 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| ST5092 2.7V SUPPLY 14-BIT LINEAR CODEC WITH HIGH-PERFORMANCE AUDIO FRONT-END PRELIMINARY DATA FEATURES: Complete CODEC and FILTER system including: 14 BIT LINEAR ANALOG TO DIGITAL AND DIGITAL TO ANALOG CONVERTERS. 8 BIT COMPANDED ANALOG TO DIGITAL AND DIGITAL TO ANALOG CONVERTERS A-LAW OR -LAW. TRANSMIT AND RECEIVE BAND-PASS FILTERS ACTIVE ANTIALIAS NOISE FILTER. Phone Features: THREE SWITCHABLE MICROPHONE AMPLIFIER INPUTS. GAIN PROGRAMMABLE: 20 dB PREAMP. (+MUTE), 0 . . 22.5 dB AMPLIFIER, 1.5 dB STEPS. EARPIECE AUDIO OUTPUT. ATTENUATION PROGRAMMABLE: 0 . . 30 dB, 2 dB STEPS. EXTERNAL AUDIO OUTPUT. ATTENUATION PROGRAMMABLE: 0 . . 30 dB, 2 dB STEPS. TRANSIENT SUPRESSION SIGNAL DURING POWER ON AND DURING AMPLIFIER SWITCHING. INTERNAL PROGRAMMABLE SIDETONE CIRCUIT. ATTENUATION PROGRAMMABLE: 16 dB RANGE, 1 dB STEP. ROUTING POSSIBLE TO BOTH OUTPUTS. INTERNAL RING OR TONE GENERATOR INCLUDING DTMF TONES, SINEWAVE OR SQUAREWAVE WAVEFORMS. ATTENUATION PROGRAMMABLE: 27dB RANGE, 3dB STEP. THREE FREQUENCY RANGES: a) 3.9Hz . . . . 996Hz, 3.9Hz STEP b) 7.8Hz . . . . 1992Hz, 7.8Hz STEP c) 15.6Hz . . . . 3984Hz, 15.6Hz STEP PROGRAMMABLE PULSE WIDTH MODULATED BUZZER DRIVER OUTPUT. General Features: SINGLE 2.7V to 3.6V SUPPLY EXTENDED TEMPERATURE RANGE OPERATION (*) -40C to 85C. 1.5 W STANDBY POWER (TYP. AT 3.0V). 15mW OPERATING POWER (TYP. AT 3.0V). 13mW OPERATING POWER (TYP. AT 2.7V). CMOS COMPATIBLE DIGITAL INTERFACES. PROGRAMMABLE PCM AND CONTROL INTERFACE MICROWIRE COMPATIBLE. June 1997 TQFP44(10x10x1.4) SO28 ORDERING NUMBERS: Package ST5092AD ST5092ADTR ST5092TQFP ST5092TQFPTR SO28 SO28 TQFP44 TQFP44 Dim. Cond. Tube Tape&Reel Tray 8x20 Tape&Reel 10x10x1.4 10x10x1.4 APPLICATIONS: GSM DIGITAL CELLULAR TELEPHONES. CT2 DIGITAL CORDLESS TELEPHONES. DECT DIGITAL CORDLESS TELEPHONES. BATTERY OPERATED AUDIO FRONT-ENDS FOR DSPs. (*) Functionality guaranteed in the range - 40C to +85C; Timing and Electrical Specifications are guaranteed in the range - 30C to +85C. GENERAL DESCRIPTION ST5092 is a high performance low power combined PCM CODEC/FILTER device tailored to implement the audio front-end functions required by the next generation low voltage/low power consumption digital terminals. ST5092 offers a number of programmable functions accessed through a serial control channel that easily interfaces to any classical microcontroller. The PCM interface supports both non-delayed (normal and reverse) and delayed frame synchronization modes. ST5092 can be configurated either as a 14-bit linear or as an 8-bit companded PCM coder. Additionally to the CODEC/FILTER function, ST5092 includes a Tone/Ring/DTMF generator, a sidetone generation, and a buzzer driver output. ST5092 fulfills and exceeds D3/D4 and CCITT recommendations and ETSI requirements for digital handset terminals. Main applications include digital mobile phones, as cellular and cordless phones, or any battery powered equipment that requires audio codecs operating at low single supply voltages 1/29 This is preliminary information on a new product now in development or undergoing evaluation. Details are subject to change without notice. ST5092 PIN CONNECTIONS (Top view) MIC3+ MIC1+ 34 33 32 31 30 29 MIC1N.C. MIC2+ MIC2N.C. N.C. N.C. LO MCLK FS N.C. 28 27 26 25 24 23 12 N.C. 13 N.C. 14 CCLK 15 CS16 CI 17 BZ 18 VCC 19 CO 20 DX 21 GND 22 N.C. GNDA 36 VCCP VCCA MIC3- N.C. N.C. N.C. N.C. 44 N.C. VFrVFr+ N.C. VLr1 2 3 4 5 6 7 8 9 10 11 43 42 41 40 39 38 37 35 N.C. VCCA VCCP N.C. VFrVFr+ VLrVLr+ GNDP DR CCLK CSCI BZ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 D94TL094 28 27 26 25 24 23 MIC3+ MIC3GNDA MIC1+ MIC1MIC2+ MIC2LO MCLK FS GND Dx CO VCC SO28 22 21 20 19 18 17 16 15 VLr+ N.C. GNDP N.C. DR N.C. TQFP44 N.C. D94TL095 BLOCK DIAGRAM MIC3MIC2- MIC PREAMP 20dB + MUTE MIC AMP 0 -> 22.5 1.5dB STEP EN MIC1(A) DE MIC2+ PREFILTER & BANDPASS FILTER PCM ADC TRANSMIT REGISTER DX MIC1+ MIC3+ EARA OUTPUT -1 VS & TE 0 -> -30dB, 2dB STEP (B) BANDPASS FILTER PCM DAC RECEIVE REGISTER DR VFr- 12dB VFr+ 1 OE VLr-1 RTE SE TONE, RING & DTMF GENER. & FILTER TONE AMP 0 -> -27dB 3dB STEP EN CO CONTROL INTERFACE -WIRE CLOCK GENERATOR & SYNCHRONIZER CI CSCCLK MCLK FS 12dB VLr+ 1 SI EXTA OUTPUT INTERFACE LATCH LO SIDETONE AMP -12.5 -> -27.5dB 1dB STEP BE BUZZER DRIVER LEVEL ADJUST (PWM) BZ D93 TL074 GNDP GNDA GND VCCA VCC VCCP 2/29 ST5092 PIN FUNCTIONS (SO28) Pin 1 2 3 4 5,6 Name N.C. VCCA VCCP N.C. VFr+, VFr- Description Not Connected. Positive power supply input for the analog section. VCC and V CCA must be directly connected together. Positive power supply input for the power section. VCCP and VCC must be connected together. Not Connected. Receive analog earpiece amplifier complementary outputs. These outputs can drive directly earpiece transductor. The signal at this output can be the sum of: - Receive Speech signal from DR, - Internal Tone Generator, - Sidetone signal. Receive analog extra amplifier complementary outputs. The signal at these outputs can be the sum of: - Receive Speech signal from DR, - Internal Tone generator, - Sidetone signal. Power ground. V Fr and VLr driver are referenced to this pin. GNDP and GND must be connected together close to the device. Receive data input: Data is shifted in during the assigned Received time slots In delayed and nondelayed normal frame synchr. modes voice data byte is shifted in at the MCLK frequency on the falling edges of MCLK, while in non-delayed reverse frame synchr. mode voice data byte is shifted in at the MCLK frequency on the rising edges of MCLK. Control Clock input: This clock shifts serial control information into CI and out from CO when the CS- input is low, depending on the current instruction. CCLK may be asynchronous with the other system clocks. Chip Select input: When this pin is low, control information is written into and out from the ST5092 via CI and CO pins. Control data Input: Serial Control information is shifted into the ST5092 on this pin when CS- is low on the rising edges of CCLK. Pulse width modulated buzzer driver output. Positive power supply input for the digital section. Control data Output: Serial control/status information is shifted out from the ST5092 on this pin when CS- is low on the falling edges of CCLK. Transmit Data ouput: Data is shifted out on this pin during the assigned transmit time slots. Elsewhere DX output is in the high impedance state. In delayed and non-delayed normal frame synchr. modes, voice data byte is shifted out from TRISTATE output DX at the MCLK on the rising edge of MCLK, while in non-delayed reverse frame synchr mode voice data byte is shifted out on the falling edge of MCLK. Ground: All digital signals are referenced to this pin. Frame Sync input: This signal is a 8kHz clock which defines the start of the transmit and receive frames. Any of three formats may be used for this signal: non delayed normal mode, delayed mode, and non delayed reverse mode. Master Clock Input: This signal is used by the switched capacitor filters and the encoder/decoder sequencing logic. Values must be 512 kHz, 1.536 MHz, 2.048 MHz or 2.56 MHz selected by means of Control Register CRO. MCLK is used also to shift-in and out data. A logic 1 written into DO (CR1) appears at LO pin as a logic 0 A logic 0 written into DO (CR1) appears at LO pin as a logic 1. Second negative high impedance input to transmit pre-amplifier for microphone connection. Second Positive high impedance input to transmit pre-amplifier for microphone connection. Negative high impedance input to transmit pre-amplifier for microphone connection. Positive high impedance input to transmit pre-amplifier for microphone connection. Analog Ground: All analog signals are referenced to this pin. GND and GNDA must be connected together close to the device. Third negative high impedance output to transmit preamplifier for microphone connection. Third positive high impedance output to transmit preamplifier for microphone connection. 7,8 VLr+, VLr- 9 10 GNDP DR 11 CCLK 12 13 14 15 16 17 CSCI BZ VCC CO DX 18 19 GND FS 20 MCLK 21 22 23 24 25 26 27 28 LO MIC2MIC2+ MIC1MIC1+ GNDA MIC3MIC3+ 3/29 ST5092 PIN FUNCTIONS (TQFP44) Pin Name 1 2,3 Description N.C. Not Connected. VFr+, VFr- Receive analog earpiece amplifier complementary outputs. These outputs can drive directly earpiece transductor. The signal at this output can be the summ of: - Receive Speech signal from DR, - Internal Tone Generator, - Sidetone signal. 4 N.C. Not Connected. 5,6 VLr+, VLr- Receive analog extra amplifier complementary outputs. The signal at these outputs can be the sum of: - Receive Speech signal from DR, - Internal Tone generator, - Sidetone signal. 7 N.C. Not Connected. 8 GNDP Power ground. V Fr and VLr driver are referenced to this pin. GNDP and GND must be connected together close to the device. 9 N.C. Not Connected. 10 DR Receive data input: Data is shifted in during the assigned Received time slots In delayed and nondelayed normal frame synchr. modes voice data byte is shifted in at the MCLK frequency on the falling edges of MCLK, while in non-delayed reverse frame sinchr. mode voice data byte is shifted in at the MCLK frequency on the rising edges of MCLK. 11,12,13 N.C. Not Connected. 14 CCLK Control Clock input: This clock shifts serial control information into CI and out from CO when the CS- input is low, depending on the current instruction. CCLK may be asynchronous with the other system clocks. 15 CSChip Select input: When this pin is low, control information is written into and out from the ST5092 via CI and CO pins. 16 CI Control data Input: Serial Control information is shifted into the ST5092 on this pin when CS- is low on the rising edges of CCLK. 17 BZ Pulse width modulated buzzer driver output. 18 VCC Positive power supply input for the digital section. 19 CO Control data Output: Serial control/status information is shifted out from the ST5092 on this pin when CS- is low on the falling edges of CCLK. 20 DX Transmit Data ouput: Data is shifted out on this pin during the assigned transmit time slots. Elsewhere DX output is in the high impendance state. In delayed and non-delayed normal frame synchr. modes, voice data byte is shifted out from TRISTATE output DX at the MCLK on the rising edge of MCLK, while in non-delayed reverse frame synchr mode voice data byte is shifted out on the falling edge of MCLK. 21 GND Ground: All digital signals are referenced to this pin. 22,23 N.C. Not Connected. 24 FS Frame Sync input: This signal is a 8kHz clock which defines the start of the transmit and receive frames. Either of three formats may be used for this signal: non delayed normal mode, delayed mode, and non delayed reverse mode. 25 MCLK Master Clock Input: This signal is used by the switched capacitor filters and the encoder/decoder sequencing logic. Values must be 512 kHz, 1.536 MHz, 2.048 MHz or 2.56 MHz selected by means of Control Register CRO. MCLK is used also to shift-in and out data. 26 LO A logic 1 written into DO (CR1) appears at LO pin as a logic 0 A logic 0 written into DO (CR1) appears at LO pin as a logic 1. 27,28,29 N.C. Not Connected. 30 MIC2- Second negative high impedance input to transmit pre-amplifier for microphone connection. 31 MIC2+ Second Positive high impedance input to transmit pre-amplifier for microphone connection. 32 N.C. Not Connected. 33 MIC1- Negative high impedance input to transmit pre-amplifier for microphone connection. 34 MIC1+ Positive high impedance input to transmit pre-amplifier for microphone connection. 35 N.C. Not Connected. 36 GNDA Analog Ground: All analog signals are referenced to this pin. GND and GNDA must be connected together close to the device. 37 MIC3- Third negative high impedance output to transmit preamplifier for microphone connection. 38 MIC3+ Third positive high impedance output to transmit preamplifier for microphone connection. 39,40 N.C. Not Connected. 41 VCCA Positive power supply input for the analog section. VCC and V CCA must be directly connected together. 42 VCCP Positive power supply input for the power section. VCCP and VCC must be connected together. 43,44 N.C. Not Connected. 4/29 ST5092 FUNCTIONAL DESCRIPTION I DEVICE OPERATION I.1 Power on initialization: When power is first applied, power on reset circuitry initializes ST5092 and puts it into the power down state. Gain Control Registers for the various programmable gain amplifiers and programmable switches are initialized as indicated in the Control Register description section. All CODEC functions are disabled. The desired selection for all programmable functions may be intialized prior to a power up command using the MICROWIRE control channel. In the mute case, the analog transmit signal is grounded and the sidetone path is also disabled. Following the first stage is a programmable gain amplifier which provides from 0 to 22.5 dB of additional gain in 1.5dB step. The total transmit gain should be adjusted so that, at reference point A, see Block Diagram description, the internal 0 dBm0 voltage is 0.49 Vrms (overload level is 0.7 Vrms). Second stage amplifier gain can be programmed with bits 4 to 7 of CR5. An active RC prefilter then precedes the 8th order band pass switched capacitor filter. A/D converter can be either a 14-bit linear (bit CM = 0 in register CR0) or can have a compressing characteristics (bit CM = 1 in register CR0) according to CCITT A or MU255 coding laws. A precision on chip voltage reference ensures accurate and highly stable transmission levels. Any offset voltage arising in the gain-set amplifier, the filters or the comparator is cancelled by an internal autozero circuit. Each encode cycle begins immediatly at the beginning of the selected Transmit time slot. The total signal delay referenced to the start of the time slot is approximatively 195 s (due to the transmit filter) plus 125 s (due to encoding delay), which totals 320 s. Voice data is shifted out on DX during the selected time slot on the transmit rising edges of MCLK in delayed or non-delayed normal mode or on the falling edges of MCLK in non-delayed reverse mode. I.2 Power up/down control: Following power-on initialization, power up and power down control may be accomplished by writing any of the control instructions listed in Table 1 into ST5092 with "P" bit set to 0 for power up or 1 for power down. Normally, it is recommended that all programmable functions be initially programmed while the device is powered down. Power state control can then be included with the last programming instruction or in a separate single byte instruction. Any of the programmable registers may also be modified while ST5092 is powered up or down by setting "P" bit as indicated. When power up or down control is entered as a single byte instruction, bit 1 must be set to a 0. When a power up command is given, all de-activated circuits are activated, but output DX will remain in the high impedance state until the second Fs pulse after power up. I.3 Power down state: Following a period of activity, power down state may be reentered by writing a power down instruction. Control Registers remain in their current state and can be changed by MICROWIRE control interface. In addition to the power down instruction, detection of loss MCLK (no transition detected) automatically enters the device in "reset" power down state with DX output in the high impedance state. I.4 Transmit section: Transmit analog interface is designed in two stages to enable gains up to 42.5 dB to be realized. Stage 1 is a low noise differential amplifier providing 20 dB gain. A microphone may be capacitevely connected to MIC1+, MIC1- inputs, while the MIC2+ MIC2- and MIC3+ MIC3- inputs may be used to capacitively connect a second microphone or a third microphone respectively or an auxiliary audio circuit. MIC1 or MIC2 or MC3 or transmit mute is selected with bits 6 and 7 of register CR4. I.5 Receive section: Voice Data is shifted into the decoder's Receive voice data Register via the DR pin during the selected time slot on the falling edges of MCLK in delayed or non-delayed normal mode or on the rising edges of MCLK in non-delayed reverse mode. The decoder consists of either a 14-bit linear or an expanding DAC with A or MU255 law decoding characteristic. Following the Decoder is a 3400 Hz 8th order band-pass switched capacitor filter with integral Sin X/X correction for the 8 kHz sample and hold. 0 dBmO voltage at this (B) reference point (see Block Diagram description) is 0.49 Vrms. A transcient suppressing circuitry ensure interference noise suppression at power up. The analog speech signal output can be routed either to earpiece (VFR+, VFR- outputs) or to an extra analog output (VLr+, VLr- outputs) by setting bits OE and SE (1 and 0 of CR4). Total signal delay is approximatively 190 s (filter plus decoding delay) plus 62.5 s (1/2 frame) which gives approximatively 252 s. Differential outputs VFR+,VFR- are intended to directly drive an earpiece. Preceding the outputs is a programmable attenuation amplifier, which must 5/29 ST5092 be set by writing to bits 4 to 7 in register CR6. Attenuations in the range 0 to -30 dB relative to the maximum level in 2 dB step can be programmed. The input of this programmable amplifier is the sum of several signals which can be selected by writing to register CR4.: - Receive speech signal which has been decoded and filtered, - Internally generated tone signal, (Tone amplitude is programmed with bits 4 to 7 of register CR7), - Sidetone signal, the amplitude of which is programmed with bits 0 to 3 of register CR5 VFR+ and VFR- outputs are capable of driving output power level up to 66mW into differentially connected load impedance of 30 . Piezoceramic receivers up to 50nF can also be driven. Differential outputs VLr+,VLr- are intended to directly drive an extra output. Preceding the outputs is a programmable attenuation amplifier, which must be set by writing to bits 0 to 3 in register CR6. Attenuations in the range 0 to -30 dB relative to the maximum level in 2.0 dB step can be programmed. The input of this programmable amplifier can be the sum of signals which can be selected by writing to register CR4: - Receive speech signal which has been decoded and filtered, - Internally generated tone signal, (Tone amplitude is programmed with bits 4 to 7 of register CR7), - Sidetone signal, the amplitude of which is programmed with bits 0 to 3 of register CR5. VLr+ and VLr- outputs are capable of driving output power level up to 66mW into differentially connected load impedance of 30 . Piezoceramic receivers up to 50nF can also be driven. BUZZER OUTPUT: Single ended output BZ is intended to drive a buzzer, via an external BJT, with a squarewave pulse width modulated (PWM) signal the frequency of which is stored into register CR8. For some applications it is also possible to amplitude modulate this PWM signal with a squarewave signal having a frequency stored in register CR9. Maximum load for BZ is 5k and 50pF. Non delayed data mode is similar to long frame timing on ST5080A: first time slot begins nominally coincident with the rising edge of FS. Alternative is to use delayed data mode, which is similar to short frame sync timing on ST5080A, in which FS input must be high at least a half cycle of MCLK earlier the frame beginning. In the case of companded code only (bit CM = 1 in register CRO) a time slot assignment circuit on chip may be used with all timing modes, allowing connection to one of the two B1 and B2 voice data channels. Two data formats are available: in Format 1, time slot B1 corresponds to the 8 MCLK cycles following immediately the rising edge of FS, while time slot B2 corresponds to the 8 MCLK cycles following immediately time slot B1. In Format 2, time slot B1 is identical to Format 1. Time slot B2 appears two bit slots after time slot B1. This two bits space is left available for insertion of the D channel data. Data format is selected by bit FF (2) in register CR0. Time slot B1 or B2 is selected by bit TS (1) in Control Register CR1. Bit EN (2) in control register CR1 enables or disables the voice data transfer on DX and DR as appropriate. During the assigned time slot, DX output shifts data out from the voice data register on the rising edges of MCLK in the case of delayed and non-delayed normal modes or on the falling edges of MCLK in the case of non-delayed reverse mode. Serial voice data is shifted into DR input during the same time slot on the falling edges of MCLK in the case of delayed and nondelayed normal modes or on the rising edges of MCLK in the case of non-delayed reverse mode. DX is in the high impedance Tristate condition when in the non selected time slots. I.6 Digital Interface (Fig. 1) F S Frame Sync input determines the beginning of frame. It may have any duration from a single cycle of MCLK to a squarewave. Three different relationships may be established between the Frame Sync input and the first time slot of frame by setting bits DM1 and DM0 in register CR1. 6/29 I.7 Control Interface: Control information or data is written into or readback from ST5092 via the serial control port consisting of control clock CCLK, serial data input CI and output CO, and Chip Select input, CS-. All control instructions require 2 bytes as listed in Table 1, with the exception of a single byte powerup/down command. To shift control data into ST5092, CCLK must be pulsed high 8 times while CS- is low. Data on CI input is shifted into the serial input register on the rising edge of each CCLK pulse. After all data is shifted in, the content of the input shift register is decoded, and may indicate that a 2nd byte of control data will follow. This second byte may either be defined by a second byte-wide CSpulse or may follow the first contiguously, i.e. it is not mandatory for CS- to return high in between the first and second control bytes. At the end of the 2nd control byte, data is loaded into the ap- ST5092 Figure 1: Digital Interface Format (*) FORMAT 1 F5 (delayed timing) F6 (non delayed timing) MCLK DR B1 B2 X X X DX B1 B2 FORMAT 2 F8 (delayed timing) F9 (non delayed timing) MCLK DR B1 X B2 X X DX B1 B2 D93TL075 (*) Significant Only For Companded Code. propriate programmable register. CS- must return high at the end of the 2nd byte. To read-back status information from ST5092, the first byte of the appropriate instruction is strobed in during the first CS- pulse, as defined in Table 1. CS- must be set low for a further 8 CCLK cycles, during which data is shifted out of the CO pin on the falling edges of CCLK. When CS- is high, CO pin is in the high impedance Tri-state, enabling CO pins of several devices to be multiplexed together. Thus, to summarise, 2 byte READ and WRITE instructions may use either two 8-bit wide CSpulses or a single 16 bit wide CS- pulse. I.8 Control channel access to PCM interface: It is possible to access the B channel previously selected in Register CR1 in the case of companded code only. A byte written into Control Register CR3 will be automatically transmitted from DX output in the following frame in place of the transmit PCM data. A byte written into Control Register CR2 will be automatically sent through the receive path to the Receive amplifiers. In order to implement a continuous data flow from the Control MICROWIRE interface to a B channel, it is necessary to send the control byte on each PCM frame. A current byte received on DR input can be read in the register CR2. In order to implement a continuous data flow from a B channel to MICROWIRE interface, it is necessary to read register CR2 at each PCM frame. 7/29 ST5092 II PROGRAMMABLE FUNCTIONS For both formats of Digital Interface, programmable functions are configured by writing to a number of registers using a 2-byte write cycle. Most of these registers can also be read-back for verification. Byte one is always register address, while byte two is Data. Table 1 lists the register set and their respective adresses. Table 1: Programmable Register Intructions Function 7 Single byte Power up/down Write CR0 Read-back CR0 Write CR1 Read-back CR1 Write Data to receive path Read data from D R Write Data to D X Write CR4 Read-back CR4 Write CR5 Read-back CR5 Write CR6 Read-back CR6 Write CR7 Read-back CR7 Write CR8 Read-back CR8 Write CR9 Read-back CR9 Write CR10 Read-back CR10 Write CR11 Read-back CR11 Write Test Register CR14 P P P P P P P P P P P P P P P P P P P P P P P P P 6 X 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 Address byte 5 X 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 4 X 0 0 0 0 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 3 X 0 0 1 1 0 0 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 2 X 0 1 0 1 0 1 0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 X X X X X X X X X X X X X X X X X X X X X X X X X none see CR0 TABLE 2 see CR0 see CR1 TABLE 3 see CR1 see CR2 TABLE 4 see CR2 see CR3 TABLE 5 see CR4 TABLE 6 see CR4 see CR5 TABLE 7 see CR5 see CR6 TABLE 8 see CR6 see CR7 TABLE 9 see CR7 see CR8 TABLE 10 see CR8 see CR9 TABLE 11 see CR9 see CR10 TABLE 12 see CR10 see CR11 TABLE 13 see CR11 reserved Data byte NOTE 1: bit 7 of the address byte and data byte is always the first bit clocked into or out from: CI and CO pins when MICROWIRE serial port is enabled. X = reserved: write 0 "P" bit is Power up/down Control bit. P = 1 Means Power Down. Bit 1 indicates, if set, the presence of a second byte. Bit 2 is write/read select bit. Registers CR12, CR13, and CR15 are not accessible. NOTE 2: NOTE 3: NOTE 4: 8/29 ST5092 Table 2: Control Register CR0 Functions 7 F1 0 0 1 1 6 F0 0 1 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 1 0 1 5 CM 4 MA 3 IA 2 FF 1 B7 0 DL MCLK = 512 kHz MCLK = 1.536 MHz MCLK = 2.048 MHz MCLK = 2.560 MHz Linear code Companded code Linear Code 2-complement * sign and magnitude 2-complement 1-complement B1 and B2 consecutive B1 and B2 separated 8 bits time-slot 7 bits time-slot Normal operation Digital Loop-back Function * * Companded Code MU-law: CCITT D3-D4 * MU-law: Bare Coding A-law including even bit inversion A-law: Bare Coding * * * (1) (1) (1) (1) *: (1): state at power on initialization significant in companded mode only Table 3: Control Register CR1 Functions 7 0 1 1 6 X 0 1 0 1 0 1 0 1 0 1 0 1 X 5 DO 4 MR 3 MX 2 EN 1 TS 0 Function delayed data timing non-delayed normal data timing non-delayed reverse data timing L0 latch set to 1 L0 latch set to 0 DR connected to rec. path CR2 connected to rec. path Trans path connected to DX CR3 connected to DX voice data transfer disable voice data transfer enable B1 channel selected B2 channel selected * DM1 DM0 * * (1) * (1) * * (1) (1) *: (1): X: state at power on initialization significant in companded mode only reserved: write 0 9/29 ST5092 Table 4: Control Register CR2 Functions 7 d7 msb (1) Significant in companded mode only. 6 d6 5 d5 4 d4 3 d3 2 d2 1 d1 0 d0 lsb Function Data sent to Receive path or Data received from DR input (1) Table 5: Control Registers CR3 Functions 7 d7 msb (1) Significant in companded mode only 6 d6 5 d5 4 d4 3 d3 2 d2 1 d1 0 d0 lsb D X data transmitted Function (1) Table 6: Control Register CR4 Functions 7 VS 0 0 1 1 6 TE 0 1 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 1 0 1 5 SI 4 3 2 1 0 SE Transmit input muted MIC1 Selected MIC2 Selected MIC3 Selected Internal sidetone disabled Internal sidetone enabled Receive output muted VFr output selected VLr output selected NOT ALLOWED Ring / Tone to VFr or VLr disabled Ring / Tone to VFr or VLr enabled Receive HP filter enabled Receive HP filter disabled Receive Signal to VFr or VLr disabled Receive Signal to VFr or VLr enabled Function * OE1 OE2 RTE HPB * * * * * *: X: state at power on initialization reserved: write 0 10/29 ST5092 Table 7: Control Register CR5 Functions 7 0 0 1 6 0 0 1 5 0 0 1 4 0 1 1 0 0 1 *: state at power on initialization 3 2 1 0 0 dB gain 1.5 dB gain in 1.5 dB step 22.5 dB gain Transmit amplifier Sidetone amplifier Function * 0 0 1 0 0 1 0 1 1 -12.5 dB gain -13.5 dB gain in 1 dB step -27.5 dB gain * Table 8: Control Register CR6 Functions 7 6 5 4 3 2 1 0 Function 0 dB gain -2 dB gain in 2 dB step -30 dB gain 0 0 1 *: state at power on initialization Earpiece ampifier [EARA] 0 0 1 0 0 1 0 0 1 0 1 1 Extra amplifier [EXTA] * 0 0 1 0 0 1 0 1 1 0 dB gain -2 dB gain in 2 dB step -30 dB gain * Table 9: Control Register CR7 Functions 7 0 0 0 0 0 0 0 0 1 1 6 0 0 0 0 1 1 1 1 X X 5 0 0 1 1 0 0 1 1 X X 4 0 1 0 1 0 1 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 1 *: (2): X state at power on initialization value provided if f1 or f2 is selected alone. if f1 and f2 are selected in the summed mode, f1=0.89 V pp while f2=0.7 Vpp. reserved: write 0 3 F1 2 F2 1 SN 0 DE Attenuation ....0 dB * -3 dB -6 dB - 9 dB -12 dB -15 dB -18 dB -21 dB -24 dB -27 dB f1 f2 f1 f1 and f2 muted selected selected and f2 in summed mode Function f1 Vpp ...1.6(2) f2 Vpp 1.26(2) Tone gain 0.066 0.053 * Squarewave signal selected Sinewave signal selected Normal operation Tone / Ring Generator connected to Transmit path * * 11/29 ST5092 Table 10: Control Register CR8 Functions 7 f17 msb 6 f16 5 f15 4 f14 3 f13 2 f12 1 f11 0 f10 lsb Function Binary equivalent of the decimal number used to calculate f1 Table 11: Control Register CR9 Functions 7 f27 msb 6 f26 5 f25 4 f24 3 f23 2 f22 1 f21 0 f20 lsb Function Binary equivalent of the decimal number used to calculate f2 Table 12: Control Register CR10 Functions 7 X 6 X 5 X 4 X 3 X 2 X 0 0 1 1 (*) Default values inserted into the Register at Power On. X reserved, write 0. 1 0 DFT HFT 0 1 0 1 Function (*) Standard Frequency Tone Range Halved Frequency Tone Range Doubled Frequency Tone Range Forbidden Table 13: Control Register CR11 Functions 7 BE 0 1 0 1 msb * state at power on initialization 6 BI 5 4 3 BZ3 2 1 0 BZ0 BZ5 BZ4 BZ2 BZ1 Function Buzzer output disabled (set to 0) Buzzer output enabled Duty Cycle is intended as the relative width of logic 1 Duty cycle is intended as the relative width of logic 0 * * lsb Binary equivalent of the decimal number used to calculate the duty cycle. 12/29 ST5092 CONTROL REGISTER CR0 First byte of a READ or a WRITE instruction to Control Register CR0 is as shown in TABLE 1. Second byte is as shown in TABLE 2. Master Clock Frequency Selection A master clock must be provided to ST5092 for operation of filter and coding/decodingfunctions. MCLK frequency can be either 512 kHz, 1.536 MHz, 2.048 MHz or 2.56 MHz. Bit F1 (7) and F0 (6) must be set during initialization to select the correct internal divider. Default value is 512 kHz. Any clock different from the default one must be selected prior a Power-Up instruction. Coding Law Selection Bits MA (4) and IA (3) permit selection of Mu-255 law or A law coding with or without even bit inversion if companded code (bit CM = 1) is selected. Bits MA(4) and IA(3) permit selection of 2-complement, 1-complement or sign and magnitude if linear code (bit CM = 0) is selected. Coding Selection Bit CM (5) permits selection either of linear coding (14-bit) or companded coding (8-bit). Default value is linear coding. Digital Interface format (1) Bit FF(2) = 0 selects digital interface in Format 1 where B1 and B2 channel are consecutive. FF=1 selects Format 2 where B1 and B2 channel are separated by two bits. (See digital interface format section.) 56+8 selection (1) Bit 'B7' (1) selects capability for ST5092 to take into account only the seven most significant bits of the PCM data byte selected. When 'B7' is set, the LSB bit on DR is ignored and LSB bit on DX is high impedance. This function allows connection of an external "in band" data generator directly connected on the Digital Interface. Digital loopback Digital loopback mode is entered by setting DL bit(0) equal 1. In Digital Loopback mode, data written into Receive PCM Data Register from the selected received time-slot is read-back from that Register in the selected transmit time-slot on DX. No PCM decoding or encoding takes place in this mode. Transmit and Receive amplifier stages are muted. CONTROL REGISTER CR1 First byte of a READ or a WRITE instruction to Control Register CR1 is as shown in TABLE 1. Second byte is as shown in TABLE 3. Digital Interface Timing Bit DM1(7) = 0 selects digital interface in delayed timing mode, while DM1 = 1 and DM0 = 0 selects non-delayed normal data timing mode, and DM1 = 1 and DM0 = 1 selects non-delayed reverse data timing mode. Default is delayed data timing. Latch output control Bit DO controls directly logical status of latch output LO: ie, a "ZERO" written in bit DO puts the output LO at logical 1, while a "ONE" written in bit DO sets the output LO to zero. Microwire access to B channel on receive path (1) Bit MR (4) selects access from MICROWIRE Register CR2 to Receive path. When bit MR is set high, data written to register CR2 is decoded each frame, sent to the receive path and data input at DR is ignored. In the other direction, current PCM data input received at DR can be read from register CR2 each frame. Microwire access to B channel on transmit path (1) Bit MX (3) selects access from MICROWIRE write only Register CR3 to DX output. When bit MX is set high, data written to CR3 is output at DX every frame and the output of PCM encoder is ignored. (1) Significant in companded mode only Mu 255 law msb Vin = + full scale Vin = 0 V Vin = - full scale 1 1 0 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 lsb 0 1 1 0 0 1 1 0 True A law even bit inversion msb 1 1 0 0 0 1 1 0 1 0 0 1 0 1 1 0 1 0 0 1 0 1 1 0 lsb 1 0 0 1 0 1 1 0 1 1 0 0 A law without even bit inversion msb 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 lsb 1 0 0 1 1 0 0 1 MSB is always the first PCM bit shifted in or out of: ST5092. 13/29 ST5092 Transmit/Receive enabling/disabling Bit 'EN' (2) enables or disables voice data transfer on DX and DR pins. When disabled, PCM data from DR is not decoded and PCM time-slots are high impedance on DX. Default value is disabled. B-channel selection (1) Bit TS(1) permits selection between B1 or B2 channels. Default value is B1 channel. CONTROL REGISTER CR2 (1) Data sent to receive path or data received from DR input. Refer to bit MR(4) in "Control Register CR1" paragraph. CONTROL REGISTER CR3 (1) DX data transmitted. Refer to bit MX(3) in "Control Register CR1" paragraph. CONTROL REGISTER CR4 First byte of a READ or a WRITE instruction to Control Register CR4 is as shown in TABLE 1. Second byte is as shown in TABLE 6. Transmit Input Selection MIC1 or MIC2 or MIC3 or transmit mute can be selected with bits 6 and 7 (VS and TE). Transmit gain can be adjusted within a 22.5 dB range in 1.5 dB step with Register CR5. Sidetone Selection Bit "SI" (5) enables or disables Sidetone circuitry. When enabled, sidetone gain can be adjusted with Register (CR5). When Transmit path is disabled, sidetone circuit is also disabled. Output Driver Selection Bits OE1(4) and OE2(3) provide the selection among the earpiece output or the extra amplifier output or both outputs muted. OE1 = 1 and OE2 = 1 is not allowed. Ring/Tone signal selection Bit RTE (2) provide select capability to connect on-chip Ring/Tone generator either to an extra amplifier input or to earpiece amplifier input. Receive High Pass Filter Selection Bit HPB (1) provide the selection of the receive high pass filter cutoff frequency. PCM receive data selection Bits "SE" (0) provide select capability to connect received speech signal either to an extra amplifier input or to earpiece amplifier input. CONTROL REGISTER CR5 First byte of a READ or a WRITE instuction to Control Register CR5 is as shown in TABLE 1. Second byte is as shown in TABLE 7. Transmit gain selection Transmit amplifier can be programmed for a gain from 0dB to 22.5dB in 1.5dB step with bits 4 to 7. 0 dBmO level at the output of the transmit amplifier (A reference point) is 0.492 Vrms (overload voltage is 0.707 Vrms). Sidetone attenuation selection Transmit signal picked up after the switched capacitor low pass filter may be fed back into both Receive amplifiers. Attenuation of the signal at the output of the sidetone attenuator can be programmed from -12.5dB to -27.5dB relative to reference point A in 1 dB step with bits 0 to 3. CONTROL REGISTER CR6 First byte of a READ or a WRITE instruction to Control Register CR6 is as shown in TABLE 1. Second byte is as shown in TABLE 8. Earpiece amplifier gain selection: Earpiece Receive gain can be programmed in 2 dB step from 0 dB to -30 dB relative to the maximum with bits 4 to 7. 0 dBmO voltage at the output of the amplifier on pins VFr+ and VFr- is then 1.965 Vrms when 0dB gain is selected down to 61.85 Vrms when -30dB gain is selected. Extra amplifier gain selection: Extra Receive amplifier gain can be programmed in 2 dB step from 0 dB to -30 dB relative to the maximum with bits 0 to 3. 0 dBmO voltage on the output of the amplifier on pins VLr+ and VLr- 1.965 Vrms when 0 dB gain is selected down to 61.85 mVrms when -30 dB gain is selected. CONTROL REGISTER CR7: First byte of a READ or a WRITE instruction to Control Register CR7 is as shown in TABLE 1. Second byte is as shown in TABLE 9. (1) Significant in companded mode only 14/29 ST5092 Tone/Ring amplifier gain selection Output level of Ring/Tone generator, before attenuation by programmable attenuator is 1.6 Vpkpk when f1 generator is selected alone or summed with the f2 generator and 1.26 Vpk-pk when f2 generator is selected alone. Selected output level can be attenuated down to -27 dB by programmable attenutator by setting bits 4 to 7. Frequency mode selection Bits 'F1' (3) and 'F2' (2) permit selection of f1 and/or f2 frequency generator according to TABLE 9. When f1 (or f2) is selected, output of the Ring/Tone is a squarewave (or a sinewave) signal at the frequency selected in the CR8 (or CR9) Register. When f1 and f2 are selected in summed mode, output of the Ring/Tone generator is a signal where f1 and f2 frequency are summed. In order to meet DTMF specifications, f2 output level is attenuated by 2dB relative to the f1 output level. Frequency temporization must be controlled by the microcontroller. Waveform selection Bit 'SN' (1) selects waveform of the output of the Ring/Tone generator. Sinewave or squarewave signal can be selected. DTMF selection Bit DE (0) permits connection of Ring/Tone/DTMF generator on the Transmit Data path instead of the Transmit Amplifier output. Earpiece or extra receive output feed-back may be provided by sidetone circuitry by setting bit SI or directly by setting bit RTE in Register CR4. Loudspeaker feed-back may be provided directly by setting bit RTL in Register CR4. CONTROL REGISTERS CR8 AND CR9 First byte of a READ or a WRITE instruction to Control Register CR8 or CR9 is as shown in TABLE 1. Second byte is respectively as shown in TABLE 10 and 11. If "standard frequency tone range" is selected, Tone or Ring signal frequency value is defined by the formula: f1 = CR8 / 0.128 Hz and f2 = CR9 / 0.128 Hz where CR8 and CR9 are decimal equivalents of the binary values of the CR8 and CR9 registers respectively. Thus, any frequency between 7.8 Hz and 1992 Hz may be selected in 7.8 Hz step. If "halved frequency tone range"is selected, Tone or Ring signal frequency value is defined by the formula: f1 = CR8 / 0.256 Hz and f2 = CR9 / 0.256 Hz This any frequency between 3.9Hz and 996Hz may be selected in 3.9Hz step. If "doubled frequency tone range"is selected, Tone or Ring signal frequency value is defined by the formula: f1 = CR8 / 0.064 Hz and f2 = CR9 / 0.064 Hz Thus any frequency between 15.6Hz and 3984Hz may be selected in 15.6Hz step. TABLE 12 gives examples for the main frequencies usual for Tone or Ring generation. CONTROL REGISTER CR10 Bit DFT(1) and HFT(0) permits the selection among "standard frequency tone range" (i.e. from 7.8Hz to 1992Hz in 7.8Hz step), "halved frequency tone range" (i.e. from 3.9Hz to 996Hz in 3.9Hz step), and "doubled frequency tone range" (i.e. from 15.6Hz to 3984Hz in 15.6Hz step) according to the values described in CONTROL REGISTER CR8 and CR9. CONTROL REGISTER CR11 Bit BE(7) permits connection of a f1 squarewave PWM Ring signal, amplitude modulated or not by a f2 squarewave signal, to buzzer driver output BZ. Bits BZ5 to BZ0 define the duty cycle of the PWM squarewave, according to the following formula: Duty Cycle = CR11(5 / 0) x 0.78125% where CR11(5 / 0) is the decimal equivalent of the binary value BZ5 / BZ0. When BE = 1, if bits F1 = 1 and F2 = 0 in register CR7, a f1 PWM ring signal is present at the buzzer output, while if bits F1 = 1 and F2 = 1 in register CR7 the f1 PWM ring signal is also amplitude modulated by a f2 squarewave frequency. Bit BI (6) allows to chose the logic level at which the duty cycle is referred: BI = 0 means that duty cycle is intended as the relative width of the logic1, while BI = 1 means that duty cycle is intended as the relative width of the logic 0. When BE = 0 (or during power down) BZ = 0 if BI = 0 or BZ = 1 if BI = 1. 15/29 ST5092 Table 12: Examples of Usual Frequency Selection (Standard frequency tone range) Description Tone Tone Tone Tone Tone Tone 250 Hz 330 Hz 425 Hz 440 Hz 800 Hz 1330 Hz f1 value (decimal) 32 42 54 56 102 170 89 99 109 120 155 171 189 209 50 56 63 67 75 80 84 89 95 100 106 113 126 134 150 169 Theoretic value (Hz) 250 330 425 440 800 1330 697 770 852 941 1209 1336 1477 1633 392 440 494 523.25 587.33 622.25 659.25 698.5 740 784 830.6 880 987.8 1046.5 1174.66 1318.5 Typical value (Hz) 250 328.2 421.9 437.5 796.9 1328.1 695.3 773.4 851.6 937.5 1210.9 1335.9 1476.6 1632.8 390.6 437.5 492.2 523.5 586.0 625.0 656.3 695.3 742.2 781.3 828.2 882.9 984.4 1046.9 1171.9 1320.4 Error % .00 -.56 -.73 -.56 -.39 -.14 -.24 +.44 -.05 -.37 +.16 -.01 .00 .00 -.30 -.56 -.34 +.04 -.23 +.45 -.45 -.45 +.30 -.34 -.29 +.33 -.34 +.04 -.23 +.14 DTMF 697 Hz DTMF 770 Hz DTMF 852 Hz DTMF 941 Hz DTMF 1209 Hz DTMF 1336 Hz DTMF 1477 Hz DTMF 1633 Hz SOL LA SI DO RE MI flat MI FA FA sharp SOL SOL sharp LA SI DO RE MI 16/29 ST5092 TIMING DIAGRAM Non Delayed Data Timing Mode (Normal) (*) 16 17 16 16 Delayed Data Timing Mode (*) 16 17 16 16 (*) In the case of companded code the timing is applied to 8 bits instead of 16 bits (see ST5080A data sheet) 17/29 ST5092 TIMING DIAGRAM (continued) Non Delayed Reverse Data Timing Mode (*) tHMFR tRM tFM tWMM 1 2 3 4 5 6 7 16 17 MCLK tSFMR tHMFR tWML FS tDFD tDMDR tDMZR DX 1 2 3 4 5 6 7 16 tSDM tHMDR DR 1 2 3 4 5 6 7 16 D93TL076A (*) In the case of companded code the timing is applied to 8 bits instead of 16 bits. Serial Control Timing (MICROWIRE MODE) 18/29 ST5092 ABSOLUTE MAXIMUM RATINGS Parameter VCC to GND Voltage at MIC (VCC 3.6V) Current at VFr and VLr Current at any digital output Voltage at any digital input (VCC 3.6V); limited at + 50mA Storage temperature range Lead Temperature (wave soldering, 10s) Value 5.5 VCC +1 to GND -1 + 100 + 50 VCC + 1 to GND - 1 - 65 to + 150 + 260 Unit V V mA mA V C C TIMING SPECIFICATIONS (unless otherwise specified, VCC = 2.7V to 3.6V, TA = -30Cto 85C ; typical characteristics are specified VCC = 3.0V, TA = 25 C; all signals are referenced to GND, see Note 5 for timing definitions) NOTICE: All timing specifications can be changed. MASTER CLOCK TIMING Symbol fMCLK Parameter Frequency of MCLK Test Condition Selection of frequency is programmable (see table 2) Min. Typ. 512 1.536 2.048 2.560 80 80 30 30 Max. Unit kHz MHz MHz MHz ns ns ns ns tWMH tWML tRM tFM Period of MCLK high Period of MCLK low Rise Time of MCLK Fall Time of MCLK Measured from VIH to VIH Measured from VIL to VIL Measured from VIL to VIH Measured from VIH to VIL PCM INTERFACE TIMING Symbol tHMF tSFM tDMD tDMZ tDFD Parameter Hold Time MCLK low to FS low Setup Time, FS high to MCLK low Delay Time, MCLK high to data valid Delay Time, MCLK low to DX disabled Delay Time, FS high to data valid Load = 100 pf ; Applies only if FS rises later than MCLK rising edge in Non Delayed Mode only 20 10 30 30 Load = 100pF 10 20 100 100 Load = 100 pf 10 Test Condition Min. 0 30 100 100 100 Typ. Max. Unit ns ns ns ns ns tSDM tHMD tHMFR tSFMR tDMDR tDMZR tHMDR Setup Time, D R valid to MCLK receive edge Hold Time, MCLK low to DR invalid Hold Time MCLK High to FS low Setup Time, FS high to MCLK High Delay Time, MCLK low to data valid Delay Time, MCLK High to DX disabled Hold Time, MCLK High to DR invalid ns ns ns ns ns ns ns 19/29 ST5092 SERIAL CONTROL PORT TIMING Symbol fCCLK tWCH tWCL tRC tFC tHCS tSSC tSDC tHCD tDCD tDSD tDDZ Parameter Frequency of CCLK Period of CCLK high Period of CCLK low Rise Time of CCLK Fall Time of CCLK Hold Time, CCLK high to CS- low Setup Time, CS- low to CCLK high Setup Time, CI valid to CCLK high Hold Time, CCLK high to CI invalid Delay Time, CCLK low to CO data valid Delay Time, CS-low to CO data valid Delay Time CS-high or 8th CCLK low to CO high impedance whichever comes first Hold Time, 8th CCLK high to CS- high Setup Time, CS- high toCCLK high A signal is valid if it is above VIH or below VIL and invalid if it is between VIL and VIH. For the purpoes of this specification the following conditions apply: a) All input signal are defined as: VIL = 0.2VCC, VIH = 0.8VCC, tR < 10ns, tF < 10ns. b) Delay times are measured from the inputs signal valid to the output signal valid. c) Setup times are measured from the data input valid to the clock input invalid. d) Hold times are measured from the clock signal valid to the data input invalid. Test Condition Measured from VIH to VIH Measured from VIL to VIL Measured from VIL to VIH Measured from VIH to VIL Min. 160 160 Typ. Max. 2.048 Unit MHz ns ns 50 50 10 50 50 50 ns ns ns ns ns ns Load = 100 pF 80 50 10 80 ns ns ns tHSC tSCS Note 5: 100 100 ns ns ELECTRICAL CHARACTERISTICS (unless otherwise specified, VCC = 2.7V to 3.6V, TA = --30C to 85C ; typical characteristic are specified at VCC = 3.0V, TA = 25C ; all signalsare referencedto GND) DIGITAL INTERFACES Symbol V IL VIH V OL VOH IIL IIH IOZ Parameter Input Low Voltage Input High Voltage Output Low Voltage Output High Voltage Input Low Current Input High Current Output Current in High impedance (Tri-state) Test Condition All digital inputs All digital inputs All digital outputs, IL = 10A All digital outputs, IL = 2mA All digital outputs, IL = 10A All digital outputs, IL = 2mA Any digital input, GND < VIN < VIL Any digital input, VIH < VIN < VCC D X and CO Min. DC AC DC AC 0.7VCC 0.8VCC 0.1 0.4 VCC-0.1 VCC-0.4 -10 -10 -10 Typ. Max. 0.3V CC 0.2V CC Unit V V V V V V V V A A A 10 10 10 A.C. TESTING INPUT, OUTPUT WAVEFORM INTPUT/OUTPUT 0.8VCC 0.7VCC TEST POINTS 0.2VCC 0.3VCC 0.3VCC D93TL077 0.7VCC AC Testing: inputs are driven at 0.8V CC for a logic "1"and 0.2VCC for a logic "0 ". Timing measurements are made at 0.7VCC for a logic "1"and 0.3V CC for a logic "0". 20/29 ST5092 ANALOG INTERFACES Symbol IMIC RMIC R LVFr C LVFr ROVFr0 VOSVFr0 Parameter Input Leakage Input Resistance Load Resistance (*) Load Capacitance (*) Output Resistance Differential offset: Voltage at VFr+, VFrLoad Resistance (*) Load Capacitance (*) Output Resistance Differential offset Voltage at VLr+, VLrTest Condition GND < VMIC < VCC GND < VMIC < VCC VFr+ to VFrFrom VFr+ to VFrSteady zero PCM code applied to DR; I = + 1mA Alternating + zero PCM code applied to DR maximum receive gain; RL = 100 VLr+ to VLrfrom VLr+ to VLrSteady zero PCM code applied to DR; I + 1mA Alternating + zero PCM code applied to DR maximum receive gain; RL = 50 -100 -100 Min. -100 50 30 50 1.0 +100 Typ. Max. +100 Unit A k nF mV R LvLr C LvLr R OLVrO VOSVLrO 30 50 1 +100 nF mV (*) See application note for VFr and VLr connections. POWER DISSIPATION Symbol ICC0 ICC1 Parameter Power down Current Power Up Current Test Condition CCLK,CI = 0.1V; CS = VCC-0.1V VLr+, VLr- and VFr+, VFr- not loaded Min. Typ. 0.5 5 Max. 5 8 Unit A mA TRANSMISSION CHARACTERISTICS (unless oth erwise spe cified , V C C = 2 .7V to 3. 6V, T A = - 30 C t o 8 5C; ty pical ch aract erist ic s are sp ec if ied at V C C = 3.0 V, T A = 25 C, MIC1/ 2/ 3 = 0dBm0, DR = -6dBm0 PCM code, f = 1015.625 Hz; all signal are referenced to GND) AMPLITUDE RESPONSE (Maximum, Nominal, and Minimum Levels) Transmit path - Absolute levels at MIC1 / MIC2 / MIC3 Parameter 0 dBm0 level Overload level 0 dBm0 level Overload level Transmit Amps connected for 42.5dB gain Test Condition Transmit Amps connected for 20dB gain Min. Typ. 49.26 70.71 3.694 5.302 Max. Unit mVRMS mVRMS mVRMS mVRMS 21/29 ST5092 TRANSMISSION CHARACTERISTICS (continued) AMPLITUDE RESPONSE (Maximum, Nominal, and Minimum Levels) Receive path - Absolute levels at VFR (Differentially measured) Parameter 0 dBM0 level 0 dBM0 level Test Condition Receive Amp programmed for 0dB gain Receive Amp programmed for - 30dB attenuation Min. Typ. 1.965 61.85 Max. Unit VRMS mVRMS AMPLITUDE RESPONSE (Maximum, Nominal, and Minimum Levels) Receive path - Absolute levels at VLr (Differentially measured) Parameter 0 dBM0 level 0 dBM0 level Test Condition Receive Amp programmed for 0dB gain Receive Amp programmed for - 30dB gain Min. Typ. 1.965 61.85 Max. Unit VRMS mVRMS AMPLITUDE RESPONSE Transmit path Symbol GXA Parameter Transmit Gain Absolute Accuracy Test Condition Transmit Gain Programmed for minimum. Measure deviation of Digital PCM Code from ideal 0dBm0 PCM code at DX Measure Transmit Gain over the range from Maximum to minimum setting. Calculate the deviation from the programmed gain relative to GXA, i.e. GAXG = G actual - G prog. - GXA Measured relative to GXA. min. gain < GX < Max. gain Measured relative to GXA GX = Minimum gain Relative to 1015,625 Hz, multitone test technique used. min. gain < GX < Max. gain f = 60 Hz f = 100 Hz f = 200 Hz f = 300 Hz f = 400 Hz to 3000 Hz f = 3400 Hz f = 4000 Hz f = 4600 Hz (*) f = 8000 Hz (*) Sinusoidal Test method. Reference Level = -10 dBm0 VMIC = -40 dBm0 to +3 dBm0 VMIC = -50 dBm0 to -40 dBm0 VMIC = -55 dBm0 to -50 dBm0 Min. -0.5 Typ. Max. 0.5 Unit dB GXAG Transmit Gain Variation with programmed gain -0.5 0.5 dB GXAT GXAV GXAF Transmit Gain Variation with temperature Transmit Gain Variation with supply Transmit Gain Variation with frequency -0.1 -0.1 0.1 0.1 dB dB -1.5 -0.5 -1.5 -30 -20 -6 0.5 0.5 0.0 -14 -35 -47 dB dB dB dB dB dB dB dB dB GXAL Transmit Gain Variation with signal level -0.5 -0.5 -1.2 0.5 0.5 1.2 dB dB dB (*) The limit at frequencies between 4600Hz and 8000Hz lies on a straight line connecting the two frequencies on a linear (dB) scale versus log (Hz) scale. 22/29 ST5092 AMPLITUDE RESPONSE Receive path Symbol GRAE Parameter Receive Gain Absolute Accuracy Test Condition Receive gain programmed for maximum Apply -6 dBm0 PCM code to D R Measure V Fr+ Receive gain programmed for maximum Apply -6 dBm0 PCM code to D R Measure V Lr+ Measure V Fr Gain over the range from Maximum to minimum setting. Calculate the deviation from the programmed gain relative to GRAE, i.e. GRAGE = G actual - G prog. - GRAE Measure V Lr Gain over the range from Maximum to minimum setting. Calculate the deviation from the programmed gain relative to GRAL, i.e. GRAGL = G actual - G prog. - GRAL Measured relative to GRA. (VLr and VFr) min. gain < GR < Max. gain Measured relative to GRA. (VLr and VFr) GR = Maximum Gain Relative to 1015,625 Hz, multitone test technique used. min. gain < GR < Max. gain f = 60Hz f = 100Hz f = 200 Hz f = 300 Hz f = 400 Hz to 3000 Hz f = 3400 Hz f = 4000 Hz Relative to 1015,625 Hz, multitone test technique used. min. gain < GR < Max. gain f = 50Hz f = 100 Hz to 3000 Hz f = 3400 Hz f = 4000 Hz Sinusoidal Test Method Reference Level = -10 dBm0 D R = -40 dBm0 to -3 dBm0 D R = -50 dBm0 to -40 dBm0 D R = -55 dBm0 to -50 dBm0 Sinusoidal Test Method Reference Level = -10 dBm0 D R = -40 dBm0 to -3 dBm0 D R = -50 dBm0 to -40 dBm0 D R = -55 dBm0 to -50 dBm0 Min. -0.5 Typ. Max. 0.5 Unit dB GRAL Receive Gain Absolute Accuracy -0.5 0.5 dB GRAGE Receive Gain Variation with programmed gain -0.5 0.5 dB GRAGL Receive Gain Variation with programmed gain -0.5 0.5 dB GRAT Receive Gain Variation with temperature Receive Gain Variation with Supply Receive Gain Variation with frequency (VLr and VFr) HPB = 0 -0.1 0.1 dB GRAV -0.1 0.1 dB GRAF -1.5 -0.5 -1.5 -20 -12 -2 0.5 0.5 0.0 -14 dB dB dB dB dB dB dB Receive Gain Variation with frequency (VLr and VFr) HPB = 1 -1.5 -0.5 -1.5 0.5 0.5 0.0 -14 dB dB dB dB GRAL E Receive Gain Variation with signal level (VFr) -0.5 -0.5 -1.2 0.5 0.5 1.2 dB dB dB GRAL L Receive Gain Variation with signal level (VLr) -0.5 -0,5 -1.2 0.5 0.5 1.2 dB dB dB 23/29 ST5092 ENVELOPE DELAY DISTORTION WITH FREQUENCY Symbol DXA DXR Parameter Tx Delay, Absolute Tx Delay, Relative f= f= f= f= f= f= f= f= f= f= f= f= f= f= Test Condition f = 1600 Hz 500 - 600 Hz 600 - 800 Hz 800 - 1000 Hz 1000 - 1600 Hz 1600 - 2600 Hz 2600 - 2800 Hz 2800 - 3000 Hz 500 - 600 Hz 600 - 800 Hz 800 - 1000 Hz 1000 - 1600 Hz 1600 - 2600 Hz 2600 - 2800 Hz 2800 - 3000 Hz Min. Typ. 320 290 180 50 20 55 80 180 280 200 110 50 20 65 100 220 Max. Unit s s s s s s s s s s s s s s s s DRA DRR Rx Delay, Absolute Rx Delay, Relative f = 1600 Hz NOISE Symbol NXP NRP NRS Parameter Tx Noise, P weighted (up to 35dB) Rx Noise, A weighted (max. gain) Noise, Single Frequency Test Condition VMIC = 0V, DE = 0 Receive PCM code = Positive Zero SI = 0 and RTE = 0 MIC = 0V, Loop-around measurament from f = 0 Hz to 100 kHz MIC = 0V, VCC = 3.3 VDC + 50 mVrms; f = 0Hz to 50KHz PCM Code equals Positive Zero, VCC = 3.3 VDC + 50 mVrms, f = 0 Hz - 4 kHz f = 4 kHz - 50 kHz DR input set to -6 dBm0 PCM code 300 - 3400 Hz Input PCM Code applied at DR 4600 Hz - 5600 Hz 5600 Hz - 7600 Hz 7600 Hz - 8400 Hz 30 Min. Typ. -75 120 -50 Max. -70 150 Unit dBm0p Vrms (*) dBm0 PPSRx PSRR, Tx 60 dB PPSRp PSRR, Rx 30 30 70 70 dB dB SOS Spurious Out-Band signal at the output -40 -50 -50 dB dB dB (*) A Weighted 24/29 ST5092 DISTORTION Symbol STDX (*) Parameter Signal to Total Distortion (up to 35dB gain) Typical values are measured with 30.5dB gain Test Condition Sinusoidal Test Method (measured using linear 300 to 3400 weighting) Level = 0 dBm0 Level = -6 dBm0 Level = -10 dBm0 Level = -20 dBm0 Level = -30 dBm0 Level = -40 dBm0 Level = -45 dBm0 Level = -55 dBm0 0 dBm0 input signal Sinusoidal Test Method (measured using linear 300 to 3400 weighting) Level = -6 dBm0 Level = -10 dBm0 Level = -20 dBm0 Level = -30 dBm0 Level = -40 dBm0 Level = -45 dBm0 Level = -55 dBm0 -6 dBm0 input signal Sinusoidal Test Method (measured using linear 300 to 3400 weighting) Level = -6 dBm0 Level = -10 dBm0 Level = -20 dBm0 Level = -30 dBm0 Level = -40 dBm0 Level = -45 dBm0 Level = -55 dBm0 -6 dBm0 input signal Loop-around measurement Voltage at MIC = -10 dBm0 to -27 dBm0, 2 Frequencies in the range 300 - 3400 Hz Min. # 56 56 50 50 48 48 43 43 38 37.5 29 28.5 24 23 15 13 65 64 61 52 42 31 26 16 -80 -56 dB dB dB dB dB dB dB dB dB Typ. Max. Unit SDFx STDRE (*) Single Frequency Distortion transmit Signal to Total Distortion (VFr) ( up to 20dB attenuation) Typical values are measured with 20dB attenuation. 50 48 43 38 29 24 15 64 62 53 43 33 28 18 -80 -50 dB dB dB dB dB dB dB dB SDFr STDRL (*) Single Frequency Distortion receive (VFr) Signal to Total Distortion (VLr) (up to 20dB attenuation) Typical values are measured with 20dB attenuation 50 48 43 38 29 24 15 64 62 53 43 33 28 18 -80 -75 -50 -46 dB dB dB dB dB dB dB dB dB SDLr IMD Single Frequency Distortion receive (VLr) Intermodulation (*) The limit curve shall be determined by straight lines joining successive coordinates given in the table. (#) Lower limits used during the automatic testing to avoid unrealistic yield loss due to 2dB imprecision of time-limited noise measurements. CROSSTALK Symbol CTx-r Parameter Transmit to Receive Test Condition Transmit Level = 0 dBm0, f = 300 - 3400 Hz DR = Quiet PCM Code Receive Level = -6 dBm0, f = 300 - 3400 Hz MIC = 0V Min. Typ. -100 Max. -65 Unit dB CTr-x Receive to Transmit -80 -65 dB 25/29 ST5092 APPLICATIONS Application Note for Microphone Connections ST5092 ST5092 ST5092 Application Note for VFr and VLr Connections DYNAMIC RECEIVERS (32) R VFr+ VFr+ VFr+ CERAMIC RECEIVERS (50nF) DYNAMIC/CERAMIC RECEIVERS (REVERSIBLE) VFr- VFr- VFr- ST5092 ST5090 R VLr+ ST5090 ST5092 R VLr+ ST5090 ST5092 VLr+ VLr- VLr- VLr- D93TL078A R must be greater than 30 For higher capacitive transducers, lower R values can be used. POWER SUPPLIES While pins of ST5092 device are well protected against electrical misuse, it is recommended that the standard CMOS practise of applying GND before any other connections are made should always be followed. In applications where the printed circuit card may be plugged into a hot socket with power and clocks already present, an extra long ground pin on the connector should be 26/29 used. To minimize noise sources, all ground connections to each device should meet at a common point as close as possible to the GND pin in order to prevent the interaction of ground return currents flowing through a common bus impedance. A power supply decoupling capacitor of 0.1 F should be connected from this common point to VCC as close as possible to the device pins. ST5092 TQFP44 (10 x 10) PACKAGE MECHANICAL DATA DIM. MIN. A A1 A2 B C D D1 D3 e E E1 E3 L L1 K 0.45 0.05 1.35 0.30 0.09 12.00 10.00 8.00 0.80 12.00 10.00 8.00 0.60 1.00 0(min.), 3.5(typ.), 7(max.) 0.75 0.018 1.40 0.37 mm TYP. MAX. 1.60 0.15 1.45 0.45 0.20 0.002 0.053 0.012 0.004 0.472 0.394 0.315 0.031 0.472 0.394 0.315 0.024 0.039 0.030 0.055 0.014 MIN. inch TYP. MAX. 0.063 0.006 0.057 0.018 0.008 D D1 D3 A1 33 34 23 22 0.10mm .004 Seating Plane A A2 E3 E1 B 44 1 11 12 E B C L K e L1 TF4 QP4 27/29 ST5092 SO28 PACKAGE AND MECHANICAL DATA DIM. MIN. A a1 b b1 C c1 D E e e3 F L S 7.4 0.4 17.7 10 1.27 16.51 7.6 1.27 8 (max.) 0.291 0.016 18.1 10.65 0.1 0.35 0.23 0.5 45 (typ.) 0.697 0.394 0.050 0.65 0.299 0.050 0.713 0.419 mm TYP. MAX. 2.65 0.3 0.49 0.32 0.004 0.014 0.009 0.020 MIN. inch TYP. MAX. 0.104 0.012 0.019 0.013 28/29 ST5092 Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specification mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGSTHOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics. (c) 1997 SGS-THOMSON Microelectronics - Printed in Italy - All Rights Reserved SGS-THOMSON Microelectronics GROUP OF COMPANIES Australia - Brazil - Canada - China - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A. 29/29 |
Price & Availability of ST5092
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |