07
DATASHEET
Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
nTXEN t1 t3 nPULSE1 t9 t4 nPULSE2 (Internal Clk) t5 t7 t6 t2 t8 LAST BIT (3200 nS BIT TIME) t13
t10 RXIN t11 Parameter t1 t2 t3 t4 t5 t6 t7 t8 t9 t13 t10 t11 t12
t12
min -25
typ 1600* 3200*
max 50
units nS nS nS nS nS nS nS nS nS nS nS nS nS
nPULSE2 High to nTXEN Low nPULSE1 Pulse Width nPULSE1 Period nPULSE2 Low to nPULSE1 Low nPULSE2 High Time nPULSE2 Low Time nPULSE2 Period nPULSE2 High to nTXEN High (First Rising Edge on nPULSE2 after Last Bit Time) nTXEN Low to first nPULSE1 Low** Beginning Last Bit Time to nTXEN High** RXIN Active Pulse Width RXIN Period RXIN Inactive Pulse Width
-25 800* 800* 1600* -25 5500 3900 10 20 1600* 3200*
50
50 5700 4100
Above values are for 312.5 Kbps. Other Data Rates are shown below. TDR is the Data Rate Period *t5, t6 = TDR/4 *t2, t7, t10 = TDR/2 *t3, t11 = TDR 7 **t9 = 4 x TDR +/- 100 nS **t13 =
5 4
x TDR +/- 100 nS
Figure 8.11 - BACKPLANE MODE TRANSMIT OR RECEIVE TIMING (These signals are to and from the differential driver or the cable)
Rev. 09-25-07
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SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
t1 4.0V XTAL1 1.0V Parameter t1 t2 t3 t4 t5 Input Clock High Time Input Clock Low Time Input Clock Period Input Clock Frequency* Frequency Accuracy*
t2
t3 50% of VDD
min 20 20 50 10 -200
typ
max
100 20 200
units nS nS nS MHz ppm
Note*: t4 and t5 are applied to crystal oscillaton. Figure 8.12 - TTL INPUT TIMING ON XTAL1 PIN
t1 nRESET
nINTR t2 Parameter t1 t2 nRESET Pulse Width*** nINTR High to Next nINTR Low EF = 0 EF = 1 min 5TXTL* TDR**/2 4TXTL* typ max units
Note*: TXTL is period of external XTAL oscillation frequency. Note**: TDR is period of Data Rate (i.e. at 312.5 Kbps, TDR = 3200 nS) Note***: When the power is turned on, t1 is measured from stable XTAL oscillation after VDD was over 4.5V.
Figure 8.13 - RESET AND INTERRUPT TIMING
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 9
9.1
Package Outlines
28 Pin PLCC Package Outline and Parameters
G E
PIN N O. 1
J F
A
B B1 D3 D2
R
J D1 D
J A1
C
D IM A A1 B B1 C D D1 D2 D3 E F G J R N OTES:
28L .160-.180 .090-.120 .013-.021 .026-.032 .020-.045 .485-.495 .450-.456 .390-.430 .300 R EF .050 BSC .042-.056 .042-.048 .000-.020 .025-.045
1. A ll dim ensions are in inches. 2. C ircle indicating pin 1 can appear on a top surface as show n on the draw ing or right above it on a beveled edge.
Rev. 09-25-07
Page 60
Base Plane
Seating Plane
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9.2
48 Pin TQFP Package Outline and Parameters
A A1 A2 D D/2 D1 E E/2 E1 H L L1 e W R1 R2 ccc ccc
MIN ~ 0.05 1.35 8.80 4.40 6.90 8.80 4.40 6.90 0.09 0.45 ~ 0o 0.17 0.08 0.08 ~ ~
NOMINAL ~ 0.10 1.40 9.00 4.50 7.00 9.00 4.50 7.00 ~ 0.60 1.00 0.50 Basic ~ ~ ~ ~ ~ ~
MAX 1.6 0.15 1.45 9.20 4.60 7.10 9.10 4.60 7.10 0.20 0.75 ~ 7o 0.27 ~ 0.20 0.0762 0.08
REMARK Overall Package Height Standoff Body Thickness X Span 1 /2 X Span Measure from Centerline X body Size Y Span 1 /2 Y Span Measure from Centerline Y body Size Lead Frame Thickness Lead Foot Length from Centerline Lead Length Lead Pitch Lead Foot Angle Lead Width Lead Shoulder Radius Lead Foot Radius Coplanarity (Assemblers) Coplanarity (Test House)
Note 1:
Controlling Unit: millimeter
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 10 APPENDIX A
This appendix describes the function of the NOSYNC and EF bits.
10.1
NOSYNC Bit
The NOSYNC bit controls whether or not the RAM initialization sequence requires the line to be idle by enabling or disabling the SYNC command during initialization. It is defined as follows: NOSYNC: Enable/Disable SYNC command during initialization. NOSYNC=0, Enable (Default): the line has to be idle for the RAM initialization sequence to be written, NOSYNC=1, Disable: the line does not have to be idle for the RAM initialization sequence to be written. The following discussion describes the function of this bit: During initialization, after the CPU writes the Node ID, the COM20019I will write "D1"h data to Address 000h and Node-ID to Address 001h of its internal RAM within 96uS. These values are read as part of the diagnostic test. If the D1 and Node-ID initialization sequence cannot be read, the initialization routine will report it as a device diagnostic failure. These writes are controlled by a micro-program which sometimes waits if the line is active; SYNC is the micro-program command that causes the wait. When the microprogram waits, the initial RAM write does not occur, which causes the diagnostic error. Thus in this case, if the line is not idle, the initialization sequence may not be written, which will be reported as a device diagnostic failure. However, the initialization sequence and diagnostics of the COM20019I should be independent of the network status. This is accomplished through some additional logic to decode the program counter, enabled by the NOSYNC bit. When it finds that the micro-program is in the initialization routine, it disables the SYNC command. In this case, the initialization will not be held up by the line status. Thus, by setting the NOSYNC bit, the line does not have to be idle for the RAM initialization sequence to be written.
10.2
EF Bit
The EF bit controls several modifications to internal operation timing and logic. It is defined as follows: EF: Enable/Disable the new internal operation timing and logic refinements. EF=0: (Default) Disable the new internal operation timing (the timing is the same as in the COM20020 Rev. B); EF=1: Enable the new internal operation timing. The EF bit controls the following timing/logic refinements in the COM20019I: A) Extend Interrupt Disable Time While the interrupt is active (nINTR pin=0), the interrupt is disabled by writing the Clear Tx/Rx interrupt and Clear Flag command and by reading the Next-ID register. This minimum disable time is changed by the Data Rate. Setting the EF bit will change the minimum disable time to always be more than 200 nS. This is done by changing the clock which is supplied to the Interrupt Disable logic. The frequency of this clock is always less than 20MHz . B) Synchronize the Pre-Scalar Output
Rev. 09-25-07
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The Pre-Scalar is used to change the data rate. The output clock is selected by CKP3-1 bits in the Set-Up register. The CKP3-1 bits are changed by writing the Set-Up register from outside the CPU. It's not synchronized between the CPU and COM20019I. Thus, changing the CKP3-1 timing does not synchronize with the internal clocks of Pre-Scalar, and changing CKP3-1 may cause spike noise to appear on the output clock line. Setting the EF bit will include flip-flops inserted between the Configuration register and Pre-Scalar for synchronizing the CKP3-1 with Pre-Scalar's internal clocks. C) Shorten The Write Interval Time To The Command Register The COM20019I limits the write interval time for continuous writing to the Command register. The minimum interval time is changed by the Data Rate. It's 800 nS at the 312.5 Kbps and 1.6 S at the 156.25 Kbps. This 1.6 S is very long for CPU. Setting the EF bit will change the clock source from OSCK clock (8 times frequency of data rate) to XTAL clock which is not changed by the data rate, such that the minimum interval time becomes 100 nS. D) Eliminate The Write Prohibition Period For The Enable Tx/Rx Commands The COM20019I has a write prohibition period for writing the Enable Transmit/Receive Commands. This period is started by the TA or RI bit (Status Reg.) returning to High. This prohibition period is caused by setting the TA/RI bit with a pulse signal. It is 3.2 S at 156.25 Kbps. This period may be a problem when using interrupt processing. The interrupt occurs when the RI bit returns to High. The CPU writes the next Enable Receive Command to the other page immediately. In this case, the interval time between the interrupt and writing Command is shorter than 3.2 S. Setting the EF bit will cause the TA/RI bit to return to High upon release of the pulse signal for setting the TA/RI bit, instead of at the start of the pulse. This is illustrated in Figure 10.1.
EF=0 TA/RI bit Setting Pulse nINTR pin
Tx/Rx completed
prohibition period
EF=1 Tx/Rx completed TA/RI bit Setting Pulse nINTR pin
Figure 10.1 - EFFECT OF THE EB BIT ON THE TA/RI BIT
SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
The EF bit also controls the resolution of the following issues from the COM20020 Rev. B: A) Network MAP Generation Tentative ID is used for generating the Network MAP, but it sometimes detects a non-existent node. Every time the Tentative-ID register is written, the effect of the old Tentative-ID remains active for a while, which results in an incorrect network map. It can be avoided by a carefully coded software routine, but this requires the programmer to have deep knowledge of how the COM20019I works. Duplicate-ID is mainly used for generating the Network MAP. This has the same issue as Tentative-ID. A minor logic change clears all the remaining effects of the old Tentative-ID and the old Duplicate-ID, when the COM20019I detects a write operation to Tentative-ID or Node-ID register. With this change, programmers can use the Tentative-ID or Duplicate-ID for generating the network MAP without any issues. This change is Enabled/Disabled by the EF bit. B) Mask Register Reset The Mask register is reset by a soft reset in the COM20020 Rev. A, but is not reset in Rev. B. The Mask register is related to the Status and Diagnostic register, so it should be reset by a soft reset. Otherwise, every time the soft reset happens, the COM20020 Rev. B generates an unnecessary interrupt since the status bits RI and TA are back to one by the soft reset. This is resolved by changing the logic to reset the Mask register both by the hard reset and by the soft reset. The soft reset is activated by the Node-ID register going to 00h or by the RESET bit going to High in the Configuration register. This solution is Enabled/Disabled by the EF bit.
Rev. 09-25-07
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SMSC COM20019I
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Cost Competitive ARCNET (ANSI 878.1) Controller with 2K x 8 On-Chip RAM
Chapter 11 APPENDIX B:
ISA Bus LS688x2 nG 12 bit Comparators Q P=Q 12 LS245 A 16 bit Bus Transceivers B 8 DIR nG D7-D0 12 I/O Address Seeting (DIP Switches)
AEN
SA15-SA4
P
COM20019 nCS
SD7-SD0 8
A
nIOR nIOW SA2-SA0 3 IRQm 3
nRD nWR A2-A0 nINTR
nIOCS16 DRQn nDACK TC nREFRESH nRESET
RESETDRV
Schmitt-Trigger Buffer
Figure 11.1 - EXAMPLE OF INTERFACE CIRCUIT DIAGRAM TO ISA BUS
SMSC COM20019I
Page 65
Rev. 09-25-07
DATASHEET

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