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| 1. general description the TDA8920C is a high-ef?ciency class-d audio power ampli?er. the typical output power is 2 110 w with a speaker load impedance of 4 w . the TDA8920C is available in both hsop24 and dbs23p power packages. the ampli?er operates over a wide supply voltage range from 12.5 v to 32.5 v and has a low quiescent current consumption. 2. features n pin compatible with tda8950/20b for both hsop24 and dbs23p packages n symmetrical high operating supply voltage range from 12.5 v to 32.5 v n stereo full differential inputs, usable as stereo single-ended (se) or mono bridge-tied load (btl) ampli?er n high output power at typical applications: u se 2 110 w, r l =4 w (v p = 30 v) u se 2 125 w, r l =4 w (v p = 32 v) u se 2 120 w, r l =3 w (v p = 29 v) u btl 1 210 w, r l =8 w (v p = 30 v) n low noise in btl operation due to bd modulation n smooth pop noise-free start-up and switch off n zero dead time pulse-width modulation (pwm) output switching n fixed frequency n internal or external clock switching frequency n high ef?ciency n low quiescent current n advanced protection strategy: voltage protection and output current limiting n thermal foldback n fixed gain of 30 db in se and 36 db in btl n full short-circuit proof across load 3. applications n dvd n mini and micro receiver n home theater in a box (htiab) system n high power speaker system TDA8920C 2 110 w class-d power ampli?er rev. 01 29 september 2008 preliminary data sheet
TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 2 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 4. quick reference data [1] the circuit is dc adjusted at v p = 12.5 v to 32.5 v. [2] output power is measured indirectly; based on r dson measurement; see section 13.3 . 5. ordering information table 1. quick reference data symbol parameter conditions min typ max unit general, v p = 30 v v p supply voltage operating mode [1] 12.5 30 32.5 v v p(ovp) overvoltage protection supply voltage non-operating mode; v dd - v ss 65 - 70 v i q(tot) total quiescent current operating mode; no load; no ?lter; no rc-snubber network connected - 5075ma stereo single-ended con?guration p o output power l = 22 m h; c = 680 nf; t j =85 c thd = 10 %; r l =4 w ; v p = 30 v [2] - 110 - w thd = 10 %; r l =4 w ; v p = 27 v -80-w mono bridge-tied load con?guration p o output power l = 22 m h; c = 680 nf; t j =85 c; thd = 10 %; r l =8 w ; v p = 30 v [2] - 210 - w table 2. ordering information type number package name description version TDA8920Cj dbs23p plastic dil-bent-sil power package; 23 leads (straight lead length 3.2 mm) sot411-1 TDA8920Cth hsop24 plastic, heatsink small outline package; 24 leads; low stand-off height sot566-3 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 3 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 6. block diagram pin numbers in brackets refer to type number TDA8920Cj. fig 1. block diagram 001aai852 out1 v ssp1 v ddp2 driver high out2 boot2 TDA8920Cth (TDA8920Cj) boot1 driver low switch1 control and handshake pwm modulator manager oscillator temperature sensor current protection voltage protection stabi mode input stage mute 9 (3) 8 (2) in1m in1p 22 (15) 21 (14) 20 (13) 17 (11) 16 (10) 15 (9) vssp2 vssp1 driver high driver low switch2 control and handshake pwm modulator 11 (5) n.c. 7 (1) osc 2 (19) sgnd 6 (23) mode input stage mute 5 (22) 4 (21) in2m in2p 19 (-) 24 (17) vssd n.c. 1 (18) vssa 12 (6) n.c. 3 (20) vdda 10 (4) n.c. 23 (16) 13 (7) 18 (12) 14 (8) vddp2 prot stabi vddp1 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 4 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 7. pinning information 7.1 pinning fig 2. pin con?guration TDA8920Cth fig 3. pin con?guration TDA8920Cj TDA8920Cth vssd vssa vddp2 sgnd boot2 vdda out2 in2m vssp2 in2p n.c. mode stabi osc vssp1 in1p out1 in1m boot1 n.c. vddp1 n.c. prot n.c. 001aai853 24 23 22 21 20 19 18 17 16 15 14 13 11 12 9 10 7 8 5 6 3 4 1 2 TDA8920Cj osc in1p in1m n.c. n.c. n.c. prot vddp1 boot1 out1 vssp1 stabi vssp2 out2 boot2 vddp2 vssd vssa sgnd vdda in2m in2p mode 001aai854 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 5 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 7.2 pin description 8. functional description 8.1 general the TDA8920C is a two-channel audio power ampli?er using class-d technology. the audio input signal is converted into a digital pulse-width modulated signal using an analog input stage and pwm modulator; see figure 1 . to enable the output power transistors to be driven, the digital pwm signal is applied to a control and handshake block and driver circuits for both the high side and low side. this level-shifts the low-power digital pwm signal from a logic level to a high-power pwm signal switching between the main supply lines. a 2nd-order low-pass ?lter converts the pwm signal to an analog audio signal across the loudspeakers. table 3. pin description symbol pin description TDA8920Cth TDA8920Cj vssa 1 18 negative analog supply voltage sgnd 2 19 signal ground vdda 3 20 positive analog supply voltage in2m 4 21 channel 2 negative audio input in2p 5 22 channel 2 positive audio input mode 6 23 mode selection input: standby, mute or operating mode osc 7 1 oscillator frequency adjustment or tracking input in1p 8 2 channel 1 positive audio input in1m 9 3 channel 1 negative audio input n.c. 10 4 not connected n.c. 11 5 not connected n.c. 12 6 not connected prot 13 7 decoupling capacitor for protection (ocp) vddp1 14 8 channel 1 positive power supply voltage boot1 15 9 channel 1 bootstrap capacitor out1 16 10 channel 1 pwm output vssp1 17 11 channel 1 negative power supply voltage stabi 18 12 decoupling of internal stabilizer for logic supply n.c. 19 - not connected vssp2 20 13 channel 2 negative power supply voltage out2 21 14 channel 2 pwm output boot2 22 15 channel 2 bootstrap capacitor vddp2 23 16 channel 2 positive power supply voltage vssd 24 17 negative digital supply voltage TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 6 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er the TDA8920C single-chip class-d ampli?er has built-in high-power switches, drivers, timing and handshaking between the power switches and some control logic. in addition, to secure maximum system robustness, an advanced protection strategy is implemented for voltage, temperature and maximum current. both of the TDA8920C audio channels contain a pwm modulator, an analog feedback loop and a differential input stage. the TDA8920C also contains circuits common to both channels such as the oscillator, all reference sources, the mode interface and a digital timing manager. the two independent ampli?er channels have high output power, high ef?ciency, low distortion and low quiescent current. the ampli?er channels can be connected in the following con?gurations: ? mono bridge-tied load (btl) ampli?er ? stereo single-ended (se) ampli?ers the ampli?er system can be switched to one of three operating modes using pin mode: ? standby mode: with a very low supply current ? mute mode: the ampli?ers are operational but the audio signal at the output is suppressed by disabling the voltage-to-current (vi) converter input stages ? operating mode: the ampli?ers are fully operational with the output signal to ensure pop noise-free start-up, the dc output offset voltage is applied gradually to the output at a level between mute mode and operating mode levels. the bias-current setting of the vi-converters is related to the voltage on pin mode. in mute mode the bias-current setting of the vi-converters is zero (vi-converters are disabled). in operating mode the bias current is at maximum. the time-constant required to apply the dc output offset voltage gradually between mute and operating mode levels can be generated using an rc network on pin mode. an example of a switching circuit for driving pin mode is illustrated in figure 4 . if the capacitor c is left out of the application the voltage on pin mode is applied with a much smaller time-constant, which may result in audible pop noises during start-up (depending on the dc output offset voltage and loudspeaker used). fig 4. example of mode selection circuit 001aab172 sgnd mode pin mute/on r c r + 5 v standby/ mute TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 7 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er to fully charge the coupling capacitors at the inputs, the ampli?er automatically remains in the mute mode before switching to the operating mode. a complete overview of the start-up timing is shown in figure 5 . (1) first 1 4 pulse down. upper diagram: when switching from standby to mute there is a delay of approximately 100 ms before the output starts switching. the audio signal is available after v mode is set to operating but not earlier than 150 ms after switching to mute. to start up pop noise-free, it is recommended that the time-constant applied to pin mode is at least 350 ms for the transition between mute and operating. lower diagram: when switching directly from standby to operating there is a delay of 100 ms before the outputs start switching. the audio signal is available after a second delay of 50 ms. to start up pop noise-free, it is recommended that the time-constant applied to pin mode is at least 500 ms for the transition between standby and operating. fig 5. timing on mode selection input pin mode 2.2 v < v mode < 3 v audio output operating standby mute 50 % duty cycle > 4.2 v 0 v (sgnd) time 001aah657 v mode 100 ms 50 ms modulated pwm > 350 ms 2.2 v < v mode < 3 v audio output operating standby mute 50 % duty cycle > 4.2 v 0 v (sgnd) time v mode 100 ms 50 ms modulated pwm > 350 ms (1) (1) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 8 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 8.2 pulse-width modulation frequency the output signal of the ampli?er is a pwm signal with a carrier frequency typically between 300 khz and 400 khz. using a 2nd-order lc demodulation ?lter in the application results in an analog audio signal across the loudspeaker. the carrier frequency is determined by an external resistor r osc , connected between pin osc and pin vssa. an optimal setting for the carrier frequency is between 300 khz and 400 khz. the carrier frequency is set to 345 khz by connecting a 30 k w external resistor between pin osc and vssa. see t ab le 8 for more details. if two or more class-d ampli?ers are used in the same audio application, it is recommended that all devices use an external clock circuit to ensure that they operate at the same switching frequency. 8.3 protection the following protection strategies are provided: ? thermal protection: C thermal foldback (tfb) C overtemperature protection (otp) ? overcurrent protection (ocp, diagnostic output on pin prot) ? window protection (wp) ? supply voltage protection: C undervoltage protection (uvp) C overvoltage protection (ovp) C unbalance protection (ubp) the device reacts to fault conditions differently for each protection type. 8.3.1 thermal protection the TDA8920C has an advanced thermal protection strategy. it consists of a tfb function that gradually reduces the output power within a de?ned temperature range. if the temperature continues to rise, otp is implemented, shutting down the device completely. 8.3.1.1 thermal foldback (tfb) if the junction temperature (t j ) exceeds the de?ned threshold value, the gain is gradually reduced. this reduces the output signal amplitude and the power dissipation, eventually stabilizing the temperature. TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 9 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er tfb is speci?ed at the thermal foldback activation temperature t act(th_fold) where the closed-loop voltage gain is reduced by 6 db. the tfb range is: t act(th_fold) - 5 c < t act(th_fold) < t act(th_prot) the value of t act(th_fold) for the TDA8920C is approximately 153 c; see t ab le 7 for more details. 8.3.1.2 overtemperature protection (otp) if despite the tfb function, the junction temperature (t j ) of the TDA8920C continues to rise exceeding the thermal protection activation temperature t act(th_prot) , the ampli?er shuts down immediately. the ampli?er resumes switching approximately 100 ms after the temperature drops below t act(th_prot) . the thermal behavior is illustrated in figure 6 . 8.3.2 overcurrent protection (ocp) overcurrent protection (ocp) will detect a short-circuit applied to any of the demodulated outputs of the ampli?er. if the output current exceeds the 9.2 a maximum, it is automatically limited to its maximum value by the ocp protection circuit, the ampli?er is not shut down completely, and the ampli?er outputs continue switching. if the active current limiting continues longer than time ( t ), the TDA8920C shuts down. activation of current limiting and the triggering of ocp are output at pin prot. ocp can distinguish between a loudspeaker impedance drop and a low-ohmic short-circuit across the load. in the TDA8920C, the impedance threshold (z th ) depends on the supply voltage used. if a short-circuit occurs across the load causing the impedance to drop below the threshold level (< z th ), the ampli?er switches off completely. after 100 ms, it tries to restart. if the short-circuit condition is still present, the cycle is repeated. the average power dissipation will be low because of the low duty cycle. (1) duty cycle of pwm output modulated according to the audio input signal. (2) duty cycle of pwm output reduced due to tfb. (3) ampli?er is switched off due to otp. fig 6. behavior of tfb and otp 001aah656 (t act(th_fold) - 5 c) t act(th_fold) t j ( c) t act(th_prot) gain (db) 30 db 24 db 0 db 12 3 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 10 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er if an impedance drop occurs (e.g. due to dynamic behavior of the loudspeaker) ocp is activated. the maximum output current stays limited to 9.2 a but the ampli?er will not switch off completely, preventing audio holes from occurring. the result is a clipped output signal. see section 13.7 for more information on this maximum output current limiting feature. 8.3.3 window protection (wp) window protection (wp) checks the conditions at the output terminals of the power stage and is activated: ? during the start-up sequence, when pin mode is switched from standby to mute. in the event of a short-circuit at one of the output terminals to pin vddpn or pin vsspn, the start-up procedure is interrupted. the TDA8920C waits until the short-circuit to the supply lines is removed. no large currents will ?ow in the event of a short-circuit because the test is done before the power stages are enabled. ? when the ampli?er shuts down completely due to ocp activation because of a short-circuit to one of the supply lines; wp is activated during a restart after 100 ms. the ampli?er will not start up until the short-circuit to the supply lines is removed. 8.3.4 supply voltage protection if the supply voltage drops below the minimum supply voltage, the undervoltage protection (uvp) circuit is activated and the system shuts down correctly. if the internal clock is used, the switch-off will be silent and without pop noise. when the supply voltage rises above the threshold level, the system restarts after 100 ms. if the supply voltage exceeds the maximum supply voltage, the ovp circuit is activated and the power stages are shut down. when the supply voltage drops below the threshold level, the system restarts after 100 ms. an additional unbalance protection (ubp) circuit compares the positive analog voltage (on pin vdda) and the negative analog supply voltage (on pin vssa) and is triggered if the voltage difference exceeds a factor of two. when the supply voltage difference drops below the threshold level, the system restarts after 100 ms. example: with a symmetrical supply of 30 v, the protection circuit is triggered if the unbalance exceeds approximately 15 v; see section 13.7 . an overview is given of all protection strategies and their respective effects on the output signal in t ab le 4 . TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 11 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er [1] ampli?er gain depends on the junction temperature and heatsink size. [2] only complete shutdown of the ampli?er if short-circuit impedance is below the threshold of 1 w . in all other cases current limiting results in a clipped output signal. [3] fault condition detected during (every) transition between standby-to-mute and during a restart after activation of ocp (short-circuit to one of the supply lines). 8.4 differential audio inputs the audio inputs are fully differential ensuring a high common mode rejection ratio and maximum ?exibility in the application. ? stereo operation: it is advised to use the inputs in anti-phase and connect the speakers in anti-phase, to avoid acoustical phase differences. the construction advantages are: C minimized power supply peak current C minimized supply pumping effect, especially at low audio frequencies ? mono btl operation: it is required that the inputs are connected in anti-parallel. the output of one channel is inverted and the speaker load is connected between the two outputs of the TDA8920C. in principle, the output power to the speaker can be boosted to twice the output power of single-ended stereo. the input con?guration for a mono btl application is illustrated in figure 7 . table 4. overview of TDA8920C protection strategies protection name complete shutdown restart directly restart after 100 ms pin prot detection tfb [1] nnnn otp y n y n ocp y [2] n [2] y [2] y wp n [3] ynn uvpynyn ovp y n y n ubpynyn fig 7. input con?guration for mono btl application v in in1p out1 power stage mbl466 out2 sgnd in1m in2p in2m TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 12 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 9. limiting values 10. thermal characteristics table 5. limiting values in accordance with the absolute maximum rating system (iec 60134). symbol parameter conditions min max unit v p supply voltage non-operating mode; v dd - v ss -65v i orm repetitive peak output current maximum output current limiting 9.2 - a t stg storage temperature - 55 +150 c t amb ambient temperature - 40 +85 c t j junction temperature - 150 c v mode voltage on pin mode referenced to sgnd 0 6 v v osc voltage on pin osc 0 sgnd + 6 v v i input voltage referenced to sgnd; pin in1p; in1m; in2p and in2m - 5+5v v prot voltage on pin prot referenced to voltage on pin vssd 0 12 v v esd electrostatic discharge voltage human body model (hbm); pin vssp1 with respect to other pins - 1800 +1800 v hbm; all other pins - 2000 +2000 v machine model (mm); all pins - 200 +200 v charged device model (cdm) - 500 +500 v i q(tot) total quiescent current operating mode; no load; no ?lter; no rc-snubber network connected -75ma table 6. thermal characteristics symbol parameter conditions typ unit r th(j-a) thermal resistance from junction to ambient in free air 40 k/w r th(j-c) thermal resistance from junction to case 1.1 k/w TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 13 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 11. static characteristics [1] the circuit is dc adjusted at v p = 12.5 v to 32.5 v. [2] with respect to sgnd (0 v). [3] the transition between standby and mute mode has hysteresis, while the slope of the transition between mute and operating mo de is determined by the time-constant of the rc network on pin mode; see figure 8 . [4] dc output offset voltage is gradually applied to the output during the transition between the mute and operating modes. the slope caused by any dc output offset is determined by the time-constant of the rc network on pin mode. [5] at a junction temperature of approximately t act(th_fold) - 5 c, gain reduction commences and at a junction temperature of approximately t act(th_prot) , the ampli?er switches off. table 7. static characteristics v p = 30 v; f osc = 345 khz; t amb = 25 c; unless otherwise speci?ed. symbol parameter conditions min typ max unit supply v p supply voltage operating mode [1] 12.5 30 32.5 v v p(ovp) overvoltage protection supply voltage non-operating mode; v dd - v ss 65 - 70 v v p(uvp) undervoltage protection supply voltage v dd - v ss 20 - 25 v i q(tot) total quiescent current operating mode; no load; no ?lter; no rc-snubber network connected - 5075ma i stb standby current measured at 30 v - 480 600 m a mode select input; pin mode v mode voltage on pin mode referenced to sgnd [2] 0- 6v standby mode [2] [3] 0 - 0.8 v mute mode [2] [3] 2.2 - 3.0 v operating mode [2] [3] 4.2 - 6 v i i input current v i = 5.5 v - 110 150 m a audio inputs; pins in1m, in1p, in2p and in2m v i input voltage dc input [2] -0-v ampli?er outputs; pins out1 and out2 v o(offset) output offset voltage se; mute mode - - 25 mv se; operating mode [4] -- 150 mv btl; mute mode - - 30 mv btl; operating mode [4] -- 210 mv stabilizer output; pin stabi v o(stabi) output voltage on pin stabi mute and operating modes; with respect to vssp1 9.3 9.8 10.3 v temperature protection t act(th_prot) thermal protection activation temperature - 154 - c t act(th_fold) thermal foldback activation temperature closed loop se voltage gain reduced with 6 db [5] - 153 - c TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 14 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 12. dynamic characteristics 12.1 switching characteristics [1] when using an external oscillator, the frequency f osc(ext) (500 khz minimum, 900 khz maximum) will result in a pwm frequency f track (250 khz minimum, 450 khz maximum) due to the internal clock divider; see section 8.2 . fig 8. behavior of mode selection pin mode standby mute on 5.5 coa021 v mode (v) 4.2 3.0 2.2 0.8 0 v o (v) v o(offset)(mute) v o(offset)(on) slope is directly related to the time-constant of the rc network on the mode pin table 8. dynamic characteristics v p = 30 v; t amb = 25 c; unless otherwise speci?ed. symbol parameter conditions min typ max unit internal oscillator f osc(typ) typical oscillator frequency r osc = 30.0 k w 325 345 365 khz f osc oscillator frequency 250 - 450 khz external oscillator or frequency tracking v osc voltage on pin osc sgnd + 4.5 sgnd + 5 sgnd + 6 v v trip(osc) trip voltage on pin osc - sgnd + 2.5 - v f track tracking frequency [1] 250 - 450 khz TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 15 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 12.2 stereo and dual se application characteristics [1] r sl is the series resistance of low-pass lc ?lter inductor in the application. [2] output power is measured indirectly; based on r dson measurement; see section 13.3 . [3] thd is measured from 22 hz to 20 khz, using aes17 20 khz brickwall ?lter. maximum limit is guaranteed but may not be 100 % tested. [4] v ripple = v ripple(max) = 2 v (p-p); r s = 0 w . measured independently between vddpn and sgnd and between vsspn and sgnd. [5] 22 hz to 20 khz, using aes17 20 khz brickwall ?lter. [6] 22 hz to 22 khz, using aes17 20 khz brickwall ?lter; independent of r s . [7] p o = 1 w; r s = 0 w ; f i = 1 khz. [8] v i = v i(max) = 1 v (rms); f i = 1 khz. [9] leads and bond wires included. table 9. dynamic characteristics v p = 30 v; r l = 4 w ; f i = 1 khz; f osc = 345 khz; r sl < 0.1 w [1] ; t amb = 25 c; unless otherwise speci?ed. symbol parameter conditions min typ max unit p o output power l = 22 m h; c = 680 nf; t j =85 c [2] thd = 0.5 %; r l = 4 w -90-w thd = 10 %; r l = 4 w - 110 - w thd = 10 %; v p = 27 v - 80 - w thd total harmonic distortion p o = 1 w; f i = 1 khz [3] - 0.05 - % p o = 1 w; f i = 6 khz [3] - 0.05 - % g v(cl) closed-loop voltage gain 29 30 31 db svrr supply voltage ripple rejection between pin vddpn and sgnd operating mode; f i = 100 hz [4] -90-db operating mode; f i = 1 khz [4] -70-db mute mode; f i = 100 hz [4] -75-db standby mode; f i = 100 hz [4] - 120 - db between pin vsspn and sgnd operating mode; f i = 100 hz [4] -80-db operating mode; f i = 1 khz [4] -60-db mute mode; f i = 100 hz [4] -80-db standby mode; f i = 100 hz [4] - 115 - db z i input impedance between the input pins and sgnd 45 63 - k w v n(o) output noise voltage operating mode; r s =0 w [5] - 160 - m v mute mode [6] -85- m v a cs channel separation [7] -70-db |d g v | voltage gain difference - - 1 db a mute mute attenuation f i = 1 khz; v i = 2 v (rms) [8] -75-db cmrr common mode rejection ratio v i(cm) = 1 v (rms) - 75 - db h po output power ef?ciency se, r l = 4 w -88-% se, r l = 6 w -90-% btl, r l = 8 w -88-% r dson(hs) high-side drain-source on-state resistance [9] - 200 - m w r dson(ls) low-side drain-source on-state resistance [9] - 190 - m w TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 16 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 12.3 mono btl application characteristics [1] r sl is the series resistance of low-pass lc ?lter inductor in the application. [2] output power is measured indirectly; based on r dson measurement; see section 13.3 . [3] total harmonic distortion is measured from 22 hz to 20 khz, using an aes17 20 khz brickwall ?lter. maximum limit is guarante ed but may not be 100 % tested. [4] v ripple = v ripple(max) = 2 v (p-p); r s = 0 w . [5] 22 hz to 20 khz, using an aes17 20 khz brickwall ?lter; low noise due to bd modulation. [6] 22 hz to 20 khz, using an aes17 20 khz brickwall ?lter; independent of r s . [7] v i = v i(max) = 1 v (rms); f i = 1 khz. table 10. dynamic characteristics v p = 30 v; r l = 8 w ; f i = 1 khz; f osc = 345 khz; r sl < 0.1 w [1] ; t amb = 25 c; unless otherwise speci?ed. symbol parameter conditions min typ max unit p o output power l = 22 m h; c = 680 nf; t j =85 c [2] thd = 0.5 %; r l = 8 w - 170 - w thd = 10 %; r l = 8 w - 210 - w thd total harmonic distortion p o = 1 w; f i = 1 khz [3] - 0.05 - % p o = 1 w; f i = 6 khz [3] - 0.05 - % g v(cl) closed-loop voltage gain - 36 - db svrr supply voltage ripple rejection between pin vddpn and sgnd operating mode; f i = 100 hz [4] -80-db operating mode; f i = 1 khz [4] -80-db mute mode; f i = 100 hz [4] -95-db standby mode; f i = 100 hz [4] - 120 - db between pin vsspn and sgnd operating mode; f i = 100 hz [4] -75-db operating mode; f i = 1 khz [4] -75-db mute mode; f i = 100 hz [4] -90-db standby mode; f i = 100 hz [4] - 130 - db z i input impedance measured between the input pins and sgnd 45 63 - k w v n(o) output noise voltage operating mode; r s =0 w [5] - 190 - m v mute mode [6] -45- m v a mute mute attenuation f i = 1 khz; v i = 2 v (rms) [7] -75-db cmrr common mode rejection ratio v i(cm) = 1 v (rms) - 75 - db TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 17 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13. application information 13.1 mono btl application when using the power ampli?er in a mono btl application, the inputs of both channels must be connected in parallel and the phase of one of the inputs must be inverted; see figure 7 . in principle, the loudspeaker can be connected between the outputs of the two single-ended demodulation ?lters. 13.2 pin mode to ensure a pop noise-free start-up, an rc time-constant must be applied to pin mode. the bias-current setting of the vi-converter input is directly related to the voltage on pin mode. in turn the bias-current setting of the vi-converters is directly related to the dc output offset voltage. a slow dv/dt on pin mode results in a slow dv/dt for the dc output offset voltage, ensuring a pop noise-free start-up. a time-constant of 500 ms is suf?cient to guarantee pop noise-free start-up; see figure 4 , figure 5 and figure 8 for more information. 13.3 output power estimation 13.3.1 se maximum output power: (1) maximum output current internally limited to 9.2 a: (2) where: ? r l : load impedance ? r sl : series impedance of the ?lter coil ? r dson(hs) : high-side r dson of power stage output dmos (temperature dependent) ? f osc : oscillator frequency ? t min : minimum pulse width (typical 150 ns, temperature dependent) ? v p : single-sided supply voltage or 0.5 (v dd + | v ss | ) ? p o(0.5 %) : output power at the onset of clipping remark: note that i o(peak) should be below 9.2 a ( section 8.3.2 ). i o(peak) is the sum of the current through the load and the ripple current. the value of the ripple current is dependent on the coil inductance and voltage drop over the coil. p o 0.5 % () r l r l r dson hs () r sl ++ ---------------------------------------------------- - v p 1t min 0.5 f osc C () 2 2r l ------------------------------------------------------------------------------------------------------------------------------- -- - = i opeak () v p 1t min 0.5 f osc C () r l r dson hs () r sl ++ ------------------------------------------------------------- - = TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 18 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13.3.2 bridge-tied load (btl) maximum output power: (3) maximum output current internally limited to 9.2 a: (4) where: ? r l : load impedance ? r sl : series impedance of the ?lter coil ? r dson(hs) : high-side r dson of power stage output dmos (temperature dependent) ? r dson(ls) : low-side r dsson of power stage output dmos (temperature dependent) ? f osc : oscillator frequency ? t min : minimum pulse width (typical 150 ns, temperature dependent) ? v p : single-sided supply voltage or 0.5 (v dd + | v ss | ) ? p o(0.5 %) : output power at the onset of clipping remark: note that i o(peak) should be below 9.2 a; see section 8.3.2 . i o(peak) is the sum of the current through the load and the ripple current. the value of the ripple current is dependent on the coil inductance and voltage drop over the coil. 13.4 external clock to ensure duty cycle independent operation of the device, the external clock input frequency is internally divided by two. this implies that the external clock frequency is twice the internal clock frequency (typically 2 345 khz = 690 khz). if several class-d ampli?ers are used together it is recommended that all devices run at the same switching frequency. this can be achieved by connecting all osc pins together and feeding them from an external oscillator. when applying an external oscillator it is necessary to force pin osc to a dc level above sgnd. this disables the internal oscillator and causes the pwm to switch at half the external clock frequency. the internal oscillator requires an external resistor r osc and capacitor c osc connected between pin osc and pin vssa. the noise contribution of the internal oscillator is supply voltage dependent. an external low-noise oscillator is recommended for low-noise applications running at high supply voltages. p o 0.5 % () r l r l r dson hs () r dson ls () ++ ------------------------------------------------------------------- 2v p 1t min 0.5 f osc C () 2 2r l ------------------------------------------------------------------------------------------------------------------------------- -------------------- - = i opeak () 2v p 1t min 0.5 f osc C () r l r dson hs () r dson ls () + () 2r sl ++ ------------------------------------------------------------------------------------------ - = TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 19 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13.5 noise noise should be measured using a high-order low-pass ?lter with a cut-off frequency of 20 khz. the standard audio band-pass ?lters used in audio analyzers, do not suppress the residue of the carrier frequency suf?ciently to ensure a reliable measurement of the audible noise. noise measurements should be carried out preferably using aes17 (brickwall) ?lters or an audio precision aux 0025 ?lter (designed speci?cally for measuring class-d switching ampli?ers). 13.6 heatsink requirements in many applications it may be necessary to connect an external heatsink to the TDA8920C. equation 5 shows the relationship between the maximum power dissipation before activation of tfb and the total thermal resistance from junction to ambient. (5) power dissipation (p) is determined by the ef?ciency of the TDA8920C. the ef?ciency measured as a function of output power is given in figure 21 . power dissipation can be derived as a function of output power as shown in figure 20 . (1) r th(j-a) = 5 k/w. (2) r th(j-a) = 10 k/w. (3) r th(j-a) = 15 k/w. (4) r th(j-a) = 20 k/w. (5) r th(j-a) = 35 k/w. fig 9. derating curves for power dissipation as a function of maximum ambient temperature r th ja C () t j t amb C p ----------------------- - = p (w) 30 20 10 0 t amb ( c) (1) (2) (3) (4) (5) 0 20 100 40 60 80 mbl469 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 20 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er in the following example, a heatsink calculation is made for an 8 w btl application with a 30 v supply: the audio signal has a crest factor of 10 (the ratio between peak power and average power (20 db)), this means that the average output power is 1 10 of the peak power. thus, the peak rms output power level is the 0.5 % thd level, i.e. 170 w. the average power is then 1 10 130w=17w. the dissipated power at an output power of 17 w is approximately 5 w. when the maximum expected ambient temperature is 85 c, the total r th(j-a) becomes r th(j-a) = r th(j-c) + r th(c-h) + r th(h-a) r th(j-c) (thermal resistance from junction to case) = 1.1 k/w r th(c-h) (thermal resistance from case to heatsink) = 0.5 k/w to 1 k/w (dependent on mounting) based on this the thermal resistance between heatsink and ambient temperature is: r th(h-a) (thermal resistance from heatsink to ambient) = 11 - (1.1 + 1) = 8.9 k/w the derating curves for power dissipation (for several r th(j-a) values) are illustrated in figure 9 . a maximum junction temperature t j = 150 c is taken into account. the maximum allowable power dissipation for a given heatsink size can be derived or the required heatsink size can be determined at a required power dissipation level; see figure 9 . 13.7 output current limiting to guarantee the robustness of the TDA8920C, the maximum output current that can be delivered by the output stage is limited to 9.2 a. overcurrent protection (ocp) is built in for each output power switch. if the current ?owing through any of the power switches exceeds the 9.2 a threshold current due to, for example, a short-circuit to a supply line or across the load, the maximum output current of the ampli?er is regulated to 9.2 a. the TDA8920C ampli?er distinguishes between low-ohmic short-circuit conditions and other overcurrent conditions such as dynamic impedance drops of the loudspeakers used. the impedance threshold (z th ) depends on the supply voltage used. depending on the impedance of the short-circuit, the ampli?er reacts as follows: ? short-circuit impedance (> z th ): the maximum output current of the ampli?er is regulated to 9.2 a but the ampli?er will not shut down the pwm outputs. effectively this results in a clipped output signal across the load (behavior very similar to voltage clipping). ? short-circuit impedance (< z th ): the ampli?er limits the maximum output current to 9.2 a and at the same time discharges the capacitor on pin prot. when the voltage across this capacitor drops below the threshold voltage, the ampli?er shuts down completely and an internal timer is started. 140 85 C () 5 ------------------------- 11 k/w = TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 21 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er a typical value for the capacitor connected to pin prot can be from 10 pf to 220 pf; see figure 10 . after a ?xed time of 100 ms the ampli?er switches on. if the requested output current is still too high, the ampli?er switches off. thus the ampli?er tries to switch to the operating mode every 100 ms. the average power dissipation will be low in this situation because of the low duty cycle. if the overcurrent condition is removed, the ampli?er stays in operating mode after restarting. this fully protects the TDA8920C ampli?er against short-circuit conditions while at the same time eliminating so-called audio holes resulting from loudspeaker impedance drops. [1] overvoltage protection activation caused by supply pumping due to the weak short-circuit; see section 13.8 . 13.8 pumping effects in a typical stereo half-bridge se application the TDA8920C is supplied by a symmetrical voltage (e.g. v dd = 30 v and v ss = - 30 v). when the ampli?er is used in an se con?guration, a pumping effect can occur. during one switching interval, energy is taken from one supply (e.g. v dd ), while a part of that energy is returned to the other supply line (e.g. v ss ) and vice versa. when the voltage supply source cannot sink energy, the voltage across the output capacitors of that voltage supply source increases and the supply voltage is pumped to higher levels. the voltage increase caused by the pumping effect depends on: ? speaker impedance ? supply voltage ? audio signal frequency ? value of supply line decoupling capacitors ? source and sink currents of other channels in applications using the TDA8920C ensure pumping effects are minimized and prevent malfunctions of either the audio ampli?er and/or the voltage supply source. ampli?er malfunction due to the pumping effect can trigger uvp, ovp or ubp. the most effective solution against pumping effects is to use the TDA8920C in a mono full-bridge application. in the case of stereo half-bridge applications, adapt the power supply, for example, by increasing the values of the supply decoupling capacitors. table 11. current limiting behavior during low output impedance conditions at different values of c prot type v p (v) v i (mv, p-p) f (hz) c prot (pf) pwm output stops short (0 w ) short (0.5 w ) short (1 w ) TDA8920Cj/n1 29.5 500 20 10 yes yes ovp [1] 1000 10 yes yes no 20 15 yes yes ovp [1] 1000 15 yes no no 1000 220 no no no TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 22 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13.9 application schematics notes for the application schematic: ? connect a solid ground plane to v ss around the switching ampli?er to prevent emission ? place 100 nf capacitors as close as possible to the TDA8920C power supply pins ? internally connect the internal heat spreader of the TDA8920C to v ss ? connect the external heatsink to the ground plane ? use a thermally conductive, electrically non-conductive, sil-pad between the backside of the TDA8920C and a small external heatsink ? use differential inputs for the most effective system level audio performance with unbalanced signal sources. in case of hum due to ?oating inputs, connect the shielding or source ground to the ampli?er ground. jumpers j1 and j2 are open on set level and closed on the stand-alone demo board ? minimum total required capacitance for each power supply line is 3300 m f xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxx x x x xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xx xx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxx xxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxx x x xxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxx xxx TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 23 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er (1) value of c prot can be in the range 10 pf to 220 pf. fig 10. typical application diagram for pop noise-free start up and switch off 001aai855 c in in1p in1 + - + - in2 in1m sgnd 2 3 19 22 21 20 18 470 nf 470 nf c in c in in2p in2m 470 nf 470 nf c in 100 nf vdda vssa 17 7 v ssp vdda vssa prot 13 14 15 vssp vssp2 out2 boot2 16 vddp vddp2 vssd c vdda 100 nf c vssa 100 nf c vddp 15 nf c bo 100 nf c vssp 100 nf c vp vssp vssp vssp vddp vddp vddp + - + - 11 vssp1 8 vddp1 23 mode mode control 1 osc 6 4 n.c. 5 n.c. n.c. 100 nf c vddp 100 nf c vssp 100 nf c vp c prot (1) v ssa 12 stabi c stab 470 nf r vdda 10 w r vssa 10 w r osc 30 k w c vp 22 m f c vddp 470 m f c vssp 470 m f load l lc c lc 2 w to 3 w 10 m h 1000 nf 3 w to 6 w 15 m h 680 nf 4 w to 8 w 22 m h 470 nf 10 9 out1 boot1 15 nf c bo l lc gnd vddp vssp vssa vdda vddp vssp vssa r sn 10 w r sn 10 w single-ended output filter values c sn 220 pf c sn 220 pf c sn 220 pf c lc c lc c sn 220 pf r zo 22 w c zo 100 nf r zo 22 w c zo 100 nf TDA8920Cj l lc TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 24 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13.10 layout and grounding to obtain a high-level system performance, certain grounding techniques are essential. the input reference grounds have to be tied to their respective source grounds and must have separate tracks from the power ground tracks. this prevents the large (output) signal currents from interfering with the small ac input signals. the small-signal ground tracks should be physically located as far as possible from the power ground tracks. supply and output tracks should be as wide as possible to deliver maximum output power. fig 11. printed-circuit board layout (quasi-single-sided); component view r19 fbgnd r20, r21 ground 001aai421 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 25 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 13.11 curves measured in reference design v p = 30 v, f osc = 350 khz, 2 4 w se con?guration. (1) out2, f i = 6 khz. (2) out2, f i = 1 khz. (3) out2, f i = 100 hz. fig 12. thd as a function of output power, se con?guration with 2 4 w load v p = 30 v, f osc = 350 khz, 2 6 w se con?guration. (1) out2, f i = 6 khz. (2) out2, f i = 1 khz. (3) out2, f i = 100 hz. fig 13. thd as a function of output power, se con?guration with 2 6 w load 001aai856 10 - 1 10 - 2 1 10 thd (%) 10 - 3 p o (w) 10 - 2 10 3 10 2 10 - 1 110 (1) (2) (3) 001aai857 10 - 1 10 - 2 1 10 thd (%) 10 - 3 p o (w) 10 - 2 10 3 10 2 10 - 1 110 (2) (1) (3) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 26 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 30 v, f osc = 350 khz, 1 8 w btl con?guration. (1) f i = 6 khz. (2) f i = 1 khz. (3) f i = 100 hz. fig 14. thd as a function of output power, btl con?guration with 1 8 w load v p = 30 v, f osc = 350 khz, 2 4 w se con?guration. (1) out2, p o = 1 w. (2) out2, p o = 10 w. fig 15. thd as a function of frequency, se con?guration with 2 4 w load 001aai858 10 - 1 10 - 2 1 10 thd (%) 10 - 3 p o (w) 10 - 2 10 3 10 2 10 - 1 110 (1) (2) (3) 001aai424 10 - 1 10 - 2 1 10 thd (%) 10 - 3 f i (hz) 10 10 5 10 4 10 2 10 3 (1) (2) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 27 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 30 v, f osc = 350 khz, 2 6 w se con?guration. (1) out2, p o = 1 w. (2) out2, p o = 10 w. fig 16. thd as a function of frequency, se con?guration with 2 6 w load v p = 30 v, f osc = 350 khz, 1 8 w btl con?guration. (1) p o = 1 w. (2) p o = 10 w. fig 17. thd as a function of frequency, btl con?guration with 1 8 w load 001aai701 10 - 1 10 - 2 1 10 thd (%) 10 - 3 f i (hz) 10 10 5 10 4 10 2 10 3 (1) (2) 001aai702 10 - 1 10 - 2 1 10 thd (%) 10 - 3 f i (hz) 10 10 5 10 4 10 2 10 3 (1) (2) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 28 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 30 v, f osc = 350 khz, 2 4 w se con?guration. out1 and out2 both 1 w and 10 w respectively. fig 18. channel separation as a function of frequency, se con?guration with 2 4 w load v p = 30 v, f osc = 350 khz, 2 6 w se con?guration. out1 and out2 both 1 w and 10 w respectively. fig 19. channel separation as a function of frequency, se con?guration with 2 6 w load 001aai703 f i (hz) 10 10 5 10 4 10 2 10 3 - 60 - 40 - 80 - 20 0 a cs (db) - 100 001aai704 f i (hz) 10 10 5 10 4 10 2 10 3 - 60 - 40 - 80 - 20 0 a cs (db) - 100 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 29 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 31.5 v, f i = 1 khz, f osc = 325 khz. (1) 2 4 w se con?guration. (2) 2 6 w se con?guration. (3) 2 8 w se con?guration. fig 20. power dissipation as a function of output power per channel, se con?guration v p = 30 v, f i = 1 khz, f osc = 325 khz. (1) 2 8 w se con?guration. (2) 2 6 w se con?guration. (3) 2 4 w se con?guration. fig 21. ef?ciency as a function of output power per channel, se con?guration p o (w) 0 120 80 40 20 100 60 001aai705 20 10 30 40 p (w) 0 25 15 35 5 (1) (2) (3) p o (w) 0 120 80 40 20 100 60 001aai706 40 20 100 h (%) 0 60 80 (1) (2) (3) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 30 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er in?nite heat sink used. f i = 1 khz, f osc = 325 khz. (1) thd = 10 %, 4 w . (2) thd = 0.5 %, 4 w ; thd = 10 %, 6 w . (3) thd = 10 %, 8 w. (4) thd = 0.5 %, 6 w . (5) thd = 0.5 %, 8 w . fig 22. output power as a function of supply voltage, se con?guration in?nite heat sink used. f i = 1 khz, f osc = 325 khz. (1) thd = 10 %, 8 w . (2) thd = 0.5 %, 8 w . (3) thd = 10 %, 16 w . (4) thd = 0.5 %, 16 w . fig 23. output power as a function of supply voltage, btl con?guration v p (v) 12.5 32.5 27.5 22.5 17.5 001aai859 80 60 40 20 100 140 120 p o (w) 0 (1) (2) (3) (4) 001aai860 v p (v) 12.5 32.5 27.5 22.5 17.5 100 200 300 p o (w) 0 (1) (2) (3) (4) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 31 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 30 v, f osc = 350 khz, v i = 100 mv, r s = 0 w , c i = 330 pf. (1) 1 8 w btl con?guration. (2) 2 4 w se con?guration. (3) 2 6 w se con?guration. (4) 2 8 w se con?guration. fig 24. closed-loop voltage gain as a function of frequency, r s = 0 w , c i = 330 pf ripple on v dd , short on input pins. v p = 30 v, f osc = 350 khz, r l = 4 w, v ripple = 2 v (p-p). (1) out2, mute mode. (2) out2, operating mode. (3) out2, standby mode. fig 25. svrr as a function of ripple frequency, ripple on v dd 001aai709 f i (hz) 10 10 5 10 4 10 2 10 3 30 35 25 40 45 g v(cl) (db) 20 (1) (2) (3) (4) 001aai710 f ripple (hz) 10 10 5 10 4 10 2 10 3 - 100 - 80 - 60 - 40 - 20 svrr (db) - 140 - 120 (3) (2) (1) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 32 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er ripple on v ss , short on input pins. v p = 30 v, f osc = 350 khz, r l = 4 w , v ripple = 2 v (p-p). (1) out2, mute mode. (2) out2, operating mode. (3) out2, standby mode. fig 26. svrr as a function of ripple frequency, ripple on v ss v p = 30 v, f osc = 325 khz. (1) out1, down. (2) out1, up. fig 27. output voltage as a function of mode voltage 001aai711 f ripple (hz) 10 10 6 10 4 10 2 10 3 - 100 - 80 - 60 - 40 - 20 svrr (db) - 140 - 120 (3) (1) (2) v mode (v) 0 5 4 23 1 4.5 3.5 1.5 2.5 0.5 001aai712 10 - 4 10 - 5 10 - 3 10 - 2 10 - 1 10 1 v o (v) 10 - 6 (1) (2) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 33 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er v p = 30 v, f osc = 325 khz, v i = 2 v (rms). (1) out2, 8 w . (2) out2, 6 w . (3) out2, 0 w . fig 28. mute attenuation as a function of frequency 001aai713 f i (hz) 10 10 5 10 4 10 2 10 3 - 70 - 80 - 60 - 50 a mute (db) - 90 (1) (2) (3) TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 34 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 14. package outline fig 29. package outline sot411-1 (dbs23p) unit a 2 references outline version european projection issue date iec jedec jeita mm 4.6 4.3 a 4 1.15 0.85 a 5 1.65 1.35 dimensions (mm are the original dimensions) note 1. plastic or metal protrusions of 0.25 mm maximum per side are not included. sot411-1 98-02-20 02-04-24 0 5 10 mm scale d l l 1 l 2 e 2 e c a 4 a 5 a 2 m l 3 e 1 q w m b p 1 d z e 2 e e 123 j dbs23p: plastic dil-bent-sil power package; 23 leads (straight lead length 3.2 mm) sot411-1 v m d x h e h non-concave view b : mounting base side b b e 1 b p cd (1) e (1) z (1) de d h ll 3 m 0.75 0.60 0.55 0.35 30.4 29.9 28.0 27.5 12 2.54 12.2 11.8 10.15 9.85 1.27 e 2 5.08 2.4 1.6 e h 6 e 1 14 13 l 1 10.7 9.9 l 2 6.2 5.8 e 2 1.43 0.78 2.1 1.8 1.85 1.65 4.3 3.6 2.8 q j 0.25 w 0.6 v 0.03 x 45 b TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 35 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er fig 30. package outline sot566-3 (hsop24) unit a 4 (1) references outline version european projection issue date 03-02-18 03-07-23 iec jedec jeita mm + 0.08 - 0.04 3.5 0.35 dimensions (mm are the original dimensions) notes 1. limits per individual lead. 2. plastic or metal protrusions of 0.25 mm maximum per side are not included. sot566-3 0 5 10 mm scale hsop24: plastic, heatsink small outline package; 24 leads; low stand-off height sot566-3 a max. detail x a 2 3.5 3.2 d 2 1.1 0.9 h e 14.5 13.9 l p 1.1 0.8 q 1.7 1.5 2.7 2.2 v 0.25 w 0.25 yz 8 0 q 0.07 x 0.03 d 1 13.0 12.6 e 1 6.2 5.8 e 2 2.9 2.5 b p c 0.32 0.23 e 1 d (2) 16.0 15.8 e (2) 11.1 10.9 0.53 0.40 a 3 a 4 a 2 (a 3 ) l p q a q d y x h e e c v m a x a b p w m z d 1 d 2 e 2 e 1 e 24 13 1 12 pin 1 index TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 36 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 15. soldering of smd packages this text provides a very brief insight into a complex technology. a more in-depth account of soldering ics can be found in application note an10365 surface mount re?ow soldering description . 15.1 introduction to soldering soldering is one of the most common methods through which packages are attached to printed circuit boards (pcbs), to form electrical circuits. the soldered joint provides both the mechanical and the electrical connection. there is no single soldering method that is ideal for all ic packages. wave soldering is often preferred when through-hole and surface mount devices (smds) are mixed on one printed wiring board; however, it is not suitable for ?ne pitch smds. re?ow soldering is ideal for the small pitches and high densities that come with increased miniaturization. 15.2 wave and re?ow soldering wave soldering is a joining technology in which the joints are made by solder coming from a standing wave of liquid solder. the wave soldering process is suitable for the following: ? through-hole components ? leaded or leadless smds, which are glued to the surface of the printed circuit board not all smds can be wave soldered. packages with solder balls, and some leadless packages which have solder lands underneath the body, cannot be wave soldered. also, leaded smds with leads having a pitch smaller than ~0.6 mm cannot be wave soldered, due to an increased probability of bridging. the re?ow soldering process involves applying solder paste to a board, followed by component placement and exposure to a temperature pro?le. leaded packages, packages with solder balls, and leadless packages are all re?ow solderable. key characteristics in both wave and re?ow soldering are: ? board speci?cations, including the board ?nish, solder masks and vias ? package footprints, including solder thieves and orientation ? the moisture sensitivity level of the packages ? package placement ? inspection and repair ? lead-free soldering versus snpb soldering 15.3 wave soldering key characteristics in wave soldering are: ? process issues, such as application of adhesive and ?ux, clinching of leads, board transport, the solder wave parameters, and the time during which components are exposed to the wave ? solder bath speci?cations, including temperature and impurities TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 37 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 15.4 re?ow soldering key characteristics in re?ow soldering are: ? lead-free versus snpb soldering; note that a lead-free re?ow process usually leads to higher minimum peak temperatures (see figure 31 ) than a snpb process, thus reducing the process window ? solder paste printing issues including smearing, release, and adjusting the process window for a mix of large and small components on one board ? re?ow temperature pro?le; this pro?le includes preheat, re?ow (in which the board is heated to the peak temperature) and cooling down. it is imperative that the peak temperature is high enough for the solder to make reliable solder joints (a solder paste characteristic). in addition, the peak temperature must be low enough that the packages and/or boards are not damaged. the peak temperature of the package depends on package thickness and volume and is classi?ed in accordance with t ab le 12 and 13 moisture sensitivity precautions, as indicated on the packing, must be respected at all times. studies have shown that small packages reach higher temperatures during re?ow soldering, see figure 31 . table 12. snpb eutectic process (from j-std-020c) package thickness (mm) package re?ow temperature ( c) volume (mm 3 ) < 350 3 350 < 2.5 235 220 3 2.5 220 220 table 13. lead-free process (from j-std-020c) package thickness (mm) package re?ow temperature ( c) volume (mm 3 ) < 350 350 to 2000 > 2000 < 1.6 260 260 260 1.6 to 2.5 260 250 245 > 2.5 250 245 245 TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 38 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er for further information on temperature pro?les, refer to application note an10365 surface mount re?ow soldering description . 16. revision history msl: moisture sensitivity level fig 31. temperature pro?les for large and small components 001aac844 temperature time minimum peak temperature = minimum soldering temperature maximum peak temperature = msl limit, damage level peak temperature table 14. revision history document id release date data sheet status change notice supersedes TDA8920C_1 20080929 preliminary data sheet - - TDA8920C_1 ? nxp b.v. 2008. all rights reserved. preliminary data sheet rev. 01 29 september 2008 39 of 40 nxp semiconductors TDA8920C 2 110 w class-d power ampli?er 17. legal information 17.1 data sheet status [1] please consult the most recently issued document before initiating or completing a design. [2] the term short data sheet is explained in section de?nitions. [3] the product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple dev ices. the latest product status information is available on the internet at url http://www .nxp .com . 17.2 de?nitions draft the document is a draft version only. the content is still under internal review and subject to formal approval, which may result in modi?cations or additions. nxp semiconductors does not give any representations or warranties as to the accuracy or completeness of information included herein and shall have no liability for the consequences of use of such information. short data sheet a short data sheet is an extract from a full data sheet with the same product type number(s) and title. a short data sheet is intended for quick reference only and should not be relied upon to contain detailed and full information. for detailed and full information see the relevant full data sheet, which is available on request via the local nxp semiconductors sales of?ce. in case of any inconsistency or con?ict with the short data sheet, the full data sheet shall prevail. 17.3 disclaimers general information in this document is believed to be accurate and reliable. however, nxp semiconductors does not give any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information. right to make changes nxp semiconductors reserves the right to make changes to information published in this document, including without limitation speci?cations and product descriptions, at any time and without notice. this document supersedes and replaces all information supplied prior to the publication hereof. suitability for use nxp semiconductors products are not designed, authorized or warranted to be suitable for use in medical, military, aircraft, space or life support equipment, nor in applications where failure or malfunction of an nxp semiconductors product can reasonably be expected to result in personal injury, death or severe property or environmental damage. nxp semiconductors accepts no liability for inclusion and/or use of nxp semiconductors products in such equipment or applications and therefore such inclusion and/or use is at the customers own risk. applications applications that are described herein for any of these products are for illustrative purposes only. nxp semiconductors makes no representation or warranty that such applications will be suitable for the speci?ed use without further testing or modi?cation. limiting values stress above one or more limiting values (as de?ned in the absolute maximum ratings system of iec 60134) may cause permanent damage to the device. limiting values are stress ratings only and operation of the device at these or any other conditions above those given in the characteristics sections of this document is not implied. exposure to limiting values for extended periods may affect device reliability. terms and conditions of sale nxp semiconductors products are sold subject to the general terms and conditions of commercial sale, as published at http://www .nxp .com/pro? le/ter ms , including those pertaining to warranty, intellectual property rights infringement and limitation of liability, unless explicitly otherwise agreed to in writing by nxp semiconductors. in case of any inconsistency or con?ict between information in this document and such terms and conditions, the latter will prevail. no offer to sell or license nothing in this document may be interpreted or construed as an offer to sell products that is open for acceptance or the grant, conveyance or implication of any license under any copyrights, patents or other industrial or intellectual property rights. quick reference data the quick reference data is an extract of the product data given in the limiting values and characteristics sections of this document, and as such is not complete, exhaustive or legally binding. 17.4 trademarks notice: all referenced brands, product names, service names and trademarks are the property of their respective owners. 18. contact information for more information, please visit: http://www .nxp.com for sales of?ce addresses, please send an email to: salesad dresses@nxp.com document status [1] [2] product status [3] de?nition objective [short] data sheet development this document contains data from the objective speci?cation for product development. preliminary [short] data sheet quali?cation this document contains data from the preliminary speci?cation. product [short] data sheet production this document contains the product speci?cation. nxp semiconductors TDA8920C 2 110 w class-d power ampli?er ? nxp b.v. 2008. all rights reserved. for more information, please visit: http://www.nxp.com for sales office addresses, please send an email to: salesaddresses@nxp.com date of release: 29 september 2008 document identifier: TDA8920C_1 please be aware that important notices concerning this document and the product(s) described herein, have been included in section legal information. 19. contents 1 general description . . . . . . . . . . . . . . . . . . . . . . 1 2 features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 3 applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 4 quick reference data . . . . . . . . . . . . . . . . . . . . . 2 5 ordering information . . . . . . . . . . . . . . . . . . . . . 2 6 block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 3 7 pinning information . . . . . . . . . . . . . . . . . . . . . . 4 7.1 pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 7.2 pin description . . . . . . . . . . . . . . . . . . . . . . . . . 5 8 functional description . . . . . . . . . . . . . . . . . . . 5 8.1 general . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 8.2 pulse-width modulation frequency . . . . . . . . . . 8 8.3 protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 8.3.1 thermal protection . . . . . . . . . . . . . . . . . . . . . . 8 8.3.1.1 thermal foldback (tfb) . . . . . . . . . . . . . . . . . 8 8.3.1.2 overtemperature protection (otp) . . . . . . . . . 9 8.3.2 overcurrent protection (ocp) . . . . . . . . . . . . . 9 8.3.3 window protection (wp). . . . . . . . . . . . . . . . . 10 8.3.4 supply voltage protection . . . . . . . . . . . . . . . . 10 8.4 differential audio inputs . . . . . . . . . . . . . . . . . 11 9 limiting values. . . . . . . . . . . . . . . . . . . . . . . . . 12 10 thermal characteristics. . . . . . . . . . . . . . . . . . 12 11 static characteristics. . . . . . . . . . . . . . . . . . . . 13 12 dynamic characteristics . . . . . . . . . . . . . . . . . 14 12.1 switching characteristics . . . . . . . . . . . . . . . . 14 12.2 stereo and dual se application characteristics. . . . . . . . . . . . . . . . . . . . . . . . . 15 12.3 mono btl application characteristics . . . . . . . 16 13 application information. . . . . . . . . . . . . . . . . . 17 13.1 mono btl application . . . . . . . . . . . . . . . . . . . 17 13.2 pin mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 13.3 output power estimation. . . . . . . . . . . . . . . . . 17 13.3.1 se . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 13.3.2 bridge-tied load (btl) . . . . . . . . . . . . . . . . . 18 13.4 external clock . . . . . . . . . . . . . . . . . . . . . . . . . 18 13.5 noise. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 13.6 heatsink requirements . . . . . . . . . . . . . . . . . . 19 13.7 output current limiting. . . . . . . . . . . . . . . . . . . 20 13.8 pumping effects . . . . . . . . . . . . . . . . . . . . . . . 21 13.9 application schematics . . . . . . . . . . . . . . . . . . 22 13.10 layout and grounding . . . . . . . . . . . . . . . . . . . 24 13.11 curves measured in reference design . . . . . . 25 14 package outline . . . . . . . . . . . . . . . . . . . . . . . . 34 15 soldering of smd packages . . . . . . . . . . . . . . 36 15.1 introduction to soldering . . . . . . . . . . . . . . . . . 36 15.2 wave and re?ow soldering . . . . . . . . . . . . . . . 36 15.3 wave soldering. . . . . . . . . . . . . . . . . . . . . . . . 36 15.4 re?ow soldering. . . . . . . . . . . . . . . . . . . . . . . 37 16 revision history . . . . . . . . . . . . . . . . . . . . . . . 38 17 legal information . . . . . . . . . . . . . . . . . . . . . . 39 17.1 data sheet status . . . . . . . . . . . . . . . . . . . . . . 39 17.2 de?nitions . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 17.3 disclaimers. . . . . . . . . . . . . . . . . . . . . . . . . . . 39 17.4 trademarks . . . . . . . . . . . . . . . . . . . . . . . . . . 39 18 contact information . . . . . . . . . . . . . . . . . . . . 39 19 contents. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 |
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