TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 1 post office box 655303 ? dallas, texas 75265 � single 5-v operation � low power consumption: operating mod e...40 mw typ standby mod e... 5 mw typ power-down mod e...3 mw typ � combined a/d, d/a, and filters � extended variable-frequency operation sample rates up to 16 khz pass-band up to 7.2 khz � electret microphone bias reference voltage available � drive a piezo speaker directly � compatible with all digital signal processors (dsps) � selectable between 8-bit companded and 13-bit (dynamic range) linear conversion: TCM320AC36 . . . m -law and linear modes tcm320ac3 7... a-law and linear modes � programmable volume control in linear mode � 300 hz 3.6 khz passband with specified master clock � designed for standard 2.048-mhz master clock for u.s. analog, u.s. digital, ct2, dect, gsm, and pcs standards for hand-held battery-powered telephones 1 2 3 4 5 6 7 8 9 10 20 19 18 17 16 15 14 13 12 11 pdn eara earb eargs v cc micmute dclkr din fsr earmute micbias micgs micin vmid gnd linsel tsx /dclkx dout fsx clk dw or n package (top view) 14 15 vmid nc agnd nc nc nc nc nc nc dgnd linsel nc 36 35 34 33 32 31 30 29 28 27 26 25 16 1 2 3 4 5 6 7 8 9 10 11 12 nc nc nc av cc nc nc nc nc dv cc nc micmute nc 17 18 19 20 pt package (top view) micgs micin nc nc 47 46 45 44 43 48 42 nc nc eargs earb eara pdn tsx/dclkx nc nc din earmute nc clk fsx dout 40 39 38 41 21 22 23 24 37 13 nc micbias nc dclkr fsr nc no internal connection these devices have limited built-in esd protection. the leads should be shorted together or the device placed in conductive foa m during storage or handling to prevent electrostatic damage to the mos gates. please be aware that an important notice concerning availability, standard warranty, and use in critical applications of texas instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. vbap is a trademark of texas instruments incorporated. production data information is current as of publication date. products conform to specifications per the terms of texas instruments standard warranty. production processing does not necessarily include testing of all parameters. copyright ? 1998, texas instruments incorporated
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 2 post office box 655303 ? dallas, texas 75265 description the TCM320AC36 and tcm320ac37 voice-band audio processor (vbap) integrated circuits are designed to perform the transmit encoding (a /d conversion) and receive decoding (d/a conversion) together with transmit and receive filtering for voice-band communications systems. cellular telephone systems are targeted in particular; however, these integrated circuits can function in other systems including digital audio, telecommunications, and data acquisition. these devices are pin-selectable for either of two modes, companded and linear, providing data in two formats. in the companded mode, data is transmitted and received in 8-bit words. in the linear mode, 13 bits of data, and either three bits of gain-setting control data, or three zero bits of padding to create a 16-bit word, are sent and received. the transmit section is designed to interface directly with an electret microphone element. the microphone input signal (micin) is buffered and amplified, with provision for setting the amplifier gain to accommodate a range of signal input levels. the amplified signal is passed through antialiasing and band-pass filters. the filtered signal is then applied to the input of a compressing analog-to-digital converter (coadc) when companded mode is selected. otherwise, the analog-to-digital converter performs a linear conversion. the resulting data is then clocked out of dout as a serial data stream. the receive section takes a frame of serial data on din and converts it to analog through an expanding digital-to-analog converter (exdac) when the companded mode is selected; otherwise, a linear conversion is performed. the analog signal then passes through switched capacitor filters, which provide out-of-band rejection, (sin x)/x correction functions, and smoothing. the filtered signal is sent to the earphone amplifier. the earphone amplifier has a differential output with adjustable gain and is designed to minimize static power dissipation. a single on-chip high-precision band-gap circuit generates all voltage references, eliminating the need for external reference voltages. an internal reference voltage equal to v cc /2, vmid, is used to develop the midlevel virtual ground for all the amplifier circuits and the microphone bias circuit. another reference voltage, micbias, can supply bias current for the microphone. the tcm320ac3xc devices are characterized for operation from 0 c to 70 c. the tcm320ac3xi devices are characterized for operation from 40 c to 85 c.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 3 post office box 655303 ? dallas, texas 75265 functional block diagram 12 13 8 din fsr 7 14 15 linsel 1 pdn 16 gnd 5 v cc 10 4 3 2 earmute eargs earb eara earphone amplifier 256 khz a/d converter voltage reference band-gap voltage reference 8 khz 256 khz clock generator autozero dclkr clk tsx /dclkx fsx dout output logic adc micgs 20 17 19 18 6 vmid micbias vmid vmid generator micin micmute input buffer receive buffer receive filter dac input logic 256 khz 8 khz 9 linsel 15 11 transmit third-order antialias transmit sixth-order low pass transmit first-order high pass d/a converter voltage reference clock control terminal numbers shown are for the dw and n packages.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 4 post office box 655303 ? dallas, texas 75265 terminal functions terminal name no. i/o description name dw, n pt agnd e 34 ground return for all internal analog circuits av cc e 4 5-v supply voltage for all internal analog circuits clk 11 19 i clock input. in the fixed-data-rate mode, clk is the master clock input as well as the transmit and receive data clock input . in the variable-data-rate mode, clk is the master clock input only (digital). dclkr 7 14 i selection of fixed- or variable-data-rate operation. when dclkr is connected to v cc , the device operates in the fixed-data-rate mode. when dclkr is not connected to v cc , the device operates in the variable-data-rate mode, and dclkr becomes the receive data clock (digital). dgnd e 27 ground return for all internal digital circuits din 8 15 i receive data input. input data is clocked in on consecutive negative transitions of the receive data clock, which is clk for a fixed data rate and dclkr for a variable data rate (digital). dout 13 21 o transmit data output. transmit data is clocked out on consecutive positive transitions of the transmit data clock, which is clk for a fixed data rate and dclkx for a variable data rate (digital). dv cc e 9 5-v supply voltage for all internal digital circuits eara 2 44 o earphone output. eara forms a differential drive when used with the earb signal (analog). earb 3 45 o earphone output. earb forms a differential drive when used with the eara signal (analog). eargs 4 46 i earphone gain set input of feedback signal for the earphone output. the ratio of an external potential divider network connected across eara and earb adjusts the power amplifier gain. maximum gain occurs when eargs is connected to earb. minimum gain occurs when eargs is connected to eara. earphone frequency response correction is performed using an rc approach (analog). earmute 10 17 i earphone output mute control signal. when earmute is low, the output amplifier is disabled and no audio is sent to the earphone (digital). fsr 9 16 i frame-synchronization clock input for the receive channel. in the variable-data-rate mode, this signal must remain high for the duration of the time slot. the receive channel enters the standby condition when fsr is ttl-low for five frames or longer. the device enters a production test-mode condition when either fsr or fsx is held high for five frames or longer (digital). fsx 12 20 i frame synchronization clock input for the transmit channel. fsx operates independently of fsr, but also in an analogous manner to fsr. the transmit channel enters the standby condition when fsx is low for five frames or longer. the device enters a production test-mode condition when either fsx or fsr is held high for five frames or longer (digital). gnd 16 e ground return for all internal circuits linsel 15 26 i linear selection input. when low, linsel selects linear coding/decoding. when high, linsel selects companded coding/decoding. companding code on the 'ac36 is m -law, and companding code on the 'ac37 is a-law (digital). micbias 20 42 o microphone bias. micbias voltage for the electret microphone is equal to vmid. micgs 19 41 o output of the internal microphone amplifier. micgs is used as the feedback to set the microphone amplifier gain. if sidetone is required, it is accomplished by connecting a series network between micgs and eargs (analog). micin 18 40 i microphone input. electret microphone input to the internal microphone amplifier (analog) micmute 6 11 i microphone input mute control signal. when micmute is active (low), zero code is transmitted (dig.). pdn 1 43 i power-down input. when pdn is low, the device powers down to reduce power consumption (digital). tsx /dclkx 14 22 i/o transmit time slot strobe (active-low output) or data clock (input) for the transmit channel. in the fixed-data-rate mode, tsx /dclkx is an open-drain output that pulls to ground and is used as an enable signal for a 3-state buffer. in the variable-data-rate mode, dclkx becomes the transmit data clock input (digital). v cc 5 e 5-v supply voltage for all internal circuits vmid 17 36 o v cc /2 bias voltage reference. a pair of external, low-leakage, high-frequency capacitors (1 m f and 470 pf) should be connected between vmid and ground for filtering.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 5 post office box 655303 ? dallas, texas 75265 absolute maximum ratings over operating free-air temperature range (unless otherwise noted) 2 supply voltage range, v cc (see note 1) 0.3 v to 7 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . output voltage range at dout, v o 0.3 v to 7 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . input voltage range at din, v i 0.3 v to 7 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . continuous total power dissipation see dissipation rating table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . operating free-air temperature range: c suffix 0 c to 70 c . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i suffix 40 c to 85 c . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . storage temperature range, t stg 65 c to 150 c . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . lead temperature 1,6 mm (1/16 inch) from case for 10 seconds 260 c . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 stresses beyond those listed under aabsolute maximum ratingso may cause permanent damage to the device. these are stress rating s only, and functional operation of the device at these or any other conditions beyond those indicated under arecommended operating conditi onso is not implied. exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. note 1: voltage value is with respect to gnd. dissipation rating table package t a 25 c power rating derating factor above t a = 25 c t a = 70 c power rating t a = 85 c power rating dw 1025 mw 8.2 mw/ c 656 mw 533 mw n 1150 mw 9.2 mw/ c 736 mw 598 mw pt 1075 mw 7.1 mw/ c 756 mw 649 mw recommended operating conditions (see note 2) min max unit supply voltage, v cc (see note 3) 4.5 5.5 v high-level input voltage, v ih 2.2 v low-level input voltage, v il 0.8 v load resistance between eara and earb, r l (see note 4) 600 w load capacitance between eara and earb, c l (see note 4) 113 nf o p erating free air tem p erature t a TCM320AC36c, tcm320ac37c 0 70 c operating free - air temperat u re , t a TCM320AC36i, tcm320ac37i 40 85 c notes: 2. to avoid possible damage to these cmos devices and resulting reliability problems, the power-up sequence detailed in th e system reliability features paragraph should be followed. 3. voltages at analog inputs, outputs, and v cc are with respect to gnd. 4. r l and c l should not be applied simultaneously.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 6 post office box 655303 ? dallas, texas 75265 electrical characteristics over recommended ranges of supply voltage and free-air temperature (unless otherwise noted) supply current, f dclkr or f dclkx = 2.048 mhz, outputs not loaded, v cc = 5 v, t a = 25 c parameter test conditions min max unit operating pdn is high with clk signal present 9.9 power down pdn is low for 500 m s 0.85 i cc supply current from v cc standby both pdn is high with fsx and fsr held low 2 ma standby one pdn is high with either fsx or fsr pulsing with the other held low 6 digital interface parameter test conditions min typ 2 max unit v oh high-level output voltage dout i oh = 3.2 ma, v cc = 5 v 2.4 4.6 v v ol low-level output voltage dout i ol = 3.2 ma, v cc = 5 v 0.2 0.4 v i ih high-level input current, any digital input v i = 2.2 v to v cc 10 m a i il low-level input current, any digital input v i = 0 to 0.8 v 10 m a c i input capacitance 5 pf c o output capacitance 5 pf 2 all typical values are at v cc = 5 v, t a = 25 c. microphone interface parameter test conditions min typ 2 max unit v io input offset voltage at micin v i = 0 to 5 v 5 mv i ib input bias current at micin 200 na b 1 unity-gain bandwidth, open loop at micin 1 mhz c i input capacitance at micin 5 pf a v large-signal voltage amplification at micgs 10 000 v/ v vmid 1 m a i o max maximum output current micbias (source only) 1 ma 2 all typical values are at v cc = 5 v, t a = 25 c. speaker interface parameter test conditions min typ 2 max unit v o(pp) ac output voltage 3 vpp v oo output offset voltage at eara, earb (single-ended) relative to gnd 80 mvpk i i(lkg) input leakage current at eargs v i = 0.5 v to (v cc 0.5) v 200 na i o max maximum output current r l = 600 w 5 ma r o output resistance at eara, earb 1 w gain change earmute low, max level when muted 80 db 2 all typical values are at v cc = 5 v, t a = 25 c.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 7 post office box 655303 ? dallas, texas 75265 transmit gain and dynamic range, companded mode ( m - law or a-law) or linear mode selected, v cc = 5 v, t a = 25 c (unless otherwise noted) (see notes 5 and 6) parameter test conditions min max unit companded mode selected, m -law ('ac36) 0.982 transmit reference-signal level (0 db) (see note 7) companded mode selected, a-law ('ac37) 0.985 vrms linear mode selected ('ac36 and 'ac37) 1.001 companded mode selected, m -law ('ac36) 4 overload-signal level (micin at unity gain) companded mode selected, a-law ('ac37) 4 vpp linear mode selected ('ac36 and 'ac37) 4 absolute gain error 0-db input signal 1 db micin to dout at 3 dbm0 to 36 dbm0 0.5 db gain error with in p ut level relative to gain at 10 dbm0 micin to dout at 37 dbm0 to 40 dbm0 1 db gain error w ith inp u t le v el relati v e to gain at 10 dbm0 micin to dout at 41 dbm0 to 50 dbm0 1.5 db micin to dout at 51 dbm0 to 55 dbm0 2 db gain variation v cc 10%, t a = 0 c to 70 c 0.5 db notes: 5. unless otherwise noted, the analog input is 0 db, 1020-hz sine wave, where 0 db is defined as the zero-reference point of the channel under test. 6. the input amplifier is set for inverting unity gain. 7. the reference-signal level, which is input to the transmit channel, is defined as a value 3 db below the full-scale value of 2 v. transmit filter transfer, companded mode ( m - law or a-law) or linear mode selected, over recommended ranges of supply voltage and free-air temperature, clk = 2.048 mhz, fsx = 8 khz (see note 6) parameter test conditions min max unit f micin = 50 hz 10 0 f micin = 200 hz 1.8 0 gain relative to input signal gain at input amplifier set for unit y g ain , f micin = 300 hz to 3 khz 0.15 g a i n re l a ti ve t o i npu t s i gna l ga i n a t 1.02 khz in ut am lifier set for unity gain, noninverting maximum gain output signal micin i db f micin = 3.3 khz 0.35 0.04 db 1 . 02 khz at micin is 0 db f micin = 3.4 khz 1 0.1 f micin = 4 khz 14 f micin 4.6 khz 32 note 6. the input amplifier is set for inverting unity gain. transmit idle channel noise and distortion, companded mode with m - law or a-law selected, over recommended ranges of supply voltage and operating free-air temperature (see note 8) parameter test conditions min max unit transmit noise, psophometrically weighted micin connected to micgs through a 10-k w resistor 71 db0p transmit noise, c-message weighted micin connected to micgs through a 10-k w resistor 10 dbrnc0 micin to dout at 0 dbm0 to 17 dbm0 36 micin to dout at 18 dbm0 to 23 dbm0 34 transmit signal-to-distortion ratio with sine-wave input micin to dout at 24 dbm0 to 29 dbm0 30 db micin to dout at 30 dbm0 to 35 dbm0 24 micin to dout at 36 dbm0 to 45 dbm0 16 intermodulation distortion, 2-tone ccitt method, ccitt g.712 (7.1), r2 49 db composite power level 13 dbm0 ccitt g.712 (7.2), r3 51 db note 8: transmit noise, linear mode: 200 m vrms is equivalent to 74 db (referenced to device 0-db level).
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 8 post office box 655303 ? dallas, texas 75265 transmit idle channel noise and distortion, linear mode selected, over recommended ranges of supply voltage and operating free-air temperature (see notes 6 and 8) parameter test conditions min max unit transmit noise, c-message weighted micin connected to micgs through a 10-k w resistor 200 m vrms micin to dout at 6 dbm0 50 micin to dout at 12 dbm0 48 transmit signal-to-distortion ratio with sine-wave in p ut micin to dout at 18 dbm0 40 db transmit signal - to - distortion ratio with sine - wave in ut micin to dout at 24 dbm0 35 db micin to dout at 40 dbm0 20 micin to dout at 45 dbm0 18 notes: 6. the input amplifier is set for inverting unity gain. 8. transmit noise, linear mode: 200 m vrms is equivalent to 74 db (referenced to device 0-db level). receive gain and dynamic range, companded mode ( m -law or a-law) or linear mode selected, v cc = 5 v, t a = 25 c (unless otherwise noted) (see notes 9 and 10) parameter test conditions min max unit companded mode selected, m -law ('ac36) 0.736 receive reference-signal level (0 db) (see note 11) companded mode selected, a-law ('ac37) 0.739 vrms linear mode selected ('ac36 and 'ac37) 0.751 companded mode selected, m -law ('ac36) 3 overload-signal level companded mode selected, a-law ('ac37) 3 vpp linear mode selected ('ac36 and 'ac37) 3 absolute gain error 0-db input signal 1 db din to eara and earb at 3 dbm0 to 36 dbm0 0.5 gain error with out p ut level relative to gain at 10 dbm0 din to eara and earb at 37 dbm0 to 40 dbm0 1 db gain error with out ut level relative to gain at 10 dbm0 din to eara and earb at 41 dbm0 to 50 dbm0 1.5 db din to eara and earb at 51 dbm0 to 55 dbm0 2 gain variation v cc 10%, t a = 0 c to 70 c 0.5 db notes: 9. receive output is measured differentially in the maximum gain configuration. to set the output amplifier for maximum ga in, eargs is connected to earb and the output is taken between eara and earb. all output levels are (sin x)/x corrected. 10. unless otherwise noted, the digital input is a word stream generated by passing a 0-db sine wave at 1020 hz through an ideal encoder, where 0 db is defined as the zero reference. 11. this reference-signal level is measured at the speaker output of the receive channel with the gain of the output speaker amp lifier set to unity. receive filter transfer, companded mode ( m -law or a-law) or linear mode selected, over recommended ranges of supply voltage and operating free-air temperature, fsr = 8 khz (see note 9) parameter test conditions min max unit f din = < 200 hz 0.15 f din = 200 hz 0.5 0.15 f din = 300 hz to 3 khz 0.15 gain relative to gain at 1.02 khz din = 0 dbm0 f din = 3.3 khz 0.35 0.03 db f din = 3.4 khz 1 0.18 f din = 4 khz 14 f din = > 4.6 khz 30 note 9. receive output is measured differentially in the maximum gain configuration. to set the output amplifier for maximum gai n, eargs is connected to earb and the output is taken between eara and earb. all output levels are (sin x)/x corrected.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 9 post office box 655303 ? dallas, texas 75265 receive idle channel noise and distortion, companded mode with m - law or a-law selected, over recommended ranges of supply voltage and operating free-air temperature (see note 9) parameter test conditions min max unit receive noise, psophometrically weighted din = 11010101 (a-law) 75 db0p receive noise, c-message weighted din = 1 1111111 ( m -law) 5 dbrnc0 din to eara and earb at 0 dbm0 to 18 dbm0 36 din to eara and earb at 19 dbm0 to 24 dbm0 34 receive signal-to-distortion ratio with sine-wave input din to eara and earb at 25 dbm0 to 30 dbm0 30 db din to eara and earb at 31 dbm0 to 38 dbm0 23 din to eara and earb at 39 dbm0 to 45 dbm0 17 note 9. receive output is measured differentially in the maximum gain configuration. to set the output amplifier for maximum gai n, eargs is connected to earb and the output is taken between eara and earb. all output levels are (sin x)/x corrected. receive idle channel noise and distortion, linear mode selected, over recommended ranges of supply voltage and operating free-air temperature (see notes 9 and 12) parameter test conditions min max unit receive noise, c-message weighted din = 00000000 200 m vrms din to eara and earb at 0 dbm0 to 6 dbm0 50 din to eara and earb at 7 dbm0 to 12 dbm0 48 receive signal to distortion ratio with sine wave in p ut din to eara and earb at 13 dbm0 to 18 dbm0 38 db recei v e signal - to - distortion ratio w ith sine -w a v e inp u t din to eara and earb at 19 dbm0 to 24 dbm0 32 db din to eara and earb at 25 dbm0 to 40 dbm0 18 din to eara and earb at 41 dbm0 to 45 dbm0 15 intermodulation, 2-tone ccitt distortion method, ccitt g.712 (7.1), r2 50 db composite power level 13 dbm0 ccitt g.712 (7.2), r3 54 db notes: 9. receive output is measured differentially in the maximum gain configuration. to set the output amplifier for maximum ga in, eargs is connected to earb and the output is taken between eara and earb. all output levels are (sin x)/x corrected. 12. receive noise, linear mode: 200 m vrms is equivalent to 71 db (referenced to device 0-db level). power supply rejection and crosstalk attenuation over recommended ranges of supply voltage and operating free-air temperature parameter test conditions min typ 2 max unit supply voltage rejection, transmit channel idle channel, supply signal = 100 mvrms, f = 0 to 30 khz (measured at dout) 30 db supply voltage rejection, receive channel idle channel, supply signal = 100 mvrms, eargs connected to earb, f = 0 to 30 khz (measured differentially between eara and earb) 30 db crosstalk attenuation, transmit-to-receive (differential) micin = 0 db, f = 1.02 khz, unity transmit gain, eargs connected to earb, measured differentially between eara and earb 68 db crosstalk attenuation, receive-to-transmit din = 0 dbm0, f = 1.02 khz, unity transmit gain, measured at dout 68 db 2 all typical values are at v cc = 5 v, t a = 25 c.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 10 post office box 655303 ? dallas, texas 75265 timing requirements clock timing requirements over recommended ranges of supply voltage and operating free-air temperature (see figure 1 through figure 4) min nom 2 max unit t t transition time, clk and dclkx /dclkr 10 ns duty cycle, clk 45% 50% 55% duty cycle, dclkx /dclkr 45% 50% 55% 2 all typical values are at v cc = 5 v, t a = 25 c. transmit timing requirements over recommended ranges of supply voltage and operating free-air temperature, fixed-data-rate mode (see figure 2) min max unit t su(fsx) setup time, fsx high before clk 20 468 ns t h(fsx) hold time, fsx high after clk 20 468 ns receive timing requirements over recommended ranges of supply voltage and operating free-air temperature, fixed-data-rate mode (see figure 1) min max unit t su(fsr) setup time, fsr high before clk 20 468 ns t h(fsr) hold time, fsr high after clk 20 468 ns t su(din) setup time, din high or low before clk 20 ns t h(din) hold time, din high or low after clk 20 ns transmit timing requirements over recommended ranges of supply voltage and operating free-air temperature, variable-data-rate mode (see figure 4) min max unit t su(fsx) setup time, fsx high before dclkx 40 t c(dclkx) 40 ns t h(fsx) hold time, fsx high after dclkx 35 t c(dclkx) 35 ns receive timing requirements over recommended ranges of supply voltage and operating free-air temperature, variable-data-rate mode (see figure 3) min max unit t su(fsr) setup time, fsr high before dclkr 40 ns t h(fsr) hold time, fsr high after dclkr 35 t c(dclkr) 35 ns t su(din) setup time, din high or low before dclkr 30 ns t h(din) hold time, din high or low after dclkr 30 ns switching characteristics propagation delay times over recommended ranges of operating conditions, fixed-data-rate mode, c l = 0 to 10 pf (see figure 2) parameter test conditions min max unit t pd1 from clk bit 1 high to dout bit 1 valid 35 ns t pd2 from clk high to dout valid, bits 2 to n 35 ns t pd3 from clk bit n low to dout bit n hi-z 30 ns t pd4 from clk bit 1 high to tsx active (low) r pullup = 1.24 k w 40 ns t pd5 from clk bit n low to tsx inactive (high) r pullup = 1.24 k w 30 ns
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 11 post office box 655303 ? dallas, texas 75265 propagation delay times over recommended ranges of operating conditions, variable-data-rate mode (see figure 4) parameter test conditions min max unit t pd6 fsx high to dout bit 1 valid c l = 0 to 10 pf 30 ns t pd7 dclkx high to dout valid, bits 2 to n c l = 0 to 10 pf 40 ns t pd8 fsx low to dout bit n hi-z 20 ns parameter measurement information all timing parameters are referenced to v ih and v il . bit 1 = msb (most significant bit) and is clocked in first on din or clocked out first on dout. bit n = lsb (least significant bit) and is clocked in last on din or is clocked out last on dout. n = 8 for the companded mode, and n = 16 for the linear mode. n1 n 1 23 4 n1n1 n+1 n n1 n2 4 3 2 1 0 clk fsr din t su(fsr) t h(fsr) see note b see note a t h(din) t su(din) receive time slot 20% 20% 80% 80% see note c n2 notes: a. this window is allowed for fsr high. b. this window is allowed for fsr low. c. transitions are measured at 50%. figure 1. fixed-data rate mode, receive side timing diagram n1 n2 3 2 1 n+1 n n1 n2 4 3 2 1 0 n t h(fsx) clk fsx dout tsx see note b t pd2 t pd3 t pd1 t pd4 t pd5 transmit time slot t su(fsx) 20% 80% 20% 80% see note c 20% 80% see note a notes: a. this window is allowed for fsx high. b. this window is allowed for fsx low (t h(fsx) max determined by data collision considerations). c. transitions are measured at 50%. figure 2. fixed-data rate mode, transmit side timing diagram
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 12 post office box 655303 ? dallas, texas 75265 parameter measurement information n1 n 1 2 3 4 n1 n 1 n+1 n n1 n2 4 3 2 1 0 dclkr fsr din receive time slot t su(fsr) see note a t h(fsr) see note b t h(din) t su(din) 80% 20% 80% 80% n2 see note c 20% notes: a. this window is allowed for fsr high (t su(fsr) max determined by data collision considerations). b. this window is allowed for fsr low. c. transitions are measured at 50%. figure 3. variable-data rate mode, receive side timing diagram 4 n n1 n2 3 2 1 n+1 n n1 n2 4 3 2 1 0 dclkx fsx dout t su(fsx) transmit time slot t h(fsx) see note b t pd8 t pd7 t pd6 see note a 80% 20% 80% 20% 80% see note c notes: a. this window is allowed for fsx high. b. this window is allowed for fsx low without data repetition. c. transitions are measured at 50%. figure 4. variable-data rate mode, transmit side timing diagram
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 13 post office box 655303 ? dallas, texas 75265 principles of operation general system reliability features the device should be powered up and initialized as follows: 1. apply gnd. 2. apply v cc . 3. connect all clocks. 4. apply ttl high to pdn . 5. apply synchronizing pulses to fsx and/or fsr. even though the vbap is heavily protected against latch-up, it is still possible to cause it to latch up under certain improper power conditions. to help ensure that latch-up does not occur, a reverse-biased schottky diode (with a forward voltage drop of less than or equal to 0.4 v e 1n5711 or equivalent) should be connected between v cc (power supply) and gnd. on the transmit channel, digital outputs dout and tsx are held in the high-impedance state for approximately four frames (500 m s) after power up or application of v cc . after this delay, dout, tsx , and signaling are functional and occur in the correct time slot. the analog circuits on the transmit side require approximately 60 ms to reach their equilibrium value due to the autozero circuit settling time. to further enhance system integrity, dout and tsx are placed in the high-impedance state after an interruption of clk. power-down and standby operations to minimize power consumption, a power-down mode and three standby modes are provided. for power down, an external low signal is applied to pdn . in the absence of a signal, pdn is internally pulled up to a high logic level and the device remains active. in the power-down mode, the average power consumption is reduced to 3 mw. three standby modes give the user the option of placing the entire device on standby, placing only the transmit channel on standby, or placing only the receive channel on standby. to place the entire device on standby, both fsx and fsr are held low. for transmit-only operation (receive channel on standby), fsx is pulsing and fsr is held low. for receive-only operation (transmit section on standby), fsr is pulsing and fsx is held low. when the entire device is in standby mode, power consumption is reduced to 5 mw. see table 1 for power-down and standby procedures.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 14 post office box 655303 ? dallas, texas 75265 principles of operation table 1. power-down and standby procedures device status procedure typical power consumption digital output status power on pdn = high, fsx = pulses, fsr = pulses 40 mw digital outputs active but not loaded power down pdn = low, fsx, fsr = x 2 3 mw tsx and dout in the high-impedance state entire device on standby mode fsx = low, fsr = low, pdn = high 5 mw tsx and dout in the high-impedance state only transmit channel in standby mode fsx = low, fsr = pulses, pdn = high 20 mw tsx and dout in the high-impedance state within five frames only receive channel in standby mode fsr = low, fsx = pulses, pdn = high 20 mw digital outputs active but not loaded 2 x = don't care fixed-data-rate timing fixed-data-rate timing, selected by connecting dclkr to v cc , uses the master clock (clk), frame synchronization clocks (fsx and fsr), and the tsx output. fsx and fsr are inputs that set the sampling frequency. data is transmitted on dout on the positive transitions of clk following the rising edge of fsx. data is received on din on the falling edges of clk following fsr. a d/a conversion is performed on the received digital word, and the resulting analog sample is held on an internal sample-and-hold capacitor until transferred to the receive filter. the data word is eight bits long in the companded mode and 16 bits long in the linear mode. variable-data-rate timing variable-data-rate timing is selected by connecting dclkr to the receive data clock. in this mode, the master clock (clk) controls the switched-capacitor filters, while data transfer into din and out of dout is controlled by dclkr and dclkx respectively. this allows the data to be transferred in and out of the device at any rate up to the frequency of the master clock. dclkr and dclkx must be synchronous with clk. while the fsx input is high, data is transmitted from dout on consecutive positive transitions of dclkx. similarly, while the fsr input is high, the data word is received at din on consecutive negative transitions of dclkr. the transmitted data word at dout is repeated in all remaining time slots in the frame as long as dclkx is pulsed and fsx is held high. this feature, which allows the data word to be transmitted more than once per frame, is available only with variable-data-rate timing. asynchronous operations to avoid crosstalk problems associated with special interrupt circuits, the design includes separate converters, filters, and voltage references on the transmit and receive sides. this allows completely independent operation of the two channels. in either timing mode, the master clock, data clock, and time-slot strobe must be synchronized at the beginning of each frame. precision voltage references a precision band-gap reference voltage is generated internally and is used to supply all the references required for operation of both the transmit and receive channels. the gain in each channel is trimmed during the manufacturing process. this ensures very accurate, stable gain performance over variations in supply voltage and device temperature.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 15 post office box 655303 ? dallas, texas 75265 principles of operation conversion laws the TCM320AC36 provides m -law companding operation that approximates the ccitt g.711 recommendation. the tcm320ac37 provides a-law companding operation that approximates the ccitt g.711 recommendation. the linear mode of operation uses a 13-bit two's-complement format and is the same for both the TCM320AC36 and the tcm320ac37. transmit operation microphone input the microphone input amplifier is designed specifically to interface to electret-type microphone elements, as shown in figure 5. the vmid buffer circuit provides a voltage (micbias) equal to 1/2 v cc as a reference for the microphone amplifier and a bias voltage to the electret microphone. the microphone amplifier output (micgs) is used in conjunction with a feedback network and applied to the amplifier inverting input (micin) to set the amplifier gain. in the companded mode, when the micin signal level decreases to a level near the noise floor, the vbap mutes the signal and outputs zero bits while continuing to monitor the signal level. when the input level once again exceeds the noise threshold, the mute is released and normal operation resumes. input hysteresis is provided to ensure noiseless transitions into and out of the muted condition. vmid appears at a terminal to provide a place to filter the vmid voltage. TCM320AC36/37 vbap 2 k w 17 vmid 18 micin 19 micgs 20 micbias to transmit filters microphone amplifier vmid buffer 10 k w + vmid reference for amplifiers 1 m f vmid generator electret microphone + 3.3 m f micmute 6 10 k w + v dd 470 pf + note a: terminal numbers shown are for the dw and n packages. figure 5. typical microphone interface microphone mute function the micmute input causes the digital circuitry to transmit all zero code on dout. transmit filter a low-pass antialiasing section is included on the device and achieves a 35-db attenuation at the sampling frequency. no external components are required to provide the necessary antialiasing function for the switched-capacitor section of the transmit filter.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 16 post office box 655303 ? dallas, texas 75265 principles of operation encoding the encoder internally samples the output of the transmit filter and holds each sample on an internal sample-and-hold capacitor. the encoder performs an a/d conversion on a switched-capacitor array. digital data representing the sample is transmitted on the first 8 or 16 data clock cycles of the next frame. the autozero circuit corrects for dc offset on the input signal to the encoder using the sign-bit averaging technique. the sign bit from the encoder output is long-term averaged and subtracted from the input to the encoder. data word structure the data word is eight bits long in the companded mode and all eight bits represent one audio data sample. the sign bit is the first bit transmitted. the data word is 16 bits long in the linear mode. the first 13 bits comprise the audio data sample, and the last three bits form the volume control word in the receive direction (din) and are zero pad bits in the transmit direction (dout). the sign bit is transmitted first. receive operation decoding in the companded mode, the serial data word is received at din on the first eight clock cycles in fixed-data rate and on the last eight clock cycles in variable-data rate. in the linear mode, the serial data word is received at din on the first 13 clock cycles. d/a conversion is performed, and the corresponding analog sample is held on an internal sample-and-hold capacitor. this sample is transferred to the receive filter. receive filter the receive section of the filter provides pass-band flatness and stop-band rejection that approximates both the at&t d3/d4 specification and ccitt recommendation g.712 when operated at the recommended frequencies. the filter contains the required compensation for the (sin x)/x response of such decoders. receive buffer the receive buffer contains the volume control. earphone amplifier the earphone audio-output amplifier has a balanced output, as shown in figure 6, to allow maximum flexibility in output configuration. the output amplifier is designed to directly drive a piezo earphone in the differential configuration without any additional external components. the output can also be used to drive a single-ended load with the output signal voltage centered around v cc /2. the receive-channel output level can be adjusted between specified limits by connecting an external resistor network to eargs.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 17 post office box 655303 ? dallas, texas 75265 principles of operation _ + _ + in vmid 4 2 3 eargs eara earb + note a: terminal numbers shown are for the dw and n packages. figure 6. earphone audio-output amplifier configuration and internal gain-setting network receive data format in the companded mode, eight bits of data are received. the sign bit is the first bit received (see table 2). in the linear mode, 16 bits of data are received. the first 13 bits are the d/a code, and the remaining three bits form the volume control word (see table 2). the volume control function is actually an attenuation control in which the first bit received is the most significant. the maximum volume occurs when all three volume control bits are zero. eight levels of attenuation are selectable in 3-db steps, giving a maximum attenuation of 21 db when all bits are 1s. the volume control bits are not latched into the vbap and must be present in each received data word.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 18 post office box 655303 ? dallas, texas 75265 principles of operation table 2. receive-data bit definitions bit no. companded mode linear mode 0 cd7 ld12 1 cd6 ld11 2 cd5 ld10 3 cd4 ld9 4 cd3 ld8 5 cd2 ld7 6 cd1 ld6 7 cd0 ld5 8 ld4 9 ld3 a ld2 b ld1 c ld0 d v2 e v1 f v0 volume control and other control bits always follow the pcm data in time: companded mode: linear data volume control linear mode: companded data v2 ld0 ld1 ld2 ld3 ld4 ld12 ld11 ld10 ld9 ld8 ld7 ld6 ld5 cd0 cd1 cd2 cd3 cd4 cd5 cd6 cd7 v1 v0 msb (sign bit) lsb msb (sign bit) lsb time where: cd7 cd0 = data word when in companded mode ld12 ld0 = data word when in linear mode v2, v1, v0 = volume (attenuation control) 000 = maximum volume, 3 dbm0 111 = minimum volume, 18 dbm0
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 19 post office box 655303 ? dallas, texas 75265 application information output gain set design considerations (see figure 7) eara and earb are low-impedance complementary outputs. the voltages at the nodes are: v o+ at eara v o at earb v od = v o+ v o (total differential response) r1 and r2 are a gain-setting resistor network with the center tap connected to eargs. a value greater than 10 k w and less than 100 k w for r1 + r2 is recommended because of the following: the parallel combination r1 + r2 and r l sets the total loading. the total capacitance at eargs and the parallel combination of r1 and r2 define a time constant that has to be minimized to avoid inaccuracies. v a represents the maximum available digital mw output response (v a = 0.751 vrms). v od = a v a where a = 1 + (r1/r2) 4 + (r1/r2) digital mw sequence iaw ccitt g.712 v o v o+ r l 3 4 2 r2 r1 v o din earb eargs eara note a: terminal numbers shown are for the dw and n packages. figure 7. gain-setting configuration higher clock frequencies and sample rates the vbap is designed to work with sample rates up to 16 khz where the frequency of the frame sync determines the sampling frequency. however, there is a fundamental requirement to maintain the ratio of the master clock frequency, f clk , to the frame sync frequency, f fsr /f fsx . this ratio for the vbap is 2.048 mhz/8 khz, or 256 master clocks per frame sync. for example, to operate the vbap at a sampling rate of f fsr and f fsx equal to 16 khz, f clk must be 256 times 16 khz, or 4.096 mhz. if the vbap is operated above an 8-khz sample rate, however, it is expected that the performance becomes somewhat degraded. exact parametric specifications for rates up to 16-khz sample rate are not specified at this time.
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 20 post office box 655303 ? dallas, texas 75265 mechanical data dw (r-pdso-g**) plastic small-outline package 16 pin shown 4040000 / b 03/95 seating plane 0.400 (10,15) 0.419 (10,65) 0.104 (2,65) max 1 0.012 (0,30) 0.004 (0,10) a 8 16 0.020 (0,51) 0.014 (0,35) 0.293 (7,45) 0.299 (7,59) 9 0.010 (0,25) 0.050 (1,27) 0.016 (0,40) (15,24) (15,49) pins ** 0.010 (0,25) nom a max dim a min gage plane 20 0.500 (12,70) (12,95) 0.510 (10,16) (10,41) 0.400 0.410 16 0.600 24 0.610 (17,78) 28 0.700 (18,03) 0.710 0.004 (0,10) m 0.010 (0,25) 0.050 (1,27) 0 8 notes: a. all linear dimensions are in inches (millimeters). b. this drawing is subject to change without notice. c. body dimensions do not include mold flash or protrusion not to exceed 0.006 (0,15). d. falls within jedec ms-013
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 21 post office box 655303 ? dallas, texas 75265 mechanical data n (r-pdip-t**) plastic dual-in-line package 20 0.975 (24,77) 0.940 (23,88) 18 0.920 0.850 14 0.775 0.745 (19,69) (18,92) 16 0.775 (19,69) (18,92) 0.745 a min dim a max pins ** 0.310 (7,87) 0.290 (7,37) (23.37) (21.59) seating plane 0.010 (0,25) nom 14/18 pin only 4040049/c 08/95 9 8 0.070 (1,78) max a 0.035 (0,89) max 0.020 (0,51) min 16 1 0.015 (0,38) 0.021 (0,53) 0.200 (5,08) max 0.125 (3,18) min 0.240 (6,10) 0.260 (6,60) m 0.010 (0,25) 0.100 (2,54) 0 15 16 pin shown notes: a. all linear dimensions are in inches (millimeters). b. this drawing is subject to change without notice. c. falls within jedec ms-001 (20 pin package is shorter then ms-001.)
TCM320AC36, tcm320ac37 voice-band audio processors (vbap ? ) slws003c may 1992 revised april 1998 22 post office box 655303 ? dallas, texas 75265 mechanical data pt (s-pqfp-g48) plastic quad flatpack 4040052 / b 03/95 0,13 nom 0,17 0,27 25 24 sq 12 13 36 37 6,80 7,20 1 48 5,50 typ 0,25 0,45 0,75 0,05 min sq 9,20 8,80 1,35 1,45 1,60 max gage plane seating plane 0,10 0 7 0,50 m 0,08 notes: a. all linear dimensions are in millimeters. b. this drawing is subject to change without notice. c. falls within jedec mo-136 d. this may also be a thermally-enhanced plastic package with leads connected to the die pads.
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