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| audio processor for advanced tv with sound if demodulator and stereo decoder adav4622 rev. b information furnished by analog devices is believed to be accurate and reliable. however, no responsibility is assumed by analog devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. specifications subject to change without notice. no license is granted by implication or otherwise under any patent or patent rights of analog devices. trademarks and registered trademarks are the property of their respective owners. one technology way, p.o. box 9106, norwood, ma 02062-9106, u.s.a. tel: 781.329.4700 www.analog.com fax: 781.461.3113 ?2008C2009 analog devices, inc. all rights reserved. features sound if (sif) processor sif demodulator and broadcast stereo decoder nicam (bg, dk, i, l), a2 (bg, dk, m), btsc (m, n), eiaj (m) automatic sound if standard detection fully programmable 28-bit audi o processor for enhanced atv sounddefault tv audio flow loaded on reset implements analog devices and third-party branded audio algorithms adjustable digital delay line for audio/video synchronization for up to 200 ms stereo delay high performance 24-bit adc and dac 94 db dnr performance on dac channels 95 db dnr performance on adc channels dual headphone outputs with integrated amplifiers high performance pulse-width modulation (pwm) digital outputs multichannel digital baseband i/o 4 stereo synchronous digital i 2 s input channels one 6-channel sample rate converter (src) and one stereo src supporting input sample rates from 5 khz to 50 khz one stereo synchronous digital i 2 s output s/pdif output with s/pdif input mux capability fast i 2 c control operates from 3.3 v (analog), 1.8 v (digital core), and 3.3 v (digital interface) available in 80-lead lqfp applications general-purpose consumer audio postprocessing home audio dvd recorders home theater in a box (htib) systems and dvd receivers audio processing subsystems for dtv-ready tvs analog broadcast capability for idtvs product overview the adav4622 is an enhanced audio processor targeting advanced tv applications with full support for digital and analog baseband audio as well as multistandard broadcast sif demodulation and decoding. the audio processor, by default, loads a dedicated tv audio flow that incorporates full matrix switching (any input to any output), automatic volume control that compensates for volume changes during advertisements or when switching channels, dynamic bass, a multiband equalizer, and up to 200 ms of stereo delay memory for audio-video synchronization. alternatively, analog devices, inc., offers an award-winning graphical programming tool (sigmastudio?) that allows custom flows to be quickly developed and evaluated. this allows the creation of customer-specific audio flows, including use of the analog devices library of third-party algorithms. the analog i/o integrates analog devices proprietary continuous-time, multibit - architecture to bring a higher level of performance to atv systems, required by third-party algorithm providers to meet system branding certification. the analog input is provided by 95 db dynamic range (dnr) adcs, and analog output is provided by 94 db dnr dacs. the main speaker outputs can be supplied as a digitally modulated pwm stream to support digital amplifiers. the adav4622 includes multichannel digital inputs and outputs. in addition, digital input channels can be routed through integrated sample rate converters (src), which are capable of supporting any arbitrary sample rate from 5 khz to 50 khz.
adav4622 rev. b | page 2 of 28 table of contents features .............................................................................................. 1 ? applications ....................................................................................... 1 ? product overview ............................................................................. 1 ? revision history ............................................................................... 2 ? functional block diagram .............................................................. 3 ? specifications ..................................................................................... 4 ? performance parameters ............................................................. 4 ? timing specifications .................................................................. 9 ? timing diagrams ........................................................................ 10 ? absolute maximum ratings .......................................................... 12 ? thermal resistance .................................................................... 12 ? thermal conditions ................................................................... 12 ? esd caution ................................................................................ 12 ? pin configuration and function descriptions ........................... 13 ? typical performance characteristics ........................................... 16 ? terminology .................................................................................... 18 ? pin functions .................................................................................. 19 ? sdin0, sdin1, sdin2, and sdin3/spdif_in0 ................... 19 ? lrclk0, bclk0, lrclk1, bclk1, lrclk2, and bclk2 19 ? sdo0/ad0 .................................................................................. 19 ? spdif_out (sdo1) ................................................................. 19 ? mclki/xin ................................................................................ 19 ? xout ........................................................................................... 19 ? mclk_out ............................................................................... 19 ? sda ............................................................................................... 19 ? scl ............................................................................................... 20 ? mute .......................................................................................... 20 ? reset .......................................................................................... 20 ? auxin1l, auxin2l, auxin1r, and auxin2r ................ 20 ? auxout1l, auxout2l, auxout3l, auxout4l, auxout1r, auxout2r, auxout3r, and auxout4r ....................................................................................................... 20 ? hpout1l, hpout2l, hpout1r, and hpout2r .......... 20 ? pll_lf ......................................................................................... 20 ? vref ............................................................................................ 20 ? filta and filtd ....................................................................... 20 ? pwm1a, pwm1b, pwm2a, pwm2b, pwm3a, pwm3b, pwm4a, and pwm4b .............................................................. 20 ? pwm_ready ........................................................................... 20 ? avdd .......................................................................................... 20 ? dvdd .......................................................................................... 20 ? odvdd ....................................................................................... 20 ? dgnd .......................................................................................... 20 ? agnd .......................................................................................... 20 ? odgnd ...................................................................................... 20 ? sif_refp, sif_refcm, and sif_refn ................................ 20 ? sif_in1 and sif_in2 ................................................................ 20 ? sif_pga_ref ............................................................................ 20 ? iset .............................................................................................. 20 ? functional descriptions ................................................................ 21 ? sif processor ............................................................................... 21 ? master clock oscillator ............................................................. 21 ? i 2 c interface ................................................................................ 22 ? adc inputs ................................................................................. 22 ? i 2 s digital audio inputs ............................................................ 22 ? dac voltage outputs ................................................................ 23 ? pwm outputs ............................................................................ 24 ? headphone outputs ................................................................... 24 ? i 2 s digital audio outputs ......................................................... 24 ? s/pdif input/output ................................................................. 25 ? hardware mute control ............................................................ 25 ? audio processor ......................................................................... 25 ? graphical programming environment ................................... 25 ? application layer ....................................................................... 25 ? loading a custom audio processing flow ............................. 26 ? outline dimensions ....................................................................... 28 ? ordering guide .......................................................................... 28 ? revision history 7/09rev. a to rev. b added advantiv logo ...................................................................... 1 change to pwm outputs section ................................................ 24 change to hardware mute control, graphical programming environment, and application layer sections ........................... 25 changes to ordering guide .......................................................... 28 11/08revision a: initial version adav4622 rev. b | page 3 of 28 functional block diagram audio processor adav4622 a-v synchronous delay memory i 2 c interface sif processor ad0 synchronous multichannel digital inputs 6-channel src asynchronous digital input 2-channel src asynchronous digital input system clocks pll spdif_in0 spdif_in1 spdif_in2 spdif_in3 spdif_in4 spdif_in5 spdif_in6 spdif_out/sdo1 s/pdif i/o pwm digital output pwm1a pwm1b pwm2a pwm2b pwm3a pwm3b pwm4a pwm4b pwm_ready bclk1 lrclk1 sdo0/ad0 hpout2l hpout2r auxout2l auxout2r dac hpout1l auxout4r auxout4l hpout1r dac auxout1l auxout1r dac auxout3l auxout3r dac scl sda bclk2 lrclk2 bclk0 lrclk0 sdin0 sdin1 sdin2 sdin3 xout mclki/xin mclk_out sif_in1 sif_in2 auxin2l auxin2r adc auxin1l auxin1r adc digital outputs bclk1 lrclk1 mute 07068-001 figure 1. adav4622 with pwm-based speaker outputs adav4622 rev. b | page 4 of 28 specifications avdd = 3.3 v, dvdd = 1.8 v, odvdd = 3.3 v, operating temperature = ?40c to +85c, master clock = 24.576 mhz, measurement bandwidth = 20 hz to 20 khz, adc input signal = dac output signal = 1 khz, unless otherwise noted. performance parameters table 1. parameter min typ max unit test conditions/comments sif adc input section analog input frequency range 10 mhz recommended analog input level 90 18 db dbu fm, agc in pga priority mode maximum analog input range 1.6 v p-p default setting input impedance 12 k pga gain = 0 db 6 k pga gain = 10 db 2.3 k pga gain = 20 db dc bias level 1.9 v sif input isolation 60 db sif_in1 to sif_ in2 fm limiting sensitivity 32 dbu a2 (dk), mono, deviation mode = 100%, f fm = 400 hz, f = 50 khz, bw = 20 hz to 15 khz, rms detector 31 dbu a2 (i), mono, deviation mode = 100%, f fm = 400 hz, f = 50 khz, bw = 20 hz to 15 khz, rms detector 31 dbu a2 (bg), mono, deviation mode = 100%, f fm = 400 hz, f = 50 khz, bw = 20 hz to 15 khz, rms detector 34 dbu btsc (m, n), mono, deviation mode = 100%, f fm = 400 hz, f = 25 khz, bw = 20 hz to 15 khz, rms detector 28.5 dbu a2 (m), mono, deviation mode = 100%, f fm = 400 hz, f = 25 khz, bw = 20 hz to 15 khz, rms detector 30 dbu eiaj (m), mono, deviation mode = 100%, f fm = 400 hz, f = 25 khz, bw = 20 hz to 15 khz, rms detector fm output level at 25% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif = 100 mv, f fm = 400 hz, f = 12.5 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 6.25 khz, rms detector 56.3 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 6.25 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 6.25 khz, rms detector fm output level at 50% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif = 100 mv, f fm = 400 hz, f = 25 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 12.5 khz, rms detector 56.3 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 12.5 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 12.5 khz, rms detector fm output level at 100% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif = 100 mv, f fm = 400 hz, f = 50 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 25 khz, rms detector 56.3 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 25 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 25 khz, rms detector fm output level at 200% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif =100 mv, f fm = 400 hz, f = 100 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 50 khz, rms detector 56.3 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 50 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 50 khz, rms detector adav4622 rev. b | page 5 of 28 parameter min typ max unit test conditions/comments fm output level at 400% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif = 100 mv, f fm = 400 hz, f = 200 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 100 khz, rms detector 56.4 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 100 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 100 khz, rms detector fm output level at 800% deviation mode 53.7 % fs a2 (dk, i, bg), mono, v sif = 100 mv, f fm = 400 hz, f = 400 khz, rms detector 53.6 % fs btsc (m, n), mono, v sif = 100 mv, f fm = 400 hz, f = 200 khz, rms detector 56.3 % fs a2 (m), mono, v sif = 100 mv, f fm = 400 hz, f = 200 khz, rms detector 56.7 % fs eiaj (m), mono, v sif = 100 mv, f fm = 400 hz, f = 200 khz, rms detector am rejection ratio 69.5 db a2 (dk), mono, deviation mode = 100%, v sif = 100 mv, f fm = 400 hz, f = 27 khz, f am = 400 hz, mod am = 30%, bw = 20 hz to 15 khz, rms detector 70 db a2 (i), mono, deviation mode = 100%, v sif = 100 mv, f fm = 400 hz, f = 27 khz, f am = 400 hz, mod am = 30%, bw = 20 hz to 15 khz, rms detector 70 db a2 (bg), mono, deviation mode = 100%, v sif = 100 mv, f fm = 400 hz, f = 27 khz, f am = 400 hz, mod am = 30%, bw = 20 hz to 15 khz, rms detector 70.5 db mono (m), deviation mode = 100%, v sif = 100 mv, f fm = 400 hz, f = 13.5 khz, f am = 400 hz, mod am = 30%, bw = 20 hz to 15 khz, rms detector am sensitivity 40 dbu mono (l), f am = 400 hz, mod = 30%, bw = 20 hz to 15 khz, rms detector, (s + n)/n = 10 db btsc (m) performance measured at analog audio output, video = 75% color bar, f sc = 4.5 mhz, f fm = 1 khz, f = 25 khz (100%), deemphasis = 75 s, measuring bw = 20 hz to 15 khz with dbx nr dynamic range stereo channel 62 db stereo l or r (l = ?r), 100%, 1 khz sap channel 68 db sap ch annel with mono 100%, 1 khz total harmonic distortion + noise stereo channel ?46 db stereo l or r (l = ?r), 100%, 1 khz sap channel ?40 db sap 100%, 1 khz frequency response f fm = 20 hz to 12 khz stereo channel +0.1/?0.7 db stereo l or r, 50%, (l = ?r) sap channel +2.5/?2.5 db sap 50%, mono 100%, 1 khz crosstalk stereo-to-sap channel ?74 db l or r 50%, 1 khz sap-to-stereo channel ?71 db sap 50%, 1 khz stereo separation dbx 30 db l off, r 50%, 1 khz eiaj (m) performance measured at analog audio output, video = 75% color bar, f sc = 4.5 mhz, f fm = 1 khz, f = 25 khz (100%), deemphasis = 75 s, measuring bw = 20 hz to 15 khz dynamic range stereo channel 58 db stereo l or r, 100%, 1 khz dual channel 56 db dual ch annel with mono 100%, 1 khz total harmonic distortion + noise stereo channel ?56 db stereo l or r, 100%, 1 khz dual channel ?47 db dual 50%, 1 khz frequency response f fm = 20 hz to 10 khz stereo channel +0.03/?0.5 3 db stereo l or r, 100% dual channel +0.17/?1.4 db dual 100%, mono 100%, 1 khz crosstalk main-to-dual channel ?75 db main 100%, 1 khz dual-to-main channel ?83 db dual 100%, 1 khz stereo separation 39 db stereo l or r, 100%, 1 khz adav4622 rev. b | page 6 of 28 parameter min typ max unit test conditions/comments a2 (m) performance measured at analog audio output, video = 75% color bar, f sc1 = 4.5 mhz, f sc2 = 4.724 mhz, f fm = 1 khz, f = 25 khz (100%), deemphasis = 75 s, measuring bw = 20 hz to 15 khz dynamic range 60 db mono 100%, 1 khz total harmonic distortion + noise ?64 db mono 100%, 1 khz frequency response +0.4/?0.05 db mono 100%, f fm = 25 hz to 15 khz crosstalk (dual) ?88 db mono or dual off, 100%, 1 khz channel separation (stereo) 66 db stereo l off, r 50%, 1 khz a2 (dk1/dk2/dk3) performance measured at analog audio output, video = 75% color bar, f sc1 = 6.5 mhz, f sc2 = 6.742 mhz, (dk2 worst case), f fm = 1 khz, f = 50 khz ( 100%), deemphasis = 50 s, measuring bw = 20 hz to 15 khz dynamic range 74 db mono 100%, 1 khz total harmonic distortion + noise ?66 db mono 100%, 1 khz frequency response +0.1/?0.3 db mono 100%, f fm = 20 hz to 15 khz crosstalk (dual) ?88 db mono or dual off, 100%, 1 khz channel separation (stereo) 77 db stereo l off, r 50%, 1 khz a2 (bg) performance measured at an alog audio output, video = 75% color bar, f sc1 = 5.5 mhz, f sc2 = 5.742 mhz, f fm = 1 khz, f = 50 khz (100%), deemphasis = 50 s, measuring bw = 20 hz to 15 khz dynamic range 74 db mono 100%, 1 khz total harmonic distortion + noise ?61 db mono 100%, 1 khz frequency response +0.1/?0.3 db mono 100%, f fm = 25 hz to 15 khz crosstalk (dual) ?89 db mono or dual off, 100%, 1 khz channel separation (stereo) 70 db stereo l off, r 50%, 1 khz nicam (i) performance measured at analog audio output, video = 75% color bar, 1 khz, unweighted, deemphasis = j17, measuring bw = 20 hz to 15 khz dynamic range 72 db stereo l or r, 0 db, 1 khz total harmonic distortion + noise ?63 db stereo l or r, 0 db, 1 khz frequency response ?1.3/+0. 07 db stereo l or r, 0 db crosstalk ?80 db mono or dual, 0 db, 1 khz stereo separation 73 db l or r, 0 db, 1 khz bit error rate 0 fm and nicam nominal conditions nicam (bg, dk, l) performance measured at analog audio output, video = 75% color bar, 1 khz, unweighted, deemphasis = j17, measuring bw = 20 hz to 15 khz dynamic range 72 db stereo l or r, 0 db, 1 khz total harmonic distortion + noise ?63 db stereo l or r, 0 db, 1 khz frequency response ?1.3/+0. 07 db stereo l or r, 0 db crosstalk ?80 db mono or dual, 0 db, 1 khz stereo separation 74 db l or r, 0 db, 1 khz bit error rate 0 fm and nicam nominal conditions am performance measured at analog audio output, 1 khz, am carrier 6.5 mhz measuring bw = 20 hz to 15 khz dynamic range rms/flat 55 db am = 54% modulation qp/ccir 35 db ccir filter, am = 54% modulation total harmonic distortion + noise ?49 db am = 54% modulation frequency response +0.03/?1.2 db am = 54% modulation reference section absolute voltage v ref 1.53 v v ref temperature coefficient 100 ppm/c adav4622 rev. b | page 7 of 28 parameter min typ max unit test conditions/comments adc section number of channels 4 two stereo channels full-scale input level 100 a rms resolution 24 bits dynamic range (stereo channel) a-weighted 95 db ?60 dbfs with respect to full-scale analog input total harmonic distortion + noise (stereo channel) ?90 db ?3 dbfs with respect to full-scale analog input gain mismatch 0.2 db left- and right-channel gain mismatch crosstalk (left to right, right to left) ?110 db gain error ?1 db input signal is 100 a rms current setting resistor (r iset ) 20 k external resistor to set current input range of adc for nominal 2.0 v rms input signal power supply rejection ?87 db 1 khz, 300 mv p-p signal at avdd adc digital decimator filter characteristics at 48 khz, guaranteed by design pass band 22.5 khz pass-band ripple 0.0002 db stop band 26.5 khz stop-band attenuation 100 db group delay 1040 s pwm section frequency 384 khz guaranteed by design modulation index 0.976 guaranteed by design dynamic range a-weighted 98 db ?60 db with respect to full-scale code input total harmonic distortion + noise ?78 db ?3 db with respect to full-scale code input dac section number of auxiliary output channels 8 four stereo channels resolution 24 bits full-scale analog output 1 v rms dynamic range a-weighted 94 db ?60 dbfs with respect to full-scale code input total harmonic distortion + noise ?86 db ?3 dbfs with respect to full-scale code input crosstalk (left to right, right to left) ?102 db interchannel gain mismatch 0.1 db left- and right-channel gain mismatch gain error 0.525 db 1 v rms output dc bias 1.53 v power supply rejection ?90 db 1 khz, 300 mv p-p signal at avdd output impedance 235 dac digital interpolation filter characteristics at 48 khz, guaranteed by design pass band 21.769 khz pass-band ripple 0.01 db transition band 23.95 khz stop band 26.122 khz stop-band attenuation 75 db group delay 580 s headphone amplifier measured at headphone output with 32 load number of channels 4 two stereo channels full-scale output power 31 mw rms 1 v rms output dynamic range a-weighted 93 db ?60 dbfs with respect to full-scale code input total harmonic distortion + noise ?83 db ?3 dbfs with respect to full-scale code input interchannel gain mismatch 0.1 db dc bias 1.53 v power supply rejection ?85 db 1 khz, 300 mv p-p signal at avdd adav4622 rev. b | page 8 of 2 8 parameter min typ max unit test conditions/comments src number of channels 8 two channels (src1), six channels (src2) dynamic range a-weighted 115 db ?60 dbfs input (worst-case input f s = 50 khz) total harmonic distortion + noise ?113 db ?3 dbfs input (worst-case input f s = 50 khz) sample rate 5 50 khz src digital interpolation filter characteristics at 48 khz, guaranteed by design pass band 21.678 khz pass-band ripple 0.005 db stop band 26.232 khz stop-band attenuation 110 db group delay 876 s digital input/output input voltage high (v ih ) 2.0 odvdd v input voltage low (v il ) 0.8 v input leakage i ih (sdin0, sdin1, sdi n2, sdin3, lrclk0, lrclk1, lrclk2, bclk0, bclk1, bclk2, spdif_out, spdif_in) 40 a v ih = odvdd, equivalent to a 90 k pull-up resistor i ih ( reset ) 13.5 a v ih = odvdd, equivalent to a 266 k pull-up resistor i il (sdo0, scl, sda) ?40 a v il = 0 v, equivalent to a 90 k pull-down resistor output voltage high (v oh ) 2.4 v i oh = 0.4 ma output voltage low (v ol ) 0.4 v i ol = ?2 ma output voltage high (v oh ) (mclk_out) 1.4 v i oh = 0.4 ma output voltage low (v ol ) (mclk_out) 0.4 v i ol = ?3.2 ma input capacitance 10 pf supplies analog supplies (avdd) 3.0 3.3 3.6 v digital supplies (dvdd) 1.65 1.8 2.0 v interface supply (odvdd) 3.0 3.3 3.6 v supply currents mclk = 24 mhz, adcs and dacs active, headphone outputs active and driving a 16 load analog current 260 ma digital current 350 ma interface current 2 ma power dissipation 1.495 w standby currents adc, dac, and headphone outputs floating, reset low, mclk = 24 mhz analog current 10 ma digital current 4 ma interface current 1.6 ma temperature range operating temperature ?40 +85 c storage temperature ?65 +150 c adav4622 rev. b | page 9 of 28 timing specifications table 2. parameter description min max unit comments master clock and reset f mclki mclki frequency 3.072 24.576 mhz t mch mclki high 10 ns t mcl mclki low 10 ns t reset reset low 200 ns master clock output t jit period jitter 800 ps t ch mclk_out high 45 55 % t cl mclk_out low 45 55 % i 2 c port f scl scl clock frequency 400 khz t sclh scl high 600 ns t scll scl low 1.3 s start condition t scs setup time 600 ns relevant for repeated start condition t sch hold time 600 ns after this period, the first clock is generated t ds data setup time 100 ns t scr scl rise time 300 ns t scf scl fall time 300 ns t sdr sda rise time 300 ns t sdf sda fall time 300 ns stop condition t scs setup time 0 ns serial ports slave mode t sbh bclk high 40 ns t sbl bclk low 40 ns f sbf bclk frequency 64 f s t sls lrclk setup 10 ns to bclk rising edge t slh lrclk hold 10 ns from bclk rising edge t sds sdin setup 10 ns to bclk rising edge t sdh sdin hold 10 ns from bclk rising edge t sdd sdo delay 50 ns from bclk falling edge master mode t mld lrclk delay 25 ns from bclk falling edge t mdd sdo delay 15 ns from bclk falling edge t mds sdin setup 10 ns from bclk rising edge t mdh sdin hold 10 ns from bclk rising edge adav4622 rev. b | page 10 of 28 timing diagrams mclki reset t mp = 1/ f mclki t reset 07068-004 figure 2. master clock and reset timing 07068-036 t jit t ch t cl t ck dvdd gnd figure 3. master cl ock output timing lrclk1 bclk1 sdinx sdo0 t sls t slh t sds t sdh t sdd 07068-002 figure 4. serial port slave mode timing lrclk1 bclk1 sdinx sdo0 t mld t mds t mdh t mdd 07068-003 figure 5. serial port master mode timing 07068-033 odvdd 100a i ol 100a i oh to output pin 50pf figure 6. load circuit for digita l output timing specifications adav4622 rev. b | page 11 of 28 07068-034 dvdd 1.8 v 0v 3. 3 v 0v av dd odvdd 1.0s max 1.0s max 1.65v 3.0v 0.33v 0.18v figure 7. power-up sequence timing 07068-035 dvdd 1.8 v 0v 3.3v 0v avdd od vdd 1.0s max 1.0s max 1.65v 3.0v 0.33v 0.18v figure 8. power-down sequence timing adav4622 rev. b | page 12 of 28 absolute maximum ratings table 3. parameter rating dvdd to dgnd 0 v to 2.2 v odvdd to dgnd 0 v to 4 v avdd to agnd 0 v to 4 v agnd to dgnd ?0.3 v to +0.3 v digital inputs dgnd ? 0.3 v to odvdd + 0.3 v analog inputs agnd ? 0.3 v to avdd + 0.3 v reference voltage indefinite short circuit to ground soldering (10 sec) 300c stresses above those listed under absolute maximum ratings may cause permanent damage to the device. this is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. thermal resistance ja is specified for the worst-case conditions, that is, a device soldered in a circuit board for surface-mount packages. table 4. thermal resistance 1 package type ja jc unit 80-lead lqfp 38.1 7.6 c/w 1 based on jedec 2s2p pcb. thermal conditions to ensure correct operation of the device, the case temperature (t case ) must be kept below 121c to keep the junction tempera- ture (t j ) below the maximum allowed, 125c. esd caution adav4622 rev. b | page 13 of 28 pin configuration and fu nction descriptions vref agnd avdd sif_refn sif_refcm sif_refp filta sif_in1 sif_pga_ref sif_in2 avdd dgnd dvdd mute sda scl s pdif_in5/lrclk2 spdi f _in6/bclk2 dgnd 2 3 4 7 6 5 1 8 9 10 12 13 14 15 16 17 18 19 20 11 agnd avdd hpout1r hpout1l pll_lf agnd agnd hpout2l avdd dgnd dvdd pwm4b pwm4a pwm3b pwm3a pwm2b pwm2a pwm1b pwm1a dgnd 59 58 57 54 55 56 60 53 52 51 49 48 47 46 45 44 43 42 41 50 reset 21 dvdd 22 sdin0 23 sdin1 24 sdin2 25 spdif_in0/sdin3 26 spdif_in1/lrclk0 27 spdif_in2/bclk0 28 odgnd 29 odvdd 30 mclk_out 31 dvdd 32 dgnd 33 mclki/xin 34 xout 35 spdif_in4/bclk1 36 spdif_in3/lrclk1 37 sdo0/ad0 38 spdif_out/sdo1 39 pwm_ready 40 dvdd iset auxin1r auxin1l auxin2r auxin2l auxout2r auxout2l auxout1r auxout1l avdd agnd agnd avdd filtd nc auxout4r auxout4l auxout3r auxout3l hpout2r 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 pin 1 adav4622 top view (not to scale) 07068-006 nc = no connect figure 9. pin configuration table 5. pin function descriptions pin o. mnemonic description 1 filta adc filter capacitor. 2 vref reference capacitor. 3 agnd adc ground. 4 avdd adc supply (3.3 v). 5 sif_refp sif adc positive reference (typical 1.4 v). 6 sif_refcm sif adc common-mode reference (typical 1 v). 7 sif_refn sif adc negative reference (typical 0.6 v). 8 sif_in1 sif input 1. 9 sif_pga_ref sif pga reference. 10 sif_in2 sif input 2. 11 agnd sif agnd. 12 avdd sif supply (3.3 v). 13 dgnd digital ground. 14 dvdd digital supply (1.8 v). 15 mute active low mute request input signal. adav4622 rev. b | page 14 of 28 pin no. mnemonic description 16 sda i 2 c data. 17 scl i 2 c clock. 18 spdif_in5/lrclk2 external input to s/pdif mux/left/right clock for src2 (default). 19 spdif_in6/bclk2 external input to s/pd if mux/bit clock for src2 (default). 20 dgnd digital ground. 21 dvdd digital supply (1.8 v). 22 sdin0 serial data input 0/src data input. 23 sdin1 serial data input 1/src data input. 24 sdin2 serial data input 2/src data input. 25 spdif_in0/sdin3 external input to s/pdif mux/s rc data input/serial data input 3 (default). 26 spdif_in1/lrclk0 external input to s/pdif mux/left/right clock for src1 (default). 27 spdif_in2/bclk0 external input to s/pd if mux/bit clock for src1 (default). 28 odgnd digital ground. 29 odvdd digital interface supply (3.3 v). 30 mclk_out master clock output. 31 dvdd digital supply (1.8 v). 32 dgnd digital ground. 33 mclki/xin master clock/crystal input. 34 xout crystal output. 35 spdif_in4/bclk1 external input to s/pdif mu x/bit clock for serial data i/o (default). 36 spdif_in3/lrclk1 external input to s/pdif mux/l eft/right clock for serial data i/o (default). 37 sdo0/ad0 serial data output. this pin acts as the i 2 c address select on reset. it has an internal pull-down resistor. 38 spdif_out/sdo1 output of s/pdif mux/serial data output. 39 pwm_ready pwm ready flag. 40 dvdd digital supply (1.8 v). 41 dgnd digital ground. 42 pwm1a pulse-width modulated output 1a. 43 pwm1b pulse-width modulated output 1b. 44 pwm2a pulse-width modulated output 2a. 45 pwm2b pulse-width modulated output 2b. 46 pwm3a pulse-width modulated output 3a. 47 pwm3b pulse-width modulated output 3b. 48 pwm4a pulse-width modulated output 4a. 49 pwm4b pulse-width modulated output 4b. 50 reset reset analog and digital cores. 51 dvdd digital supply (1.8 v). 52 dgnd digital ground. 53 avdd pll supply (3.3 v). 54 pll_lf pll loop filter. 55 agnd pll ground. 56 agnd headphone driver ground. 57 hpout1l left headphone output 1. 58 hpout1r right headphone output 1. 59 avdd headphone driver supply (3.3 v). 60 hpout2l left headphone output 2. 61 hpout2r right headphone output 2. 62 auxout3l left auxiliary output 3. 63 auxout3r right auxiliary output 3. 64 auxout4l left auxiliary output 4. 65 auxout4r right auxiliary output 4. 66 nc no connection to this pin allowed. 67 filtd dac filter capacitor. adav4622 rev. b | page 15 of 28 pin no. mnemonic description 68 avdd dac supply (3.3 v). 69 agnd dac ground. 70 agnd dac ground. 71 avdd dac supply (3.3 v). 72 auxout1l left auxiliary output 1. 73 auxout1r right auxiliary output 1. 74 auxout2l left auxiliary output 2. 75 auxout2r right auxiliary output 2. 76 auxin2l left auxiliary input 2. 77 auxin2r right auxiliary input 2. 78 auxin1l left auxiliary input 1. 79 auxin1r right auxiliary input 1. 80 iset adc current setting. adav4622 rev. b | page 16 of 28 typical performance characteristics 0 ?180 ?160 07 magnitude (db) frequency (khz) 192 384 576 ?140 ?120 ?100 ?80 ?60 ?40 ?20 6 8 07068-007 figure 10. dac composite filter response (48 khz) 0 ?160 09 magnitude (db) frequency (khz) 24 48 72 ?140 ?120 ?100 ?80 ?60 ?40 ?20 6 07068-008 figure 11. dac band-pass filter response (48 khz) 0.6 ?0.6 ?0.4 ?0.2 0 0.2 0.4 02 magnitude (db) frequency (khz) 81 6 4 07068-009 figure 12. dac pass-band ripple (48 khz) 0 ?30 ?60 ?90 ?120 ?150 ?180 ?210 ?240 ?270 ?300 03 magnitude (db) frequency (khz) 128 256 8 4 07068-010 figure 13. adc composite filter response (48 khz) 0 ?180 ?150 ?120 ?90 ?60 ?30 09 magnitude (db) frequency (khz) 24 48 72 6 07068-011 figure 14. adc band-pass filter response (48 khz) 0.04 ?0.04 ?0.03 ?0.02 ?0.01 0 0.01 0.02 0.03 02 magnitude (db) frequency (khz) 81 6 4 07068-012 figure 15. adc pass-band ripple (48 khz) adav4622 rev. b | page 17 of 28 0 ?160 0 20000 magnitude (dbv) frequency (hz) 4000 8000 12000 16000 ?140 ?120 ?100 ?80 ?60 ?40 ?20 0 7068-013 figure 16. dac dynamic range 0 ?160 02 0 0 0 0 magnitude (dbv) frequency (hz) 4000 8000 12000 16000 ?140 ?120 ?100 ?80 ?60 ?40 ?20 0 7068-014 figure 17. dac total harmonic distortion + noise 0 ?160 magnitude (dbv) ?140 ?120 ?100 ?80 ?60 ?40 ?20 07068-015 0 20000 frequency (hz) 4000 8000 12000 16000 figure 18. adc dynamic range 0 ?160 magnitude (dbv) ?140 ?120 ?100 ?80 ?60 ?40 ?20 0 7068-016 0 20000 frequency (hz) 4000 8000 12000 16000 figure 19. adc total harmonic distortion + noise 0 ?140 ?120 ?100 ?80 ?60 ?40 ?20 01 0.90.80.70.60.5 0.4 0.30.20.1 gain (db) normalized frequency . 0 07068-017 figure 20. sample rate co nverter transfer function adav4622 rev. b | page 18 of 28 terminology dynamic range the ratio of a full-scale input signal to the integrated input noise in the pass band (20 hz to 20 khz), expressed in decibels (db). dynamic range is measured with a ?60 db input signal and is equal to (s/[thd+n]) + 60 db. note that spurious harmonics are below the noise with a ?60 db input, so the noise level establishes the dynamic range. the dynamic range is specified with and without an a-weight filter applied. pass band the region of the frequency spectrum unaffected by the attenuation of the digital decimators filter. pass-band ripple the peak-to-peak variation in amplitude response from equal amplitude input signal frequencies within the pass band, expressed in decibels. stop band the region of the frequency spectrum attenuated by the digital decimators filter to the degree specified by stop-band attenuation. gain error with a near full-scale input, the ratio of the actual output to the expected output, expressed in db. interchannel gain mismatch with identical near full-scale inputs, the ratio of the outputs of the two stereo channels, expressed in decibels. crosstalk ratio of response on one channel with a grounded input to a full-scale 1 khz sine wave input on the other channel, expressed in decibels. power supply rejection with no analog input, the signal present at the output when a 300 mv p-p signal is applied to power supply pins, expressed in decibels of full scale. group delay intuitively, the time interval required for an input pulse to appear at the converters output, expressed in milliseconds (ms). more precisely, the derivative of radian phase with respect to radian frequency at a given frequency. sif input isolation the level of the crosstalk between the sif inputs in db. fm limiting sensitivity fm limiting sensitivity is given by the modulated carrier level that gives half the power to the fm demodulators output amplitude comparing to that when the carrier level satisfies the demodulators limiting level. deviation mode in some regions, the transmitted signal can deviate from the specification. in order for the adav4622 to decode these high deviation signals correctly, the appropriate modulation level must be selected. am rejection ratio am rejection ratio is given by the ratio of fm (deviation = 54%) demodulated audio level vs. residual am (modulation = 27%) demodulated audio level at the same carrier level. it is the ability of the receiver to not mistake an am signal for an fm signal. am sensitivity am sensitivity is a measure of how well the receiver picks up very weak am signals. adav4622 rev. b | page 19 of 28 pin functions table 5 shows the pin numbers, mnemonics, and descriptions for the adav4622. the input pins have a logic threshold compatible with 3.3 v input levels. sdin0, sdin1, sdin2, and sdin3/spdif_in0 serial data inputs. these input pins provide the digital audio data to the signal processing core. any of the inputs can be routed to either of the srcs for conversion; this input is then not available as a synchronous input to the audio processor but only as an input through the selected src. the serial format for the synchronous data is selected by bits [3:2] of the serial port control register. if the srcs are required, the serial format is selected by bits [12:9] of the same register. the synchronous inputs are capable of using any pair of serial clocks lrclk0/ bclk0, lrclk1/bclk1, or lrclk2/bclk2. by default, they use lrclk1 and bclk1. see figure 24 for more details regarding the configuration of the synchronous inputs. sdin3 is a shared pin with spdif_in0. if sdin3 is not in use, this pin can be used to connect an s/pdif signal from an external source, such as an mpeg decoder, to the adav4622 on-chip s/pdif output multiplexer. if spdif_out is selected from one of the spdif_in (external) signals, the signal is simply passed through from input to output. lrclk0, bclk0, lrclk1, bclk1, lrclk2, and bclk2 by default, lrclk1 and bclk1 are associated with the synchronous inputs, lrclk0 and bclk0 are associated with src1, and lrclk2 and bclk2 are associated with src2. however, the srcs and synchronous inputs can use any of the serial clocks (see figure 24 for more details). lrclk0, bclk0, lrclk1, bclk1, lrclk2, and bclk2 are shared pins with spdif_in1, spdif_in2, spdif_in3, spdif_in4, spdif_in5, and spdif_in6, respectively. if lrclk0/lrclk1/lrclk2 or bclk0/bclk1/bclk2 are not in use, these pins can be used to connect an s/pdif signal from an external source, such as an mpeg decoder, to the adav4622 on-chip s/pdif output multiplexer. if spdif_out is selected from one of the spdif_in (external) signals, the signal is simply passed through from input to output. sdo0/ad0 serial data output. this pin can output two channels of digital audio using a variety of standard 2-channel formats. the clocks for sdo0 are always the same as those used by the synchronous inputs; this means that lrclk1 and bclk1 are used by default, although sdo0 is capable of using any pair of serial clocks, lrclk0/bclk0, lrclk1/bclk1, or lrclk2/bclk2. the serial port control register selects the serial format for the synchronous output. on reset, the sdo0 pin duplicates as the i 2 c? address select pin. in this mode, the logical state of the pin is polled for four mclki cycles following reset. the address select bit is set as the majority poll of the pins logic level after the four mclki cycles. spdif_out (sdo1) the adav4622 contains an s/pdif multiplexer functionality that allows the spdif_out signal to be chosen from an internally generated s/pdif signal or from the s/pdif signal from an external source, which is connected via one of the spdif_in pins. this pin can also be configured as an additional serial data output (sdo1) as an alternate function. mclki/xin master clock input. the adav4622 uses a pll to generate the appropriate internal clock for the audio processing core. a clock signal of a suitable frequency can be connected directly to this pin, or a crystal can be connected between mclki/xin and xout together with the appropriate capacitors to dgnd to generate a suitable clock signal. xout this pin is used in conjunction with mclki/xin to generate a clock signal for the adav4622. mclk_out this pin can be used to output mclki or one of the internal system clocks. it should be noted that the output level of this pin is referenced to dvdd (1.8 v) and not odvdd (3.3 v) like all other digital inputs and outputs. sda serial data input for the i 2 c control port. sda features a glitch elimination filter that removes spurious pulses that are less than 50 ns wide. adav4622 rev. b | page 20 of 2 8 scl serial clock for the i 2 c control port. scl features a glitch elimination filter that removes spurious pulses that are less than 50 ns wide. mute mute input request. this active-low input pin controls the muting of the output ports (both analog and digital) from the adav4622. when low, it asserts mute on the outputs that are enabled in the audio flow. reset active-low reset signal. after reset goes high, all the circuit blocks are powered down. the blocks can be individually powered up with software. when the part is powered up, it takes approximately 3072 internal clocks to initialize the internal circuitry. the internal system clock is equal to mclki until the pll is powered and enabled, after which the internal system clock becomes 2560 f s (122.88 mhz). once the pll is powered up and enabled after reset, it takes approximately 3 ms to lock. when the audio processor is enabled, it takes approximately 32,768 internal system clocks to initialize and load the default flow to the audio processor memory. the audio processor is not available during this time. auxin1l, auxin2l, auxin1r, and auxin2r analog inputs to the on-chip adcs. auxout1l, auxout2l, auxout3l, auxout4l, auxout1r, auxout2r, auxout3r, and auxout4r auxiliary dac analog outputs. these pins can be programmed to supply the outputs of the internal audio processing for line out or record use. hpout1l, hpout2l, hp out1r, and hpout2r analog outputs from the headphone amplifiers. pll_lf pll loop filter connection. a 100 nf capacitor and a 2 k resistor in parallel with a 1 nf capacitor tied to avdd are required for the pll loop filter to operate correctly. vref voltage reference for dacs and adcs. this pin is driven by an internal 1.5 v reference voltage. filta and filtd decoupling nodes for the adc and dac. decoupling capacitors should be connected between these nodes and agnd, typically 47 f/0.1 f and 10 f/0.1 f, respectively. pwm1a, pwm1b, pwm2 a, pwm2b, pwm3a, pwm3b, pwm4a, and pwm4b differential pulse-width modulation outputs are suitable for driving class-d amplifiers. pwm_ready this pin is set high when pwm is enabled and stable. avdd analog power supply pins. these pins should be connected to 3.3 v. each pin should be decoupled with 10 f and 0.1 f capacitors to agnd, as close to the pin as possible. dvdd digital power supply. this pin is connected to a 1.8 v digital supply. connecting 10 f and 0.1 f decoupling capacitors to dgnd, as close to the pin as possible, is strongly recommended for optimal performance. odvdd digital interface power supply pin. this pin should be connected to a 3.3 v digital supply. the pin should be decoupled with 10 f and 0.1 f capacitors to dgnd, as close to the pin as possible. dgnd digital ground. agnd analog ground. odgnd ground for the digital interface power supply. sif_refp, sif_refcm, and sif_refn decoupling nodes for the sif block. sif_in1 and sif_in2 analog inputs for the sif block. sif_pga_ref pga reference output. this pin should be decoupled to agnd with 10 f and 0.1 f capacitors. iset adc current setting resistor. adav4622 rev. b | page 21 of 2 8 functional descriptions sif processor supported sif standards the adav4622 supports all worldwide standards, as shown in table 6 . table 6. adav4622 worldwide sif standards system sound sc1 (mhz) sc2 (mhz) m btsc 4.5 C n btsc 4.5 C m eiaj 4.5 C m a2 4.5 4.724 bg a2 5.5 5.742 bg nicam 5.5 5.85 i mono 6.0 C i nicam 6.0 6.552 dk1 a2 6.5 6.258 dk2 a2 6.5 6.742 dk3 a2 6.5 5.742 dk nicam 6.5 5.85 l mono 6.5 C l nicam 6.5 5.85 sif demodulation figure 22 shows a block diagram of the sif demodulation block. the selected sif input signal is digitized by an adc with a sample rate of 24.576 mhz. an agc is included to ensure that for even low level signals, the full range of the adc is used. the digitized input is passed to the sif demodulator for demodulating. the outputs of the demodulator are then passed to the internal audio processor. internally, the audio processor runs at a 48 khz sampling frequency. when nicam is selected, an internal src upsamples the 32 khz nicam signal to the audio processor rate of 48 khz. sif processor configuration the adav4622 supports automatic standard detection, which is enabled by default. the asd controller configures the sif processor with the optimum register settings based on the detected standard. if the user prefers to operate in manual mode, or if the user prefers to use an external asd loop, all of the asd status registers are available. master clock oscillator internally, the adav4622 operates synchronously to the master mclki input. all internal system clocks are generated from this single clock input using an internal pll. this mclki input can also be generated by an external crystal oscillator connected to the mclki/xin pin or by using a simple crystal resonator connected across mclki/xin and xout. by default, the master clock frequency is 24.576 mhz; however, by using the internal dividers, an mclki of 12.288 mhz, 6.144 mhz, and 3.072 mhz are also supported. osc divider register divider word [8, 4, 2, 1] 3.072mhz pll reference clock master clock frequency [24.576mhz, 12.288mhz, 6.144mhz, 3.072mhz] i 2 c external clock/ crystal 07068-018 figure 21. master clock sif_in2 sif_in1 sif input 4.5mhz ~ 6.742mhz mux agc adc 24.576mhz fm/dqpsk/am demod sc1 sc2 a b sif parameters asd 07068-020 figure 22. sif demodulation adav4622 rev. b | page 22 of 2 8 i 2 c interface the adav4622 supports a 2-wire serial (i 2 c compatible) microprocessor bus driving multiple peripherals. the adav4622 is controlled by an external i 2 c master device, such as a microcontroller. the adav4622 is in slave mode on the i 2 c bus, except during self-boot. while the adav4622 is self-booting, it becomes the master, and the eeprom, which contains the roms to be booted, is the slave. when the self- boot process is complete, the adav4622 reverts to slave mode on the i 2 c bus. no other devices should access the i 2 c bus while the adav4622 is self-booting (refer to the application layer section and the loading a custom audio processing flow section). initially, all devices on the i 2 c bus are in an idle state, wherein the devices monitor the sda and scl lines for a start condition and the proper address. the i 2 c master initiates a data transfer by establishing a start condition, defined by a high-to-low transition on sda while scl remains high. this indicates that an address/data stream follows. all devices on the bus respond to the start condition and read the next byte (7-bit address plus the r/ w bit) msb first. the device that recognizes the transmit- ted address responds by pulling the data line low during the ninth clock pulse. this ninth bit is known as an acknowledge bit. all other devices on the bus revert to an idle condition. the r/ w bit determines the direction of the data. a logic level 0 on the lsb of the first byte means the master writes information to the peripheral. a logic level 1 on the lsb of the first byte means the master reads information from the peripheral. a data transfer takes place until a stop condition is encountered. a stop condition occurs when sda transitions from low to high while scl is held high. the adav4622 determines its i 2 c device address by sampling the sdo0 pin after reset. internally, the sdo0 pin is sampled by four mclki edges to determine the state of the pin (high or low). because the pin has an internal pull-down resistor default, the address of the adav4622 is 0x34 (write) and 0x35 (read). an alternate address, 0x36 (write) and 0x37 (read), is available by tying the sdo0 pin to odvdd via a 10 k resistor. the i 2 c interface supports a clock frequency up to 400 khz. adc inputs the adav4622 has four adc inputs. by default, these are configured as two stereo inputs; however, because the audio processor is programmable, these inputs can be reconfigured. the adc inputs are shown in figure 23 . the analog inputs are current inputs (100 a rms fs) with a 1.5 v dc bias voltage. any input voltage can be accommodated by choosing a suitable combination of input resistor (r in ) and iset resistor (r iset ) using the formulas r in = v fs rms /100 a rms r iset = 2r in /v in resistor matching (typically 1%) between r in and r iset is important to ensure a full-scale signal on the adc without clipping. dc bias 1.5v 24-bit adc auxin1l 20k? a nalog input 100 a rms full scale dc bias 1.5v 24-bit adc auxin1r 20k? a nalog input 100 a rms full scale dc bias 1.5v 24-bit adc auxin2l 20k? a nalog input 100 a rms full scale dc bias 1.5v 24-bit adc auxin2r 20k? a nalog input 100 a rms full scale r iset 20k ? iset 07068-019 figure 23. analog input section i 2 s digital audio inputs the adav4622 has four i 2 s digital audio inputs that are, by default, synchronous to the master clock. also available are two srcs capable of supporting any nonsynchronous input with a sample rate between 5 khz and 50 khz. any of the serial digital inputs can be redirected through the src. figure 24 shows a block diagram of the input serial port. src2b src2c lrclk0 bclk0 lrclk1 bclk1 lrclk2 bclk2 sdin0 sdin1 sdin2 sdin3 lrclk0 bclk0 sdin0 sdin1 sdin2 sdin3 lrclk1 bclk1 lrclk2 bclk2 src1 lrclk0 bclk0 sdin0 sdin1 sdin2 sdin3 lrclk1 bclk1 lrclk2 bclk2 src2 src2a src2b src2c audio processor 0 7068-021 figure 24. digital input section adav4622 rev. b | page 23 of 2 8 synchronous inputs and outputs the synchronous digital inputs and outputs can use any of the bclk or lrclk inputs as a clock and framing signal. by default, bclk1 and lrclk1 are the serial clocks used for the synchronous inputs. the synchronous port for the adav4622 is in slave mode by default, which means the user must supply the appropriate serial clocks, bclk and lrclk. the synchronous port can also be set to master mode, which means that the appropriate serial clocks, bclk and lrclk, can be generated internally from the mclk; therefore, the user does not need to provide them. the serial data inputs are capable of accepting all the popular audio transmission standards (see the serial data interface section for more details). asynchronous inputs the adav4622 has two srcs, src1 and src2, that can be used for converting digital data, which is not synchronous to the master clock. each src can accept input sample rates in the range of 5 khz to 50 khz. data that has been converted by the src is inputted to the part and is then synchronous to the internal audio processor. the src1 is a 2-channel (single-stereo) sample rate converter that is capable of using any of the three serial clocks available. the src1 can accept data from any of the serial data inputs (sdin0, sdin1, sdin2, and sdin3). once selected as an input to the src, this sdin line is assumed to contain asynchronous data and is then masked as an input to the audio processor to ensure that asynchronous data is not processed as synchronous data. by default, src1 uses the lrclk0 and bclk0 as the clock and framing signals. the src2 is a 6-channel (3-stereo) sample rate converter that is capable of using any of the three serial clocks available. the src2 can accept data from any of the serial data inputs (sdin0, sdin1, sdin2, and sdin3). once selected as an input to the src, this sdin line is assumed to contain asynchronous data and is then masked internally as an input to the audio processor to ensure that asynchronous data is not processed as synchronous data. by default, src2 uses the lrclk2 and bclk2 as the clock and framing signals. the first output (src2a) from src2 is always available to the audio processor. the other two outputs are muxed with two of the serial inputs before being available to the audio processor. src2b is muxed with sdin2 and src2c is muxed with sdin3. by default, these muxes are configured so that the synchronous inputs are available to the audio processor. the src2b and src2c channels can be made available to the audio processor simply by enabling them by register write. when using the adav4622 in an asynchronous digital-in-to- digital-out configuration, the input digital data are input to the audio processor core from one of the srcs, using the assigned bclk/lrclk as a framing signal. the digital output is synchronous to the bclk/lrclk, which is assigned to the synchronous port; the default clocks in this case are bclk1 and lrclk1. serial data interface lrclk is the framing signal for the left- and right-channel inputs, with a frequency equal to the sampling frequency (f s ). bclk is the bit clock for the digital interface, with a frequency of 64 f s (32 bclk periods for each of the left and right channels). the serial data interface supports all the popular audio interface standards, such as i 2 s, left-justified (lj), and right-justified (rj). the interface mode is software selectable, and its default is i 2 s. the data sample width is also software selectable from 16 bits, 20 bits, or 24 bits. the default is 24 bits. i 2 s mode in i 2 s mode, the data are left-justified, msb first, with the msb placed in the second bclk period following the transition of the lrclk. a high-to-low transition of the lrclk signifies the beginning of the left-channel data transfer, and a low-to-high transition on the lrclk signifies the beginning of the right- channel data transfer (see figure 26 ). lj mode in lj mode, the data are left-justified, msb first, with the msb placed in the first bclk period following the transition of the lrclk. a high-to-low transition of the lrclk signifies the beginning of the right-channel data transfer, and a low-to-high transition on the lrclk signifies the beginning of the left- channel data transfer (see figure 27 ). rj mode in rj mode, the data are right-justified, lsb last, with the lsb placed in the last bclk period preceding the transition of lrclk. a high-to-low transition of the lrclk signifies the beginning of the right-channel data transfer, and a low-to-high transition on the lrclk signifies the beginning of the left- channel data transfer (see figure 28 ). dac voltage outputs the adav4622 has eight dac outputs, configured as four stereo auxiliary dac outputs. however, because the flow is customiza- ble, this is programmable. the output level is 1 v rms full scale. auxout2l auxout2r dac auxout1l auxout1r dac auxout3l auxout3r dac auxout4l auxout4r dac 07068-025 figure 25. dac output section adav4622 rev. b | page 24 of 2 8 lrclk bclk sdo0 msb left channel lsb msb right channel lsb 1 /f s 07068-022 figure 26. i 2 s mode lrclk bclk sdo0 left channel msb lsb msb right channel lsb 1 /f s 07068-023 figure 27. left-justified mode lrclk bclk sdo0 left channel msb lsb msb right channel lsb 1 /f s 07068-024 figure 28. right-justified mode pwm outputs in the adav4622, the main outputs are available as four pwm output channels, which are suitable for driving class-d amplifiers. pwm_ready is a status pin used to signify that the adav4622 pwm outputs are in a valid state. during pwm power-up and power-down, this pin remains low to signify that the outputs are not in a valid state. the output power stage should remain muted until this pin goes high. this functionality helps to eliminate pop/click and other unwanted noise on the outputs. pwm1a pwm1b pwm2a pwm2b pwm3a pwm3b pwm modulator pwm modulator pwm modulator + ? + ? + ? pwm4a pwm_ready pwm4b pwm modulator + ? 07068-026 figure 29. pwm output section each set of pwm outputs is a complementary output. the modulation frequency is 384 khz, and the full-scale duty cycle has a ratio of 97:3. full details on the use of the pwm outputs are available upon request. contact a local analog devices sales representative for more details. headphone outputs there are two stereo headphone amplifier outputs capable of driving 32 loads at 1 v rms. hpout1 is shared with auxout4, and hpout2 is shared with auxout2, as shown in figure 30 . auxout2r auxout2l pa hpout2l hpout2r dac 07068-027 auxout4r auxout4l pa hpout1l hpout1r dac figure 30. headphone outputs section i 2 s digital audio outputs one i 2 s output, sdo0, uses the same serial clocks as the serial inputs, which are bclk1 and lrclk1 by default. if an addi- tional digital output is required, an additional pin can be reconfigured as a serial digital output, as shown in figure 31 . sdo0 r l r l s/pdif output spdif_out (sdo1) i 2 s output interface bclk1 lrclk1 0 7068-028 figure 31. i 2 s digital outputs adav4622 rev. b | page 25 of 2 8 s/pdif input/output the s/pdif output (spdif_out/sdo1) uses a multiplexer to select an output from the audio processor or to pass through the unprocessed spdif_in signals, as shown in figure 32 . on the adav4622, the s/pdif inputs, spdif_in0/spdif_in1/ spdif_in2/spdif_in3/spdif_in4/spdif_in5/spdif_in6, are available on the sdin3, lrclk0, bclk0, lrclk1, bclk1, lrclk2, and bclk2 pins, respectively. it is possible to have all seven s/pdif inputs connected to different s/pdif signals at one time. a consequence of this setup is that none of the lrclks and bclks are available for use with the digital inputs sdin0, sdin1, sdin2, and sdin3. if there is only one s/pdif input in use, using the sdin3 pin as the dedicated s/pdif input is recommended; this enables bclk0/lrclk0, bclk1/lrclk1, and bclk2/lrclk2 to be used as the clock and framing signal for the synchronous and asynchronous port. if sdin3 is used as an s/pdif input, it should not be used internally as an input to the audio processor because it contains invalid data. similarly, if bclk or lrclk are used as s/pdif inputs, they can no longer be used as the clock and framing signals for sdin0, sdin1, sdin2, and sdin3. the s/pdif encoder supports only consumer formats that conform to iec-600958. sdin3 (spdif_in0) lrclk0 (spdif_in1) bclk0 (spdif_in2) lrclk1 (spdif_in3) bclk1 (spdif_in4) lrclk2 (spdif_in5) bclk2 (spdif_in6) sdo1 (spdif_out) s/pdif encoder 0 7068-029 figure 32. s/pdif output hardware mute control the adav4622 mute input can be used to mute any of the analog or digital outputs. when the mute pin goes low, the selected outputs ramp to a muted condition. unmuting is handled in one of two ways and depends on the register setting. by default, the mute pin going high causes the outputs to immediately ramp to an unmuted state. however, it is also possible to have the unmute operation controlled by a control register bit. in this scenario, even if the mute pin goes high, the device does not unmute until a bit in the control register is set. this can be used when the user wants to keep the outputs muted, even after the pin has gone high again, for example, in the case of a fault condition. this allows the system controller total control over the unmute operation. full details on register settings and operation of the mute function are available upon request. contact a local analog devices sales representative for more details. audio processor the internal audio processor runs at 2560 f s ; at 48 khz, this is 122.88 mhz. internally, the word size is 28 bits, which allows 24 db of headroom for internal processing. designed specific- ally with audio processing in mind, it can implement complex audio algorithms efficiently. by default, the adav4622 loads a default audio flow, as shown in figure 34 . however, because the audio processor is fully programmable, a custom audio flow can be quickly developed and loaded to the audio processor. the audio flow is contained in program ram and parameter ram. program ram contains the instructions to be processed by the audio processor, and parameter ram contains the coefficients that control the flow, such as volume control, filter coefficients, and enable bits. graphical programming environment custom flows for the adav4622 are created in a powerful drag-and-drop graphical programming application. no knowl- edge of assembly code is required to program the adav4622. featuring a comprehensive library of audio processing blocks (such as filters, delays, dynamics processors, and third-party algorithms), it allows the quick and simple creation of custom flows. for debugging purposes, run-time control of the audio flow allows the user to fully configure and test the created flow. training materials and support are available upon request. contact a local analog devices sales representative for more details. application layer unique to this family is the embedded application layer, which allows the user to define a custom set of registers to control the audio flow, greatly simplifying the interface between the audio processor and the system controller. once a custom flow is created, a user-customized register map can be defined for controlling the flow. each register is 16 bits, but controls can use only one bit or all 16 bits. users have full control over which parameters they control and the degree of control they have over those parameters during run time. the combination of the graphical programming environment and the powerful application layer allows the user to quickly develop a custom audio flow and still maintain the usability of a simple register-based device. comprehensive documentation on developing a custom audio flow and the definition and creation of the custom application layer for the adav4622 is available upon request. contact a local analog devices sales representative for more details. adav4622 rev. b | page 26 of 2 8 audio processor memory address data default code i 2 c port load on command load on reset boot-up rom custom code external boot-up rom 47260 bytes (max) audio processor 0 7068-030 loading a custom audio processing flow the adav4622 can load a custom audio flow from an external i 2 c rom. the boot process is initiated by a simple control register write. the eeprom device address and the eeprom start address for the audio flow roms can all be programmed. for the duration of the boot sequence, the adav4622 becomes the master on the i 2 c bus. transfer of the roms from the eeprom to the adav4622 takes a maximum of 1.06 sec, assuming that the full audio processor memory is required, during which time no other devices should access the i 2 c bus. once the transfer is complete, the adav4622 automatically reverts to slave mode, and the i 2 c bus master can resume sending commands. figure 33. external eeprom booting adav4622 rev. b | page 27 of 2 8 07068-031 limiter limiter volume control balance balance dynamic bass crossover loudness 7-band eq beeper avc lip sync trim main mux mux delay sif auxin2l auxin2r sdin0 sdin1 mute volume balance loudness 7-band eq trim hp mux mute trim auxout2 mux mute trim s/pdif mux mute pwm1 (lhigh) pwm2 (rhigh) mute pwm3 (llow) pwm4 (rlow) auxout2l/ hpout2l auxout2r/ hpout2r hpout1l/ auxout4l hpout1r/ auxout4r sub channel to input muxes s/pdif outl (sdol1) s/pdif outr (sdor1) + + mute trim sdo0 mux sdol0 sdor0 mute auxout3 mux auxout3l auxout3r mute trim auxout1l auxout1r (l + r)/2 lpf crossover trim crossover trim sub channel auxin1l auxin1r s din2/src2 c hannel b s din3/src2 c hannel c s rc1 s rc2 c hannel a src delay src2 mute 8-band eq spatializer src1 mute auxout1 mux figure 34. default audio processing flow adav4622 rev. b | page 28 of 28 outline dimensions compliant to jedec standards ms-026-bec 1.45 1.40 1.35 0.15 0.05 0.20 0.09 0.10 coplanarity view a rotated 90 ccw seating plane 7 3.5 0 61 60 1 80 20 41 21 40 view a 1.60 max 0.75 0.60 0.45 16.20 16.00 sq 15.80 14.20 14.00 sq 13.80 0.65 bsc lead pitch 0.38 0.32 0.22 top view (pins down) pin 1 051706-a figure 35. 80-lead low profile quad flat package [lqfp] (st-80-2) dimensions shown in millimeters ordering guide model temperature range sif standard package description package option ADAV4622BSTZ 1 ?40c to +85c pal/ntsc/secam 80-lead low profile quad flat package (lqfp) st-80-2 eval-adav4622ebz 1 evaluation board 1 z = rohs compliant part. in addition, it is backward compatible with conventional snpb soldering processes. this means the electroplated sn coating can be soldered with sn/pb solder pastes at conventional reflow te mperatures of 220c to 235c. purchase of licensed i 2 c components of analog devices or one of its sublicensed associated companies conveys a license for the purchaser under the phi lips i 2 c patent rights to use these components in an i 2 c system, provided that the system conforms to the i 2 c standard specification as defined by philips. ?2008C2009 analog devices, inc. all rights reserved. trademarks and registered trademarks are the prop erty of their respective owners. d07068-0-7/09(b) |
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