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rtmp-1 ut1553 remote terminal multi-protocol f e a t u r e s p complete mil-std-1553 remote terminal interface p mode selectable to comply with either mil-std- 1553a or mil-std-1553b bus protocol p mil-std-1773 compatible p remote terminal operation is certified by asd/ enasc (seafac) p implements all dual-redundant remote terminal mode codes and operational functions including broadcast commands p provides handshake control for quad-redundant systems p data pointers permit programmable memory mapping for 1553 data over the entire 64k host memory space p provides all handshaking signals for a dma interface p stores 1553 command word and time-tag information with all incoming data for enhanced data management p three-state address bus, databus, and control signals simplify dma operations p supports end-of-command activity and data bus error interrupts p self-test capability p available as a gate array macrocell p available in 84-pin pingrid array, 84-lead leadless chip carrier, or 84-lead flatpack packages p standard microcircuit drawing 5962-88645 available - qml q compliant i n t r o d u c t i o n the ut1553 rtmp (figures 1 and 4) is a monolithic, cmos, vlsi integrated circuit that meets all requirements for a dual-redundant mil-std-1553 remote terminal interface. the rtmp?s advanced design supports both mil-std-1553a and mil-std-1553b serial data bus protocols, including differences in the status word response time and bit definitions, providing the system designer a single-chip solution to most remote terminal interface requirements. the ut1553 rtmp provides all requisite 1553 protocol and data handling, 1553 message error checking, dma handshake and control signals, and comprehensive self-test capabilities. the rtmp?s pointer-based, programmable memory-mapping architecture permits the host to map 1553 message data anywhere in the 64k memory space. this advanced memory mapping, along with the rtmp?s control and status functions, minimize the host system?s 1553 interface overhead. the ut1553 rtmp is a member of utmc?s complete family of high-reliability monolithic mil-std-1553 interface products. 16 5 5 subaddress address terminal mode code/ 3 16 16 16 9 13 outputs control inputs control address memory control address memory data time tag control base ptr status last cmd logic control and error 12mhz reset master logic reset clock and timer logic transfer logic data command recognition mux out in a out in b decoder decoder encoder channel channel o u t p u t m u l t i p l e x i n g a n d s e l f - t e s t w r a p a r o u n d l o g i c figure 1. ut1553 rtmp functional block diagram
rtmp-2 table of contents 1.0 functional description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2.0 pin identification and description . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.0 remote terminal architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 3.1 internal registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 3.2 read/write register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 3.3 time tag data register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 3.4 control register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 3.5 base pointer data register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 3.6 read only registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 3.6.1 operational status register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 3.6.2 last 1553 command register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 3.7 write only register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.0 remote terminal interface operation . . . . . . . . . . . . . . . . . . . . . . 17 4.1 programming the bpd . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.2 rtmp pointer block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 4.3 pointer block location definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 4.4 rtmp data storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 4.5 rtmp interrupt function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 4.6 rtmp error detection capabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 4.6.1 terminal address parity errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 4.6.2 framing or overrun error . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 4.6.3 1553 message errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 4.7 rtmp self-test function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 5.0 1553a and 1553b modes of operation . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 5.1 status word bit definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 5.2 mode code responses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 5.3 status word response time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 6.0 rtmp system interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 6.1assigning the terminal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 6.2controlling the dma interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 6.3interfacing with the rtmp?s internal register . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 6.4rtmp hardware interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 6.4.1 rtmp -- 1553 transceiver interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 6.4.2 rtmp dma interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 7.0 maximum and recommended operating conditions 31 8.0 dc electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 9.0 ac electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 10.0 package outline drawings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
rtmp-3 f u n c t i o n a l d e s c r i p t i o n general description the rtmp is an interface device linking a mil-std-1553 serial data bus and a host microprocessor system (figure 2). by selecting the correct state of the 1553 protocol select pin (pra/ b = 1 for 1553a, 0 for 1553b), the system designer can program the rtmp to comply fully with either mil- std-1553a or mil-std-1553b. the link between the 1553 data bus and the rtmp is the shared memory area. all the data the rtmp transmits or receives over the 1553 bus is stored in this shared memory area. the rtmp accesses the shared memory with its dma signals ( dmar , dmag , and dmaen), the 16-bit bidirectional data bus (d0-d15), and the 16-bit address bus (a0-a15). since the rtmp?s architecture is based on a series of data pointers, the 1553 transmit and receive data can be placed anywhere in the 64k memory space, allowing the system designer to optimize memory usage. the system designer can program the rtmp to store the data received over the 1553 bus in one of two ways. the rtmp can store the received data in a single data buffer or in separate buffers. when the rtmp stores the received data in a single buffer, all received data, regardless of subaddress, is stored in contiguous locations in the shared memory. when the rtmp stores the received data in separate buffers, the rtmp stores the data associated with each of the 30 subaddresses in unique locations in memory. the rtmp has six internal registers that provide the host subsystem with rtmp control and status information. three of these registers are read/write: time tag data register (ttd), the control register (ctl), and the base pointer data register (bpd). two are read only: operational status register (ops), and the last command register (lcm). the stop self-test register (sst) is a write-only register. to control the rtmp and the 1553 interface, the host begins by programming the base pointer data register. by programming the bpd, the system designer tells the rtmp where in the shared memory the 64-word pointer block will reside, whether the rtmp will store the 1553 received data in single or separate buffers, and how deep these data buffers will actually be. figure 3 is a simple representation of the rtmp?s memory-mapping architecture. after the host has programmed the bpd, the 1553 interface is enabled by setting either chaen or chben in the rtmp?s control register. the rtmp now monitors the 1553 data bus for a valid command word or mode code to its particular terminal address. when received, the rtmp looks at the mode bit (single/separate) in the bpd, the 1553 command transmit/receive bit, and the mode code or subaddress portion of the 1553 command to determine which of the address pointers in the 64-word pointer block the rtmp will use for this particular memory transaction. each memory transaction consists of memory writes for receive command words and memory reads for transmit command words. this process continues until all 1553 data words have been received or transmitted. if the host has enabled any of the rtmp?s interrupts, the rtmp asserts them when the memory transaction is complete.
rtmp-4 address bus data bus control 1553 transceiver ut1553 rtmp host subsystem 64k x 16 shared ram 1553 bus a 1553 bus b ut63m125 figure 2. rtmp general system diagram lsb buffer mode select l s f u b 1 z i s b 2 z i s b 0 z i s b 3 z i s b 64k x 16 shared ram 0000h ffffh base pointer data register b p a 6 these ten bits form the address of the starting location of the 64-word pointer block. 64-word pointer block receive data pointer (30) transmit data pointer (30) receive subaddress data buffer - 8 to 32k words transmit subaddress data buffer the receive data buffer size is programmed with these four bits. msb figure 3. rtmp receiveand transmit data memory mapping
rtmp-5 2.0 p i n i d e n t i f i c a t i o n a n d d e s c r i p t i o n bidirectional pin. leadless chip carrier pinnumbers are not in parentheses. ( ) pingrid array pin numbers are in parentheses. (f3) (l5) (f10) (a7) (k11) (l11) (l2) (k2) (k3) (g11) (j6) (g10) (a2) (b11) (c11) (c10) (e9) (e10) (e11) (e3) (a5) (f9) (l7) (c1) (d2) (d1) (f2) (e2) (d10) (d11) (f11) (b4) (a4) (a6) (b5) (c5) (c6) (b6) (b7) (c7) (a8) (b8) (a9) (a10) (b9) (b10) (a11) (l1) (j2) (k1) (j1) (h2) (h1) (g3) (g2) (g1) (f1) (e1) (j5) (h11) (k8) (l9) (g9) (h10) (j11) (k5) (k6) (l4) (k4) (l3) (b3) (a3) (a1) (b2) (c2) (b1) (j7) (k9) (l10) (k7) (l6) (j10) (k10) (l8) a a a a a a a a a a a a a a a a 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 d d d d d d d d d d d d d d d d 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 address lines data lines taz tao tbz tbo raz rao rbz rbo rta0 rta1 rta2 rta3 rta4 rtpty mcsa0 mcsa1 mcsa2 mcsa3 mcsa4 biphase out biphase in mode code/ subaddress status signals terminal address dma signals control signals power ground clock reset clk 14 12 13 41 22 40 72 51 50 52 44 46 45 49 48 47 21 38 28 29 39 37 36 19 18 17 16 15 71 73 74 75 76 77 33 34 23 25 30 31 26 27 70 69 68 67 65 64 63 61 60 59 58 57 56 55 54 53 11 10 9 8 7 6 5 4 3 2 83 82 81 80 79 78 24 43 66 84 1 20 42 62 35 32 ++ ++ ++ ++ * ** pin internally pulled up. pin internally pulled down. eort eomc merr timeron cha/ b comstr mc /sa dmar * dmag *dmaen rd wr * cs av rrd rwr **tapen * svc **illcom **sme **enbc pra/ b **test v ss v dd v dd v dd v dd v ss v ss v ss reset figure 4. rtmp functional pin description
rtmp-6 legend for type and active fields: to = ttl output i = ttl input tui = ttl input (pull-up) tdi = ttl input (pull-down) tto = three-state ttl output ttb = three-state ttl bidirectioal ah =active high al = active low d15 78 c1 ttb bit 15 (msb) of the bidirectional data bus. data bus name pin number lcc pga type active description d14 d13 d12 d10 d9 d8 d7 d6 d5 d4 d3 d2 d1 d0 79 80 81 82 83 2 3 4 5 6 7 8 9 10 11 d2 d1 f2 e2 e1 f1 g1 g2 g3 h1 h2 j1 k1 j2 l1 ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb ttb bit 14 of the bidirectional data bus. bit 13 of the bidirectional data bus. bit 12 of the bidirectional data bus. bit 11 of the bidirectional data bus. bit 10 of the bidirectionaldata bus. bit 9 of the bidirectional data bus. bit 8 of the bidirectional data bus. bit 7 of the bidirectional data bus. bit 6 of the bidirectional data bus. bit 5 of the bidirectional data bus. bit 4 of the bidirectional data bus. bit 3 of the bidirectional data bus. bit 2 of the bidirectional data bus. bit 1 of the bidirectional data bus. bit 0 (lsb) of the bidirectional data bus. d11 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
rtmp-7 a15 53 a11 tto bit 15 (msb) of the address bus. address bus name pin number lcc pga type active description a14 a13 a12 a10 a9 a8 a7 a6 a5 a4 a3 a2 a1 a0 tto tto tto tto tto tto tto tto tto tto tto tto ttb ttb ttb bit 14 of the address bus. bit 13 of the address bus. bit 12 of the address bus. bit 11 of the address bus. bit 10 of the address bus. bit 9 of the address bus. bit 8 of the address bus. bit 7 of the address bus. bit 6 of the address bus. bit 5 of the address bus. bit 4 of the address bus. bit 3 of the address bus. bit 1 of the address bus. (reference a2) bit 0 (lsb) of the address bus. (reference a2) a11 54 55 56 57 58 59 60 61 63 64 65 67 68 69 70 b10 b9 a10 a9 b8 a8 c7 b7 b6 c6 c5 b5 a6 a4 b4 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- bit 2 of the address bus. address bits a2 - a0 are bidirectional so the host can select one of the rtmp?s internal registers during internal i/o operations. 47 f11 to name pin number lcc pga type active description dma signals al dma request. indicates the rtmp is requesting dmaen 48 49 d11 d10 tui tui al ah use of the data bus from the current bus master. dma enable. when high, this input allows the rtmp to recognize dmag . when low, dmaen places all three-state pins in a high-impedance state and disables the rtmp?s memory access cycle. dma grant. gives control of the data bus to the rtmp. dmag is recognized only if dmaen is high. dmag must remain asserted until av goes high to ensure that the rtmp completes the current dma cycle. dmag dmar
rtmp-8 sme illcom 44 e9 tui name pin number lcc pga type active description al 45 46 52 50 51 40 e11 e10 c10 c11 b11 g10 ti ti tto tto tto tui al al al al al al set message error. asserting this input causes the message error bit in thestatus word to be set. illegal command. this input illegalizes a command word that the rtmp accepts but the system does not support. when set, the rtmp responds with the message error bit set in the status word. illcom 41 22 g11 j6 tdi tdi ah ah control signals 12 k2 ti -- 13 14 k3 l2 tdi tdi ah ah enbc test enable broadcast. a high on this input, when the rtmp is in the 1553b mode, allows the rtmp to recognize a broadcast command word. is used in conjunction with the mode code/ subaddress outputs. cs rd wr av rrd rwr svc pra/ b chip select. this input, along with rd and wr , allows the host to access the rtmp?s internal data registers. read. when used in conjunction with cs , rd allows the rtmp to place data from the selected internal register on the data bus (d15-d0). write. when used in conjunction with cs , wr latches data from the data bus (d15-d0) into the selected rtmp internal register. address valid. the rtmp asserts av to indicate that the address (a15-a0) is valid. ram read. the rtmp asserts rrd during dma cycles that require data from system ram. ram write. the rtmp asserts rwr during dma cycles to write data to system memory. superseding valid command. the host system uses this input when more than one rt is present in the system; i.e., a quad-redundant system. when asserted, this input causes the rtmp to terminate all present activity and perform an internal reset of encoders/decoders, rt state machine, and dma state machine. registers are not affected. do not assert while dmar is asserted (tpw 250ns minimum). program a/ b . this input is the 1553 mode select input. a high input places the rtmp in the mil-std-1553a mode; a low places the rtmp in the mil-std-1553b mode. test. the test input pin allows the user to select between internal (test = 0) or external (test = 1) self-test. when test equals a logic one and dmaen equals a logic zero, mcsa (4:0) and mc /sa three-state.
rtmp-9 36 j11 tto name pin number lcc pga type active description al status signals merr 37 38 39 28 29 h10 h11 g9 k8 l9 tto to to to to al al ah -- al 21 j5 tto name pin number lcc pga type active description al mcsa0 mcsa1 mcsa2 mcsa3 mcsa4 15 16 17 18 19 l3 k4 l4 k6 k5 tto mode code/subaddress timer on. indicates the rtmp is transmitting data. the output remains active until the data transmission is complete or the internal fail-safe timer times out (600ms for 1553a and 800ms for 1553b). the rtmp internally disables both transmitters and keeps them disabled until the rtmp receives a valid command word. this signal is as- serted approximately 250ns before beginning of status word transmission. -- end of receive/transmit. this interrupt is a pulse that is maskable by writing to the control register. the user can select eort to occur at the end of receive command activity, at the end of transmit command activity, under either of these conditions, or disable it completely. the eort output is de- signed to simulate an open-collector output and requires a pull-up resistor. (250ns pulse width). this signal is not gen- erated if a message error condition exists. eort end of mode code. this non-maskable interrupt is a pulse that occurs at the end of all memory accesses associated with any mode code command. the eomc output is designed to sim- ulate an open-collector output and requires a pull-up resistor. eomc and eort can be logically ored together to form a composite interrupt. the 250ns pulse width is generated after command word is stored. this signal is not generated if a message error condition exists. eomc comstr cha/ b timeron message error. active when the rtmp detects an error in the 1553 transmission and sets the message error bit in the status word. merr is reset when the rtmp receives the next valid command word. ( comstr assertion) channel a/ b . when high, this output indicates the rtmp received the last command on channel a; when low, the last command was received on channel b. mode code/subaddress. mc /sa = 0 indicates that the mc- sao-mcsa4 pins contain the mode code bits of the most recently received mode code. mc /sa = 1 indicates that mcsa0-mcsa4 pins contain the subaddress bits of the most recently received command word. mc /sa mode code/subaddress. these five bits are used in conjunc- tion with the mc /sa output. mc /sa = 0 indicates that these five bits are the five least significant bits of the mode code command word. mc /sa = 1 indicates these five bits are the 1553 command word subaddress. command strobe. this low-going pulse identifies re- ceipt of a valid 1553 command word.
rtmp-10 rta4 73 b3 ti name pin number lcc pga type active description remote terminal address inputs. the rtmp uses remote terminal address these inputs to select the terminal address for this specific remote terminal. terminal address parity enable. enables the rtmp?s terminal address parity-checking remote terminal parity. when the terminal address parity-checking function is enabled (tapen = 1), rtpty must provide odd parity for the terminal address input pins (rta4-rta0). rta3 rta2 rta1 rta0 tapen rtpty 74 75 76 77 72 71 a1 b2 c2 b1 a2 a3 tdi ti ah 32 l11 ti name pin number lcc pga type active description master reset and clock rao 23 l6 ti name pin number lcc pga type active description receiver (channel) a one. manchester input from channel a biphase signals al clk 35 k11 ti the 1553 bus receiver. receiver (channel) a zero. this input is the complement of rao. transmitter (channel) a one. this manchester- encoded data output is connected to the 1553 bus transmitter input. the output is idle low. transmitter (channel) a zero. this output is the complement of tao. the output is idle low. raz tao taz 25 26 27 k7 j7 l8 ti to to function. -- -- -- -- -- -- -- reset reset. initializes all internal functions of the rtmp. reset must be asserted before normal rtmp operation. clock. the clock input requires a 50% 10% duty cycle with an accuracy of 12mhz 0.01%.
rtmp-11 3.0 r e m o t e t e r m i n a l a r c h i t e c t u r e 3.1 internal registers the rtmp has six internal registers that allow the host to control the rtmp?s actions and also to obtain its operational status. the host can read from or write to three of these registers: the time tag data register (ttd), the control register (ctl), and the base pointer data register (bpd). two of the registers are read-only: the operational status register (ops), and the last command register (lcm). the stop self-test register (sst) is a write-only register. six signals allow the host to access the rtmp?s internal registers. three of the six signals are control signals: chip select ( cs ), read ( rd ), and write ( wr ). the other three signals are the rtmp?s bidirectional address lines, a0 - a2. when the cs = 0, the three least significant address lines, a0 - a2, become inputs to the rtmp. the rtmp decodes these three address lines, along with cs , rd , and wr , to determine which of the six internal registers the host is attempting to access. table 1 shows the addresses for the rtmp?s internal registers for read and write operations. 3.2 read/write registers the rtmp has three internal read/write registers. these three registers are: the time tag data register the control register the base pointer data register time tag data register (ttd) the ttd contains a free-running, 16-bit, ripple counter. the time tag clock has a resolution of 64ms. the ttd is initialized to 0000h when the host asserts the reset input. all ttd bits are programmable by performing a write to the ttd with the desired bit pattern. the rtmp stores the ttd?s value in the shared memory area at the end of each 1553 receive message. the host can also directly read the ttd. since the ttd is a free-running counter, the host may read the ttd while the counter is rippling, resulting in the host reading erroneous data. if this situation presents a problem, the host should read the ttd data twice. figure 5 represents the ttd. (0000h after master reset.) rbo 33 k10 ti name pin number lcc pga type active description receiver (channel) b one. manchester data input channel b biphase signals from the 1553 bus receiver. receiver (channel) b zero. this input is the complement of rbo. transmitter (channel) b one. this manchester- encoded output is connected to the 1553 bus transmitter input. the output is idle low. transmitter (channel) b zero. this output is the complement of tbo. the output isidle low. rbz tbo tbz 34 30 31 j10 l10 k9 ti to to 24 l7 name pin number lcc pga type active description power and ground 43 66 84 1 20 42 62 f9 a5 e3 f3 l5 f10 a7 -- -- -- -- -- -- -- -- +5 v dc power. power supply input must be reference ground. zero v dc logic ground. v dd v ss
rtmp-12 table 1. rtmp internal register addresses 1. rtmp register write addresses a2 a1 a0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 0 1 0 1 time tag data register control register base pointer data register stop self-test register 2. rtmp register read addresses a2 a1 a0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 1 1 0 0 1 0 1 0 time tag data register control register base pointer data register operational status register last 1553 command register 0 0 1 x x don?t care 0 0 0 0 0 0 1 1 1 0 1 1 1 0 1 don?t care don?t care don?t care cs wr cs rd 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 c n t 1 5 c n t 1 4 c n t 1 3 c n t 1 2 c n t 1 1 c n t 1 0 c n t 9 c n t 8 c n t 7 c n t 6 c n t 5 c n t 4 c n t 3 c n t 2 c n t 1 c n t 0 msb lsb figure 5. the time tag data register
rtmp-13 3.4 control register (ctl) the ctl provides the host with the ability to control four functions: (1) programming the bits in 1553 status word; (2) masking the end of receive/transmit message activity interrupt (output pin eort ); (3) enabling and selecting the channel for the self- test; and (4) selecting the active 1553 channel. the definition of the 1553 status word bits in the ctl is different when the rtmp is operating in the 1553a mode (pra/ b = 1) as opposed to the1553b mode (pra/ b = 0). figure 6 shows the bit definitions in the ctl for the 1553a mode; figure 7 shows the definition for the 1553b mode. the host determines the ctl functions status by reading the ctl register. ctl bit definitions - 1553a mode bit 15 chaen [0] channel a enable. when chaen = 1, the rtmp responds to a 1553 command word or mode code on bus channel a. chaen = 0 disables the rtmp from responding to 1553 command word or mode code on 1553 bus channel a. bit 14 chben [0] channel b enable. when chben = 1, the rtmp responds to a 1553 command word or mode code on bus channel b. chben = 0 disables the rtmp from responding to 1553 command word or mode code on 1553 bus channel b. disable for internal self-test. bit 13 sten [0] self-test enable. sten enables the rtmp?s internal self-test. bit 12 stcs [0] self-test channel select. if the host has enabled an rtmp self-test (sten = 1), stcs selects the rtmp receiver channel to test. stcs = 1 selects channel a, and stcs = 0 selects channel b. bit 11 im1 [0] interrupt mask one. if im1 = 1, the eort interrupt output is active at the end of 1553 receive command memory activity. im1 = 0 masks this interrupt function. bit 10 im2 [0] interrupt mask two. if im2 = 1, the eort interrupt output is active at the end of 1553 transmit command memory activity. im2 = 0 masks this interrupt function. bit 9 swb10 [0] status word bit 10. when the host sets this bit, swb10 = 1, the bit in the rtmp?s status word that is transmitted during bit time ten is set (see figure 30 for status word bit time definitions). the bits in the status word are system-defined in mil-std-1553a. bit 8 swb11 [0] status word bit 11. when the host sets this bit (swb11 = 1), the bit in the rtmp?s status word transmitted during bit time 11 is set. bit 7 swb12 [0] status word bit 12. when the host sets this bit (swb12 = 1), the bit in the rtmp?s status word transmitted during bit time 12 is set. bit 6 swb13 [0] status word bit 13. when the host sets this bit (swb13 = 1), the bit in the rtmp?s status word transmitted during bit time 13 is set. bit 5 swb14 [0] status word bit 14. when the host sets this bit (swb14 = 1), the bit in the rtmp?s status word transmitted during bit time 14 is set. bit 4 swb15 [0] status word bit 15. when the host sets this bit (swb15 = 1), the bit in the rtmp?s status word transmitted during bit time 15 is set. bit 3 swb16 [0] status word bit 16. when the host sets this bit (swb16 = 1), the bit in the rtmp?s status word transmitted during bit time 16 is set. bit 2 swb17 [0] status word bit 17. when the host sets this bit (swb17 = 1), the bit in the rtmp?s status word transmitted during bit time 17 is set. bit 1 swb8 [0] status word bit 18. when the host sets this bit (swb18 = 1), the bit in the rtmp?s status word transmitted during bit time 18 is set. bit 0 tflg terminal flag. tflg = 1 sets the terminal flag bit in the 1553a status word. tflg = 0 resets the terminal flag bit in the 1553a status word.
rtmp-14 ctl bit definitions - 1553b mode bit 15 chaen [0] channel a enable. same as 1553a mode. disable for internal self-test. bit 14 chben [0] channel b enable. same as 1533a mode. disable for internal self-test. bit 13 sten [0] self-test enable. same as 1553a mode. bit 12 stcs [0] self-test channel select. same as 1553a mode. bit 11 im1 [0] interrupt mask one. same as 1553a mode. bit 10 im2 [0] interrupt mask two. same as 1553a mode. bit 9 instr [0] instrumentation bit. when instr = 1, the rtmp?s 1553 status word response has the instru- mentation bit set. this bit remains set until instr is set to 0. bit 8 svreq [0] service request bit. when svreq = 1, the rtmp?s 1553 status word response has the service request bit set. this bit remains set until svreq is set to 0. bit 7 n/a this bit is defined as a reserved bit in mil-std-1553b and is not used. setting this bit has no effect on the status word response. bit 6 n/a same as bit 7. bit 5 n/a same as bit 7. bit 4 bdcst [0] broadcast bit. when bdcst = 1, the rtmp?s 1553 status word response has the broadcast bit set. manual override; not cleared by receipt of next command. broadcast bit in outgoing status word is set to a logical one on the receipt of broadcast command. bit 3 busy [0] busy bit. when busy = 1, the rtmp?s 1553 status word response has the busy bit set. this bit remains set until is set to 0. bit 2 sflg [0] subsystem flag. when sflg = 1, the rtmp?s 1553 status word response has the subsystem flag bit set. this bit remains set until sflg is set to 0. bit 1 n/a same as bit 7. bit 0 tflg [0] terminal flag. same as 1553a mode. 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 c h a e n c h b e n s t e n s t c s i m 1 i m 2 s w b 1 t f l g figure 6. the control register in 1553a mode msb lsb 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 n / a b u s y t f l g figure 7. the control register in 1553b mode msb lsb 0 s w b 1 1 s w b 1 2 s w b 1 3 s w b 1 4 s w b 1 5 s w b 1 6 s w b 1 7 s w b 1 8 c h a e n c h b e n s t e n s t c s i m 1 i m 2 i n s t r s v r e q n / a n / a b d c s t s f l g n / a
rtmp-15 3.5 base pointer data register the bpd provides three types of information: (1) the location in memory for the 64-word pointer block; (2) the receive-data storage-buffer select for either single or separate data buffers; and (3) the size or depth of the single or separate data buffe rs (figure 8). (0000h after master reset.) bpd bit definitions bit 15- bpa15-bpa 6 block pointer address. these ten bits provide the rtmp with the bit 6 ten most significant address lines for the location, within the 64k word addressing range, of the 64-word pointer block. bit 5 n/a this bit is not used. bit 4 bufsl buffer select. when bufsl = 1, the host selects the rtmp?s single buffer mode of storing 1553 receive data. if bufsl = 0, the host selects the separate buffer mode of storing 1553 receive data. bit 3- bsiz3-bsiz0 buffer size select. these four bits select the size of the receive data bit 0 buffers and can range from 3 (0011b) to 15 (1111b). the actual size of the data buffer is equal to 2 x where x is the decimal equivalent of bsiz3-bsiz0. the size of the data buffers can range from eight (2 3 ) words to 32k (2 15 ) words. the variable x is not defined for zero through two. 3.6 read only registers the rtmp has two internal registers that are read-only. these two registers provide status information on the operation of the rtmp: the operational status register the last 1553 command register 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 b p a 1 5 1 4 1 3 1 2 1 1 1 0 9 8 7 6 n / a msb lsb b p a b p a b p a b p a b p a b p a b p a b p a b p a s l b u f z 3 b s i z 2 b s i z 1 b s i z 0 b s i figure 8. the base pointer data register
rtmp-16 3.6.1 operational status register (ops) the ops provides the host with the operational status of the rtmp while the rtmp is active. figure 9 shows the information bits stored in the ops. ops bit definitions bit 15 mact [0] message active. mact = 1 indicates that the rtmp is actively processing a message. the rtmp clears mact upon completing the message. bit 14 vmpro [0] valid message processed. vmpro = 1 indicates that the rtmp has processed a valid 1553 message. the host clears vmpro bit when the ops is read. bit 13 me [0] message error. me = 1 indicates that a 1553 message error has occurred. the host clears me when the ops is read unless the condition that caused the merr still persists after the register read. bit 12 pe [x] parity error. pe = 0 indicates that the rtmp has detected an error in the terminal address parity. this bit can only be active when tapen = 1. bit 11 stact [0] self-test active. stact = 1 indicates that the rtmp is performing a built-in self-test. bit 10 bdcen [x] broadcast enable. bdcen = 1 indicates that the rtmp will accept a 1553 broadcast command as a valid command. bit 9 tfgen [1] terminal flag enable. when the rtmp is in the 1553b mode, tfgen = indicates that the terminal flag option is set. mode code 00110 (inhibit terminal flag) will clear this bit. bit 8 chaen [0] 1553 channel a enable. chaen = 1 indicates that channel a is enabled and ready to process 1553 bus messages. bit 7 chben [0] 1553 channel b enable. chben = 1 indicates that channel b is enabled and ready to process 1553 bus messages. bit 6 msel [x] mode select. when msel = 1, the rtmp is in the 1553a mode of operation. msel = 0 indicates the rtmp is in the 1553b mode of operation. bit 5 mdrcv [0] mode received. mdrcv = 0 indicates that the last valid 1553 command the rtmp received was a mode command. bit 4 xmtac [0] transmitter active. xmtac = 1 indicates that the rtmp?s transmitter is transmitting data. bit 3 ilcmd [x] illegal command. ilcmd = 1 indicates that the last 1553 command the rtmp received was illegal. ilcmd is cleared when the host reads the ops. in 1553a mode, this bit reflects input pin illcom. in 1553b mode, this bit reflects either input pin illcom or internal hardware. internal illegalization is reviewed in table 2. bit 2 cha/ b [0] channel a or . cha/ b = 1 indicates that the last valid 1553 command word the rtmp received was on channel a. cha/ b = 0 indicates that the last valid command word was on channel b. bit 1 vcmd [0] valid 1553 command. vcmd = 1 indicates that the last command word the rtmp received was valid. vcmd is reset when the host reads the ops. bit 0 oe [0] overrun error (framing error). oe = 1 indicates that the rtmp has detected an overrun error. this bit is reset when the host performs an ops read unless the error condition persists. 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 m a c c r o c t e n l msb lsb v m p m e p e s t a b d c m s e a c x m t m d i l c / b c h a d v c m 0 e e n t f g e n a c h e n b c h c v m d r figure 9. the operational status register
rtmp-17 3.6.2 last 1553 command register (lcm) the rtmp stores the last valid 1553 command word it received in the lcm. the only exception is if the rtmp is in the 1553b mode and it receives a transmit last command word mode code. figure 10 shows the configuration of the lcm. (0410h after master reset.) 3.7 write only register the rtmp has one register that is write only. this register is the stop self-test register (sst). the host can terminate the rtmp?s self-test execution by writing to the sst. when the host performs a write to the sst, the rtmp terminates all memory activity. the self-test enable (sten) bit in the ctl is also reset, and the self-test active (stact) bit in the ops is reset. when writing to the sst, the 16-bit data word is a don?t care. 4.0 r e m o t e t e r m i n a l i n t e r f a c e o p e r a t i o n the rtmp?s remote terminal interface is based on a shared memory concept where the shared memory is the link between the mil-std-1553 data bus and the host subsystem (figure 11). all 1553 data, whether transmitted or received, must at one time be stored in this defined memory area. the rtmp accesses the shared memory area with a conventional direct memory access (dma) interface. since the rtmp can access data anywhere within the 64k memory space, the host has to specify exactly where in memory the data associated with each valid transmit or receive command word or mode code is located. the host specifies the 1553 data area locations by programming the rtmp?s base pointer data register (bpd) and by initializing the 64-word pointer block. the bpd tells the rtmp where in memory the pointer block is located. the pointer block in turn specifies the location in memory where the data associated with each valid command word or mode code resides. therefore, to control the rtmp?s operation, the host first programs the bpd to provide the rtmp with three essential pieces of information: (1) the location in memory of the 64- word pointer block; (2) the type of data buffer -- single or separate; and (3) the receive data buffer size. the host can update the base pointer data register if a new 64-word pointer block needs to be selected, but do not update the bpd while the rtmp is processing a message transaction. figure 8 shows the bpd. 4.1 programming the bpd the host programs the ten most significant bits of the bpd (bpa15 - bpa6) to point to the starting address of the 64- word pointer block within the rtmp?s 64k address space. the rtmp generates the least significant six address lines to determine which of the words within the 64-word pointer block to use for a specific 1553 transmission. the rtmp does this by detecting the t/ r bit and the subaddress bits of the last 1553 command word (figure 12). usually the six least significant address lines, bpa5-bpa0, are part of the t/ r bit and subaddress or mode code bits of the last command word, respectively. in some cases, bpa5-bpa0 are forced to specific values: (1) when the rtmp stores the command word on the data buffer; (2) when the single buffer mode of operation is chosen; and (3) when a mode code is received. the data buffer mode bit, bufsl, is the next bit in the bpd that the host programs. the state of bufsl determines whether the rtmp stores the 1553 receive data in a single data buffer (bufsl = 1) or in separate data buffers (bufsl = 0). finally, the host programs bits bsiz3-bsiz0 in the bpd to tell the rtmp how large to make the separate data buffers. a formula determines the size of the data buffer(s): take the decimal equivalent of the binary number represented by bsiz3-bsiz0, where bsiz3 is the msb. this number, represented by x, can range in size from three to fifteen. the actual size of the data buffers is equal to 2. this means the data buffers can range from 8 to 32k words in length. in the single buffer mode, bits bsiz3-bsiz0 determine the size of this single buffer. in the separate buffer mode, all data buffers are the same size. this means the system designer must program the buffer size so the largest possible message the rtmp can receive over the 1553 bus fits within the programmed buffer size. 4.2 rtmp pointer block the rtmp?s pointer block is a contiguous block of 64, 16- bit words. the rtmp uses this block of data as the actual address pointer locations for the memory accesses associated with each 1553 message transaction. therefore, the pointer block is divided into receive data pointers, of which one location is for the single buffer mode, transmit data pointers, a mode code command pointer location, and a location for the current 1553 command word (figure 13). the host must initialize the pointer block before enabling the rtmp?s 1553 receivers 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 t a 4 msb lsb t / r s a 4 t a 3 t a 2 t a 1 t a 0 s a 3 s a 2 s a 1 s a 0 w c 4 w c 3 w c 2 w c 1 w c 0 x
rtmp-18 the host can program the 16-bit pointer addresses that make up the pointer block to point to any memory location in the rtmp?s 64k memory space. in this respect, the host has total flexibility to determine where in ram it stores the actual transmit, receive, and mode code data. the rtmp?s data storage flexibility allows the host to buffer 1553 receive messages and maintain data integrity. the host can update the pointer data within the pointer block at any time, but the recommended procedure is for the host not to update the pointer data for 1553 receive command data while the rtmp is actively processing a message. to prevent this action, the host can program the rtmp to generate an end-of-activity interrupt for every valid 1553 message with associated data words. in addition, the host can read the operational status register to determine if the rtmp is active. the rtmp uses the present 1553 command word and the selected mode of operation, single or separate mode, to determine which pointer within the 64-word pointer block to use as an address pointer for the memory accesses during 1553 message activity. the 1553 command word t/ r bit and the subaddress bits, or the mode code bits for a mode command, specify the exact location of the address pointer in the pointer block for transmit, receive, and mode code command words. if the host has selected the single mode of operation, the rtmp forces selection of the address pointer stored in the single mode location for all receive commands. the rtmp stores the present command word in the first address bus data bus control 1553 transceiver ut1553 rtmp host subsystem 1553 bus a 1553 bus b 64k x 16 shared ram 64-word pointer block receive data buffer(s) transmit data buffer(s) these three blocks can ut63m125 reside anywhere in the 64k memory space. figure 11. the memory link between the rtmp and the host subsystem
rtmp-19 4.3 pointer block location definitions for the following description of the pointer block locations, please refer to figure 13. command word data - location 0-0h of the pointer block contains the last valid 1553 command word the rtmp received. bit times 4 through 19 (figure 14) of the 1553 command word are stored in bit positions 15 through 0, respectively. the rtmp updates this location with the most recent command word except when the rtmp is in the 1553b mode and it receives a transmit last command mode code. separate mode, receive data pointers - pointer block address locations 1-30 (01h-1eh) contain the pointer values for each receive command word subaddress if the rtmp is operating in the separate mode (bit 4 of the bpd = 0). the rtmp selects the address pointer data from one of these locations by using the subaddress of the most recent receive command word. the rtmp internally stores this pointer value. this stored pointer value points to the memory location where the rtmp stores the received data associated with this subaddress. after the rtmp has stored all data associated with this subaddress in memory, the rtmp stores the updated pointer value back into the selected location in the pointer block. the updated pointer value points to the next available location in memory. base pointer data register msb b p a 15 b p a 6 t/r bit subaddress this data is from the current 1553 command word 10 most significant address lines 6 least significant addresslines 16 1553 data address the 16-bit addresspoints to a specific location in the 16-bit word pointer block 64-word pointer figure 12. constructionof the block pointer address (bpa) bits 3f 3e 3d 22 21 20 1f 1e 1d 02 01 00 not used subaddress 30 pointer subaddress 29 pointer subaddress 1 pointer subaddress 2 pointer pointer mode code data pointer single buffer mode subaddress 30 pointer subaddress 29 pointer current 1553 command word subaddress 1 pointer subaddress 2 pointer pointer block location (h) figure 13. the 64-word pointer block
rtmp-20 single mode, data pointer - when the host selects the single mode of operation (bit 4 of the bpd = 1), the pointer value at location 31 (1fh) of the pointer block is the address the rtmp uses to store all 1553 receive data, regardless of the command word?s subaddress. after the rtmp has stored all data associated with a 1553 receive command word, the rtmp stores an updated pointer value back into location 31 of the pointer block. the updated pointer value points to the next available location in memory. mode code pointer - the rtmp uses the pointer value stored in location 32 (20h) of the pointer block when it recognizes a valid mode code command with an associated data word. a mode code with data word is only valid when the rtmp is operating in the 1553b mode. when the rtmp is operating in the 1553a mode, it does not recognize or process any mode code with an associated data word. 1553a mode: no mode codes with data word al- lowed. 1553a mode: mc /sa field = 00000 or 11111 is a mode code. 1553b mode: mc /sa field = 00000 or 11111 is a mode code. the rtmp stores the pointer value from location 32 internally. the rtmp uses bits 15-4 of this pointer value to point to a memory location of a data block containing the data words associated with each mode code. bits 3-0 of the pointer address are the four least significant bits of the mode code the rtmp received. these four bits specify the data word within this data block that the rtmp uses for this specific mode code. figure 15 shows how the rtmp handles mode codes with associated data words. transmit data pointers - pointer block address locations 33 - 62 (21h-3eh) contain the pointer values for each of the 1553 transmit command word subaddresses. the rtmp 1 5 5 1 5 code mode count/ word mode address/ sub- r / t address terminal remote sync 2 0 9 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 1 1 1 9 8 7 6 5 4 3 2 1 times bit word com- r a p mand figure 14. command wordbit-time definitions mode command sync terminal address t / r 00000 mode code p a r four lsbs of the mode code 4 a mode code 20h 64-word pointer block mode code data block 12 location twelve msbs of the stored address 16 word data word for this mode code 16 this 16-word block can be located anywhere in the 64k memory space. mode code with data word points to this location. data address (1) note: 0000 transmit vector word 0011 transmit bit word 0001 synchronize with data 0100 selected transmitter shutdown 0010 transmit last command 0101 override selected transmitter shutdown figure 15. mode code with associated data word memory mapping
rtmp-21 selects the address pointer data from one of these locations using the subaddress of the most recent valid command word. the rtmp internally stores this pointer value. this stored pointer value points to the memory location where the rtmp accesses the data to transmit with this subaddress. every rtmp memory access for transmitted data increments the pointer value by one until the rtmp has transmitted all data. only the host can update the pointer values stored in the pointer block. therefore, if the host requires transmit data buffering, the host must control the pointer values stored in the pointer block. no identification word or time tag is associated with transmit commands. note that the rtmp does not use address location 63 (3fh) of the pointer block. 4.4 rtmp data storage the rtmp uses two modes of allocating memory for 1553 receive messages: (1) the single buffer mode, and (2) the separate buffer mode. the user selects the buffer mode by programming bit 4 (bufsl) of the base pointer data (bpd) register. both modes of operation are based on a ring-buffer type of memory mapping. ring-buffer memory mapping means the rtmp stores all incoming 1553 data words sequentially in memory starting with an initial address value. the initial address value is one of the address values stored in the 64- word block pointer. note that the initial pointer address must be set up on a boundary consistent with the chosen buffer size. example: if the buffer size is sixteen (0010h), the initial pointer address must be some multiple of sixteen. after the rtmp selects an address pointer within the pointer block, it loads the selected address pointer into an internal up-counter. every time the rtmp performs a memory store operation, the up-counter increments by one. therefore, the address pointer always points to the next sequential memory location. the rtmp continues to increment the address pointer until it reaches the programmed buffer size, which the user programs with bits 3 through 0 of the bpd (bsiz3- bsiz0). when the rtmp reaches the programmed buffer size, the internal up-counter ripples over; i.e., it returns to all zeros. at this time, the address pointer once again points to the initial block boundary memory address. to avoid the possibility of corrupting the initial receive data after the up- counter has rippled over, the user must read the data in the block before this event occurs. after the rtmp completes all memory accesses, the rtmp stores the updated address pointer in its initial 64-word pointer block location. when the user chooses the single buffer mode of operation (bufsl = 1), the rtmp always accesses the same address pointer within the 64-word pointer block for every 1553 receive command. since the rtmp stores all 1553 data words in the same buffer during this mode of operation, the user needs to program the buffer size large enough to allow the rtmp to store several 1553 messages before it overwrites the data at the beginning of the buffer. when the user chooses the separate buffer mode of operation (bufsl = 0), the rtmp uses the subaddress of the present 1553 command word to select which of the address pointers within the 64-word pointer block it will use to store the received data. therefore, the user can define up to 30 separate data buffers, one for each receive subaddress, anywhere in memory. the starting memory location of each buffer is stored in the receive section of the pointer block. in the separate buffer mode, the user needs to program the buffer size so it is large enough to keep the rtmp from overwriting the current data in any of the separate data buffers if the rtmp receives a new message with the same subaddress before the host can read the data from that data buffer. figures 16a and 16b show how each mode operates for a sample receive transmission. in addition to the data words associated with a receive command, the rtmp also stores two additional words, an identification word, which the rtmp stores immediately before the data words, and a time tag word, which the rtmp stores immediately after the data words. the identification word is the 1553 command word associated with the data in this data block, and the time tag word is the output of the time tag register. command word bit time four (figure 14) is stored as the msb of the identification word and command word bit time 19 is stored as the lsb of the identification word. therefore, each receive message requires two additional memory locations to allow the rtmp to store the message successfully. for example, a receive message with twelve data words actually requires fourteen memory locations. therefore, the user needs to program the buffer size to be sixteen (2 4 ) since buffer sizes defined in the bpd can only be a length of two raised to an integer power from three to fifteen. if, on the other hand, a receive message has fifteen data words, this message actually requires seventeen memory locations. in this case, the user must program a buffer size of 32 (2 5 ), since this is the next power of two that accommodates seventeen data words. in the separate buffer mode of operation, the rtmp makes all buffers the same length. therefore, the host must be sure to program the rtmp so the buffer size is large enough to accommodate the largest message the rtmp can receive for any subaddress. 4.5 rtmp interrupt functions the rtmp has two outputs that provide the host subsystem processor with interrupt control capability: (1) the end of receive/transmit message activity ( eort ) interrupt; and (2) the end of mode code activity ( oemc ) interrupt. the host subsystem can use these two outputs in conjunction with the information the operational status register (ops) provides to determine the condition of the rtmp after an interrupt condition occurs.
rtmp-22 the end of receive/transmit message activity ( eort ) interrupt is a maskable interrupt the user can select to occur (1) only when the 1553 receive command activity is complete; (2) only when the 1553 transmit command activity is complete; or (3) when either receive or transmit command activity is complete. the host masks the eort interrupt by resetting the appropriate bits (bit 11-im1 and bit 10-im2) in the rtmp?s control register (ctl). im1 = 0 keeps eort from occurring at the end of receive command activity. im2 = 0 keeps eort from occurring at the end of transmit command activity. if the host does not mask either im1 or im2, the eort interrupt pulses low. this pulse occurs at the end of either the receive or transmit command activity. the end of mode code activity ( eomc ) interrupt is a non- maskable interrupt. the eomc interrupt, like the eort interrupt, is also a low pulse, except the eomc interrupt occurs at the end of all memory accesses associated with any 1553 mode code command. both eort and eomc require an external pull-up resistor and, if necessary, the user can wire-or the two outputs together to form a composite rtmp interrupt. if any one of the following conditions occurs during normal rtmp operation, the rtmp does not generate either the eort or the eomc interrupt: (1) if a message error occurs; (2) if a framing (overrun) error occurs; (3) if the rtmp receives an illegal 1553 command; (4) if the rtmp receives a superseding command word; or (5) if the busy bit in the control register is set (1553b mode of operation only). 4.6 rtmp error detection capabilities the rtmp provides the host with significant error- detection capabilities. the rtmp can detect the following types of errors: terminal address parity errors framing or overrun errors 1553 message errors 4.6.1 terminal address parity errors the rtmp can check the the terminal address parity inputs (rta4-rta0) when the terminal address parity enable (tapen) input is active high. if tapen = 1, then rta4- cwd1 cwd1 dwd1 dwd2 dwd3 swd dwd4 dwd5 dwd6 dwd7 swd 1553 bus activity s/a=21 s/a=0a 64-word pointer block 1553 command word receive pointers (30) single mode pointer = 0100h mode code data pointer transmit pointer (30) 64k data ram id word 1 dwd1 dwd2 dwd3 time tag 1 id word 2 dwd4 dwd5 dwd6 dwd7 time tag 2 0100h 010ah 1000h 101fh 0105h figure 16a. rtmp single buffer mode of operation note: after the rtmp stores the first set of data, the next available address (0105h) is stored inlocation 10fh.
rtmp-23 rta0 and the remote terminal parity (rtpty) input must provide the rtmp with odd parity, or the rtmp flags a terminal address parity error. for example: if the ta = 01000, then rtpty must equal 0 to prevent a parity error. if the ta = 00110, then rtpty must equal 1 to prevent a parity error. if the rtmp detects a terminal address parity error, this error prevents the rtmp from recognizing any valid commands on either channel, preventing the rtmp from responding to a 1553 command word not actually intended for this remote terminal. 4.6.2 framing or overrun errors a framing error occurs when the rtmp is not permitted to access memory at a sufficient rate to service the requirements of the 1553 data bus. for receive messages, after the rtmp generates a dma request ( dmar ) signal, the host must generate a dma grant ( dmag ) signal before the rtmp receives the next incoming data word to prevent a framing error. for transmit messages, after the rtmp generates dmar , the host must generate a dmag before the rtmp completes transmitting the previous 1553 data word to prevent a framing error. when a framing error occurs during a receive command, all rtmp memory accesses cease. when a framing error occurs during a transmit command, the rtmp terminates all data transmissions. the worst-case timing for receive commands requires the rtmp to make four memory accesses within 40ms. the worst-case timing for transmit commands depends on whether the rtmp is operating in 1553b or 1553a mode. when the rtmp is operating in the 1553a mode, the worst-case timing requires the rtmp to make three memory accesses within 22ms; when in the 1553b mode, the worst-case timing requires the rtmp to make three memory accesses within 28ms. the difference in the timing here is due to the difference in the status word response time between 1553a and 1553b. the worst-case timing for a transmit command consists of the remote terminal response time, which is mode- dependent, and the time it takes to transmit the 1553 status word (20ms). during this time, the rtmp must fetch the address pointer from the 64-word pointer block, store the 1553 command word in the first location of the pointer block, then fetch the first data word from memory before it completes transmitting the status word. 1000h 0100h time tag 2 dwd7 dwd6 dwd5 dwd4 id word 2 time tag 1 dwd3 dwd2 dwd1 id word 1 64k data ram word 1553 command block 64-word pointer s/a=0a s/a=21 1553 bus activity swd dwd7 dwd6 dwd5 dwd4 swd dwd3 dwd2 dwd1 cwd1 cwd1 subaddress oa pointer = 0100h subaddress 21 pointer = 0200h subaddress 30 pointer 100ah 1021h 0200h receive pointers figure 16b. rtmp separate buffer mode of operation
rtmp-24 when the rtmp detects a receive command word, it must make four separate memory accesses before it receives the second 1553 data word. the rtmp must (1) fetch the appropriate address pointer from the 64-word pointer block; (2) store the 1553 command word in the first location of the pointer block; (3) store the identification word at the memory location pointed to by the address pointer; and (4) store the first received data word in the memory location immediately after the identification word. 4.6.3 1553 message errors the rtmp sets the message error bit in the 1553 status word and also asserts the merr output if the rtmp detects a failure in one of the following areas. 1553 data word tests: invalid sync field for any data word incorrect manchester ii format incorrect data word or command word parity too few data bits per word too many data bits per word too few data words per message too many data words per message (1553b mode only) non-contiguous data words rt-to-rt transfer tests: during an rt-to-rt command sequence, the rtmp monitors the 1553 bus and compares the terminal address of the transmit command word with the terminal address of the status word from the transmitting rt. the rtmp declares the rt-to-rt transfer invalid if no match occurs. the rtmp then sets the message error bit. the rtmp also sets the message error bit if it detects one of the following errors: data word transmission before the status word transmission excessive time before the transmitting rt sends the status word any deviation from the proper sequence of events for rt-to-rt transfers illegal mode commands: when the rtmp is operating in the 1553a mode, it does not automatically declare any received mode code as illegal. to illegalize any mode code, the rtmp outputs the mode code/subaddress outputs (mcsa0-mcsa4) along with the mode code/subaddress status signal ( mc /sa). the host uses these signals to decode when the rtmp receives a mode code and what mode code was received. if the mode code is illegal for this application, the host asserts the rtmp?s illegal command (illcom) input and the message error bit is set in the rtmp?s 1553 status word response. when the rtmp is operating in the 1553b mode, it automatically illegalizes the following mode codes: mode code 00000 - dynamic bus control reserved mode codes 01001 through 01111 (no associated data word) reserved mode codes 10110 through 11111 (with associated data word) in these cases, the rtmp status word response has the message error bit set. 4.7 rtmp self-test functions the rtmp performs a self-test by wrapping the encoder output back into the decoder inputs. self-test is either internal or external to the rtmp. an internal self-test wraps the rtmp encoder output back into the decoder input via a multiplexer internal to the rtmp. external self-test loops the rtmp encoder back into the decoder via the bus transceiver. in normal operation the transceiver transmitter is connected to the receiver. this connection closes the loop from the encoder to decoder. self-test has the ability to check the function of channel a and b, command recognition logic, data transfer logic, and memory address control. the rtmp?s self-test capability is based on the fact that the mil-std-1553 status word sync pulse is identical to the command word sync pulse. thus, if the status from the encoder is fed back to the decoder, the rtmp will recognize the status word as a command and thus cause the rtmp to process the validated command word. after the host invokes self-test, the rtmp self-test logic forces the transmission of a status word even though the rtmp has not received a valid command. by reading the rtmp?s operational status register the host can monitor self-test. the host compares self-test results to expected results; data mismatches result in self-test failure. normal operation is inhibited during self-test. anytime during the rtmp?s self-test execution, the host can monitor the operational status register?s (ops) self- test active bit (stact), bit 11. stact=1 signifies that the rtmp is performing a self-test. stact is active until the rtmp completes all self-test memory activity. if the host has enabled the activity interrupts ( eort and eomc ), eomc occurs after the memory fetch for the data word that the rtmp wraps around during the self-test, and eort occurs when the self-test is complete. do not send mode code commands in self-test while operating in the a mode. in b mode the rtmp can verify 3 mode codes (synchronize with data, selected transmitter shutdown, override selected transmitter shutdown). all of these mode codes have the t/ r bit set to zero.
rtmp-25 note: when monitoring self-test via the operational status register, each ops read will clear any bits the rtmp set. control and invoke self-test by using the test input pin, along with control register bits 12, 13, 14, and 15 (i.e., stcs, sten, chben, and chaen). control register bit 12, self-test channel select (stcs), determines whether internal self-test is performed on channel a or channel b. control external self-test channel select via control register bit 12 (stcs) and control register bit 14 or bit 15. these three bits determine which channel is active during self-test. stcs identifies which channel, bit 15 or bit 14, enables the hardware. disable channels a and b, via control register bits 15 and 14, for internal self-test. control register bit 13, self-test enable, initiates the self-test routine. see control register bit descriptions for more information on the function of bits 12 and 13. input pin test determines whether the self-test is external or internal (test = 1 external, test = 0 internal). note: external self-test will corrupt an operational bus since a remote terminal transmits command word information. also note that bus activity received by the rtmp decoder (specifically command word validation) will corrupt self- test. after the host processor enables a self-test, the rtmp?s internal self-test logic remains in a ?wait? state until the rtmp is not receiving or transmitting any information. once the rtmp determines that there is no 1553 bus activity, the sten bit of the control register is reset and self-test begins. essentially, the self-test makes the rtmp behave as if it just received a transmit vector word mode code. the transmit vector word mode code tells the rtmp to transmit a status word and one associated data word. the rtmp wraps this status word and data word back around into the channel under test. since a status word and a command word have the same sync pulse, when the rtmp decoder sees this status word, the receiver thinks it has received a valid command from the 1553 data bus. the status word the rtmp transmits during the self-test, which is wrapped around to the decoder as the 1553 command word, is host-programmable. the rtmp forces bit 11 of this status word to logic zero, hence the status word is recognized as a receive command word. all commands used in self-test are receive commands. the host can program bits 1 through 10 of this status word by writing to bits 0 through 9 of the control register. when the rtmp?s decoder sees these ten bits in the wrapped-around command word, these bits are decoded as the command word?s subaddress and word-count fields. only one data word is transmitted with the status word, therefore setting the word count field not equal to 1 results in a message error. the rtmp accesses the data word that it wraps around during the self-test from memory just as it would any other data word. the rtmp reads the data word for the wrap- around test from the memory location to which the address in the mode code pointer (location 20h) points. the twelve most significant bits of this address come from the data programmed in the mode code pointer location. the rtmp always the four least significant address bits to zero (transmit vector word mode code). the rtmp?s decoder on the selected test channel recognizes the status word that is wrapped around during the self-test as a valid 1553 receive command word. the rtmp?s internal sequencer and error detection logic begin processing the received command word and its associated data in a normal sequence. the host programs the outgoing status/command word to receive one data word at a specific subaddress. then the rtmp goes to the location in the 64- word pointer block corresponding to the actual memory location subaddress where the rtmp stores the data word wrapped around during the self-test, if the host has chosen the separate buffer mode of operation. if the host has selected the single buffer mode of operation, the rtmp stores the wrapped-around data word at the memory location to which the single mode data pointer in the 64- word pointer block points. the rtmp suppresses transmitting a status word after receiving the wrapped- around command word and data word during self-test execution. at this time, the self-test terminates and the rtmp resets the self-test active (stact) bit in the operational status register. the host has complete control over the rtmp?s self-test processing and can terminate a self-test at any time by performing a write to the stop self-test register (sst). when the host writes to the sst, the rtmp terminates all memory activity, resets sten, and resets the self-test active (stact) bit in the ops. 5.0 1553a a n d 1553b m o d e s o f o p e r a t i o n the rtmp provides two modes of operation -- one to meet the requirements of mil-std-1553a and another to meet the requirements of mil-std-1553b. the user selects the mode of operation for the specific application by programming the 1553 mode select input (pra/ b ). when the host sets pra/ b = 1, the rtmp is in the 1553a mode of operation. when pra/ b = 0, the rtmp is in the 1553b mode of operation. in either the 1553a or 1553b mode, the rtmp?s basic operation remains the same with three major differences among the modes of operation. these differences are: status word bit definitions, mode code responses, and status word response time.
rtmp-26 5.1 status word bit definition when the rtmp operates in the 1553a mode, the only bits of the status word it defines are the message error bit (bit 11) and the terminal flag bit (bit 1). the rtmp does not specifically define the rest of the bits in the status word (bits 2 through 10). the user can define these bits for a specific application by programming the corresponding bits in the control register (ctl bits 1-9). in the 1553b mode of operation, the rtmp defines all status word bits in the ctl that correspond to a specific function in the transmitted 1553 status word. the host controls some of the status word bits in the ctl, namely the instrumentation, service request, broadcast, busy, subsystem flag, and terminal flag bits. finally, if the host sets any undefined status word bits in the ctl, the rtmp masks these bits (i.e., sets to logic zero) before they can be transmitted in the status word. 5.2 mode code responses when the rtmp operates in the 1553a mode, it does not internally detect any mode codes as being illegal. the rtmp recognizes all other mode codes as being valid, and responds to these mode codes with a status word only. the 1553a mode of operation does not support mode codes with an associated data word. do not send mode codes with data to the rtmp when operating in the 1553a mode. no auto-execution of mode codes is performed in the 1553a mode of operation. the host can illegalize any mode code by decoding the mode code/subaddress outputs (mcsa0-4) and the mc / sa output with an external device (figure 17). the host can program the external decoder to generate the illegal command (illcom) input whenever the rtmp receives a mode code that the system declares illegal. asserting illcom causes the rtmp to transmit a status word with the message error bit set. illegalization does not stop the auto-execution of mode codes. in the 1553b mode of operation, the rtmp internally detects the dynamic bus control mode code and all reserved mode codes as illegal. the host can illegalize any other mode code by setting the illcom input, just as described for the 1553a mode of operation. table 2 shows the action the rtmp takes for each of the mode codes. 5.3 status word response time when the rtmp operates in the 1553b mode, it checks to see if too many data words are received while processing a receive command. while operating in the 1553a mode, the rtmp does not make this check. therefore, the status word response time for the rtmp in the 1553a mode is different from the status word response time in the 1553b mode. operating in the 1553a mode, the rtmp?s status word response time is from 4.25 to 5.75ms (reference figure 29). this time is measured from midbit of the command word parity bit to midbit of the status word sync pulse. operating in the 1553b mode, the rtmp?s status word response time is from 9.25 to 10ms (reference figure 29). this time is also measured from midbit of the command word parity bit to midbit of the status word sync pulse. these midbit-to-midbit response times are measured from the midbit time of the parity bit at the rtmp?s inputs to the midbit time of the sync pulse at the rtmp?s outputs. these measurements do not include any delays attributable to external devices such as transformers or transceivers. illcom mcsa0 mcsa1 mcsa2 mcsa3 mcsa4 mc /sa rtmp illegal command decoder figure 17. mode code/subaddress illegalization circuit comstr
rtmp-27 6.0 rtmp s y s t e m i n t e r f a c e the rtmp system interface consists of the major functional interfaces between the host processor and the rtmp. these interfaces (1) allow the host to control the functions of the rtmp and determine its operational status; (2) permit the rtmp and the host to exchange the information from the 1553 data bus; and (3) allow the host to select the rtmp?s terminal address. the system interface provides a description of the following aspects of the rtmp?s operation: assigning the rtmp?s terminal address controlling the rtmp?s dma interface interfacing with the rtmp?s internal registers mode code (7) number legal (l)/ illegal (i) operation dynamic bus control synchronize transmit status word initiate self-test transmitter shutdown override transmitter shutdown inhibit terminal flag bit override inhibit terminal flag bit reset remote terminal reserved transmit vector word synchronize transmit last command transmit bit word selected transmitter shutdown override selected transmitter shutdown (6) reserved 00000 00001 00010 00011 00100 00101 00110 00111 01000 01001 01111 10000 10001 10010 10011 10100 10101 10110- 11111 i l l l l l l l l i l l l l l l i 1 2 3 2 3,8 3,8 3,8 3,8 2 1 4 4 5 4 4 4 1 definition of operations: 1. the rtmp sets the message error bit, sends a status word, and stores the 1553 command word, but takes no internal action. 2. the rtmp sends a status word, stores the 1553 command word, but takes no internal action 3. the rtmp sends a status word, stores the 1553 command word, and takes the appropriate internal action. 4. the rtmp sends a status word, stores the 1553 command word, accesses memory for the associated data word, but takes no internal action. 5. the rtmp sends a status word, updates the 1553 command word in an internal register, (see below) accesses memory for the associated data word, but takes no internal action. 1553a mode l(2) l(2) l(2) l(2) l(2) l(2) l(2) l(2) l(2) l(2) l(2) n/a l(2) l(2) n/a n/a l(2) notes no mode code with data status word only no mode code with data no mode code with data 6. the rtmp must receive an override selected transmitter shutdown before the channel that was disabled can be enabled. 7. undefined mode codes in mil-std-1553b are illegalized. table 2. mode code operation 8. illegalized mode code is still executed.
rtmp-28 6.1 assigning the terminal address the rtmp?s terminal address input pins (rta0-rta4) are static inputs. this means the rtmp does not require a latching signal of any sort to assign the rtmp its terminal address. the host simply has to present the correct terminal address on inputs rta0-rta4 and the rtmp recognizes this as the terminal address for all 1553 command words. the rtmp can check the parity of the assigned terminal address by using the remote terminal parity input (rtpty) and the terminal address parity enable input (tapen) in conjunction with the rta0-rta4 inputs. in most applications, it is important that the host enable the terminal address parity checking input to prevent the rtmp from inadvertently responding to a command word not meant for it. if the host requires the rtmp to check the parity of the terminal address, tapen must be high and rtpty must provide the rtmp with odd parity (an odd number of high inputs) for the assigned terminal address. if for some reason, such as a broken or missing terminal address input or an inadvertent terminal address change, the rtmp detects bad parity, it ignores all incoming command words. the rtmp also sets bit 12 in the operational status register, the parity error (paerr) bit. if the host can re- establish the correct terminal address and parity, the rtmp resumes communication on the 1553 data bus. 6.2 controlling the dma interface the rtmp has a standard dma interface that consists of a set of three arbitration signals between the rtmp and the host processor: (1) dma request ( dmar ); (2) dma grant ( dmag ); and (3) dma enable (dmaen). after the bus controller grants the rtmp control of the address and data buses, the rtmp uses three additional signals to control the shared memory: (1) ram read ( rrd ); (2) ram write ( rwr ); and (3) address valid ( av ). figure 18 shows the general relationship of these signals during bus arbitration and data acquisition. when the rtmp requires access to the shared memory, it initiates the bus arbitration sequence by generating dmar . for a transmit message, the rtmp generates dmar when the internal transmitter buffer is empty. therefore, the rtmp must be granted control of the data bus before the current data word transmission is finished or an overrun error occurs. the rtmp continues to generate dmar s until it has transmitted the proper number of data words or until an error condition occurs. for a receive message, the rtmp generates dmar after a received data word is validated. in this situation, the rtmp must receive a bus grant signal before receiving the next data word or an overrun error occurs. after the rtmp generates dmar , it waits until the bus master generates dmag . after the bus master generates dmag , bus arbitration is complete (provided dmaen is high) and the rtmp takes control of the address and data buses by first enabling the address three-state buffers. after the address lines have settled, the rtmp generates av signifying the address is valid. the next step in the sequence depends on whether the present memory access is for a receive or a transmit message. if the rtmp is processing a receive command, rwr goes active allowing the rtmp to write the received 1553 data to the shared memory. if, on the other hand, the rtmp is processing a transmit command, rrd goes active allowing the rtmp to access data from the shared memory. in either case, the data is read from or written to shared memory on the rising edge of rrd or rwr , respectively, thus signifying the end of this memory access cycle. if a memory access bus cycle is pending, i.e., the rtmp has generated dmar but the bus controller has not acknowledged with a dmag , four events can terminate the current bus cycle: (1) the rtmp receives a superseding 1553 command word on the same or opposite channel; (2) an overrun error occurs; (3) a message error occurs; or (4) a write to the stop self-test (sst) register occurs. dmar dmag av rrd or rwr figure 18. general rtmp dma timing relationships
rtmp-29 6.3 interfacing with the rtmp?s internal registers the host interfaces with the rtmp?s six internal registers to control the rtmp?s operation and to determine the rtmp?s operational status while the rtmp is active. six signals between the host and the rtmp control this interface: (1) the three least significant address lines (a2- a0); (2) chip select ( cs ); (3) register read ( rd ); and (4) register write ( wr ). figure 19 shows the general timing relationship of these signals. the rtmp?s three least significant address bits (a2-a0) are bidirectional. when the host drives these inputs along with cs , rd , and wr , the rtmp uses this information to select which of its six internal registers the host will access during this operation (table 1). before the host attempts to access the rtmp?s internal registers, it must make sure the rtmp is not performing a dma operation. accessing the rtmp?s internal registers during a dma operation causes data corruption because the cs input takes precedence over all other rtmp memory operations and causes the rtmp immediately to place its address and data buffers in a high-impedance state. therefore, after the bus master has granted the rtmp control of the buses, the host must not attempt any internal register reads or writes until the rtmp completes its memory operation. the interface timing between the host and the rtmp?s internal registers follows standard microprocessor interfacing techniques. after the host has determined that the rtmp is not using the address and data buses, it generates the address for the selected rtmp internal register. the host asserts cs , informing the rtmp that an internal register operation is about to occur. the rtmp responds by placing its address and data bus signals in a high-impedance state and allowing the three least significant address lines to become inputs. at this point, the host asserts either rd or wr telling the rtmp the direction of the data flow. the host completes the current register access cycle on the rising edge of wr for data input operations and on the rising edge of rd for data output operations. 6.4 rtmp hardware interface 6.4.1 the rtmp - 1553 transceiver interface the rtmp?s manchester ii encoder/decoders interface directly with the 1553 bus transceiver as shown in figure 20. the rtmp uses the rao, raz, tao, and taz pins to interface with bus channel a. the rtmp uses the rbo, rbz, tbo, and tbz pins to interface with bus channel b. the rtmp?s encoder outputs (tao, taz, tbo, and tbz) are low when they are inactive. in addition to the signals listed above, the rtmp also provides two signals that assist the rtmp in meeting the mil-std-1553 fail-safe timer requirements. these signals are the timer on ( timeron ) and the channel a/ (cha/ b ) outputs. these signals are also shown in figure 20. 6.4.2 the rtmp dma interface when the rtmp is in its standard dma configuration, its address, data, and control signals are directly connected to each other as shown in figure 21. the rtmp?s signals remain in a high-impedance state until the rtmp is granted control of the buses after dma arbitration has occurred, or until the host asserts cs signifying that the host is about to access one of the rtmp?s internal registers. the host can disable all dma transfers by setting the busy bit (bit 3) of the control register (ctl). data bus address data bus figure 19a. general rtmp register read timing bus cs * rd cs * wr figure 19b. general rtmp register write timing
rtmp-30 channel disable logic txinha txinhb channel a channel b utmc rao raz tao taz rbo rbz tbo tbz channel a channel b rtmp 63m125 timeron cha/b figure 20. rtmp-to-transceiver interface diagram ram 16 16 16 16 host 16 16 13 3 rtmp a3-a15 a0-a2 rrd rwr rd wr cs data dmar dmag figure 21. rtmp-to host interface
rtmp-31 7.0 o p e r a t i n g c o n d i t i o n s * (r e f e r e n c e d t o v ss ) symbol parameter limits unit dc supply voltage voltage on any pin dc input current storage temperature v v ma power dissipation 300 mw q thermal resistance, junction-to-case 10 maximum junction temperature +175 v dd v i/o i i t stg p d t j 10 -0.3 to +7.0 -64 to +150 -0.3 to v dd +0.3 c c/w c * stresses outside the listed absolute maximum ratings may cause permanent damage to the device. this is a stress rating only, and functional operation of the device at these or any other conditions beyond limits indicated in the operational sections of this specification is notrecommended. exposure to absolute maximum rating conditions for extended periods may affect device reliability. recommended operating conditions symbol parameter limits unit dc supply voltage temperature range 4.5 to 5.5 v operating frequency mhz dc input voltage v v dd t a f o v in 12 .01% 0 to v dd -55 to +125 c
rtmp-32 8.0 dc e l e c t r i c a l c h a r a c t e r i s t i c s symbol parameter unit low-level input voltage high-level input voltage input leakage current low-level output voltage high-level output voltage v v v condition minimum maximum ttl inputs ttl inputs ttl outputs ttl outputs three-state output leakage ttl outputs current 0.8 2.0 ttl inputs inputs with pull-down resistors inputs with pull-up resistors -1 100 -1000 1 1000 -100 m a m a m a 0.4 v 2.4 -10 m a ma 20 pf 15 pf 10 pf notes: 5. guaranteed by design or characterization. 2. not more than one output may be shorted at a time for a maximum duration of one second. voltage supply should be adequately sized and decoupled to handle a large current surge. 50 ma 100 ma 3. includes current through input pull-ups. instantaneous surge currents on the order of 1 amp can occur during output switching . +10 inputs with pull-down resistors 400 m a quiescent current see note 4 1 ma 4. all inputs with internal pull-ups and pull-downs should be left floating. all other inputs should be tied high or low. -100 1. measured only for initial qualification and after process or design changes which may affect input/output capacitance. v il v ih v ol v oh i oz i os i dd c in c out c io qi dd i in v in = v dd or v ss v in = v dd v in = 2.4v v in = v ss i ol = 3.2ma i oh = -400ma v o = v dd or v ss v dd = 5.5v, v o = v dd v dd = 5.5v, v o = 0v f = 1mhz @ 0v f = 1mhz @ 0v f = 1mhz @ 0v f = 12mhz, c l = 50pf short-circuit output current 2, 5 input capacitance 1 output capacitance 1 bidirect i/o capacitance 1 average operating current 3, 5
rtmp-33 9.0 ac e l e c t r i c a l c h a r a c t e r i s t i c s 90% figure 23. ac test loads and input waveforms note: 50pf including scope probe and test socket input pulses 10% 10% 90% < 2ns < 2ns 50pf 3v 0v 5v i ref (source) i ref (sink) v ref to data valid to high z to response to response to response input input input input input input input to high z to data valid to response input parameter symbol bus output out-of-phase output in-phase input notes: 1. timing measurements made at (v ih min + v il max)/2. 2. timing measurements made at (v ol max + v oh min)/2 3. based on 50pf load. 4. unless otherwise noted, all ac electrical characteristics are guaranteed by design or characterization. 1 1 2 2 2 2 v ih min v ih min v oh min v oh min v oh min t a t b t c t d t e t f t g t h t a t c t b t d t e t f t g t h - - - - - - figure 22. typical timing measurements
rtmp-34 valid ad- symbol parameter units max min 134 ns ns ns ns ns ns ns ns 40 176 80 90 95 140 50 0 32 70 0 62 7.3 m s bus data bus address note: 1. guaranteed by test. ns 0 valid 0 0 dmar dmag av rrd t 22a t 22b (1) t 22c t 22d t 22e t 22f t 22g t 22a t 22b t 22c t 22d t 22e t 22f t 22g t 22h t 22i t 22j t 22h t 22i t 22j dmar to dmag av - to dmag - figure 24. detailed timing - rtmp dma read cycle dmag to address bus valid address bus valid to av av to rrd rrd pulsewidth data setup time to rrd - data hold time from rrd - rrd - to av - av - to address high-impedance (hold) and dmar -
rtmp-35 dmag to address bus valid address bus valid to av av to rwr rwr pulsewidth data setup time to rwr rwr - to data bus high-impedance rwr - to av - address bus data symbol parameter min max units 0 93 ns ns 10 100 address bus data bus symbol parameter units max min ns ns ns ns ns ns ns ns 134 40 176 80 90 95 140 145 311 90 32 70 0 62 7.3 m s note: 1. guaranteed by test. ns 0 valid address valid data valid data bus valid address 20 ns ns 20 20 0 0 t 23a t 23b 1 t 23c t 23d t 23e t 23f t 23g t 23h t 23i t 23j dmar to dmag t 23a t 23b t 23c t 23d t 23f t 23e t 23g t 23h t 23i t 23j dmar dmag av rwr cs * rd t 24a t 24b 1 t 24c t 24d address bus valid to ( cs * rd) ( cs * rd) to data bus valid ( cs * rd) - to data bus high-impedence ( cs * rd) - to address bus high-impedence t 24a t 24b t 24c t 24d figure 25. detailed timing - rtmp dma write cycle figure 26. detailed timing x0106 rtmp register reads
rtmp-36 1553 cmd wd mcsa0-4 m 3.7 240 230 240 symbol parameter units max min bus data address symbol min max units 80 50 70 50 ns ns ns ns s ns 100 ns ns ns illcom bus ns 20 sme 500 ns 1.0 .100 m s cs+wr t 25 t 25 t 25 t 25 t 25 t 25 t 25 t 25 t 25 t 25 address bus valid to ( cs + wr ) parameter wr pulsewidth wr - to data bus high-impedance (hold time) (cs * wr ) - to address bus high-impedance data valid to ( cs * wr ) - (set-up time) comstr cha/b t 26 t26a t 26 t26c t26d t26e t26f mid-bit of command word parity to comstr? comstr pulsewidth cha/b valid to comstr | mcsa0-4 valid to comstr | comstr | to illcom| (active) comstr | to sme| (active) sme t26b t 26 t 26 t 26 t 26 t 26 figure 28. 1553 command strobeand channel timing figure 27. detailed timing - rtmp register writes valid data valid address
rtmp-37 10.0 9.25 5.75 4.25 1553b mode status word response time 1553a mode status word response time cmd wd 1553 m symbol parameter units max min status word 1553 note: 1. this timing is for rtmp signals only and does not include delays from other sources. s m s t resp (pra/ b =0) t resp (pra/ b =1) t resp 1 figure 29. 1553 status word response times s w b 1 4 s w b 1 5 address terminal sync word status 2 0 9 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 1 1 1 9 8 7 6 5 4 3 2 1 times bit 5 1 1 1 1 1 1 1 1 1 1 1 1 m e s s a g e e r r o r s w b 1 0 s w b 1 1 s w b 1 2 s w b 1 3 s w b 1 6 s w b 1 7 s w b 1 8 t f l g p a r figure 30. status word bit-time definitions for 1553a mode
rtmp-38 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 5 1 5 5 1 reserved remote terminal address sync status word data word sync sync data p p remote terminal address t/r subaddress/ mode data word count/mode code bit times note: t/r - transmit/receive p - parity command word i n s t r u m e n t a t i o n s e r v i c e r e q u e s t b r o a d c a s t c o m m a n d r e c e i v e d b u s y s u b s y s t e m f l a g d y n a m i c b u s c o n t r o l a c c e p t a n c e t e r m i n a l f l a g p a r i t y m e s s a g e e r r o r figure 31. mil-std-1553b word formats
rtmp-39 ss v rta4 tapen a4 a0 a1 a2 a13 a14 a9 a8 a7 a10 a3 a11 a12 rao reset tbz tbo tao raz mcsa4 mcsa1 mcsa0 mcsa3 mcsa2 test enbc 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 16 19 32 31 30 29 28 27 26 25 24 23 22 21 20 18 17 15 14 13 12 74 rta3 rtpty 11 10 9 8 7 6 5 4 3 2 1 84 83 82 81 80 79 78 77 76 75 ss v illcom dd v taz dd v a5 a6 r b o r b z c l k e o r t e o m c c o m s t r m e r r s v c s m e c s r d w r d m a r d m a g d m a e n r r d r w r a v a 1 5 v v s s d d d 0 d 1 d 2 d 3 d 4 d 5 d 6 d 7 d 8 d 9 d 1 0 d 1 1 d 1 2 d 1 3 d 1 4 d 1 5 r t a 0 r t a 1 r t a 2 v v s s d d cha/b timeron mc /sa pra/ b figure 32a. leadless chip carrier functional pin identification (top view)
rtmp-40 v dd burst ssysf a b c d e f g h j k rbz clk merr sme dmaen d2 d3 d5 d6 d7 d8 d9 d8 d11 d12 d13 d14 d15 rta0 rta1 a12 a11 a3 a10 a7 a8 a15 a9 a13 a2 a1 a0 a4 rtpty l enbc test msca2 mcsa3 mcsa0 mcsa1 mcsa4 tao d1 taz d0 tbo tbz rbo rta2 rta4 a14 11 10 9 8 7 6 5 4 3 2 1 d4 index corner rta3 tapen d10 rao a6 a5 illcom raz timeron reset eort comstr eomc svc cha/ b pra/ b mc /sa v ss v dd v dd v ss v dd vdd vss dmar rd wr cs dmag rrd av rwr v ss figure 32b. pingrid array functional pin identification (bottom view)

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