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| TS4997 2 x 1W differential input stereo audio amplifier with programmable 3D effects Features QFN16 4x4mm Operating range from VCC= 2.7V to 5.5V 1W output power per channel @ VCC=5V, THD+N=1%, RL=8 Ultra low standby consumption: 10nA typ. 80dB PSRR @ 217Hz with grounded inputs High SNR: 106dB(A) typ. Fast startup time: 45ms typ. Pop&click-free circuit Dedicated standby pin per channel Lead-free QFN16 4x4mm package 3D0 3D1 BYP VCC 16 15 14 Pin connections (top view) Applications 13 Cellular mobile phones Notebook and PDA computers LCD monitors and TVs Portable audio devices LINLIN+ RIN+ RIN1 2 3 4 12 LOUT11 LOUT+ 10 ROUT+ 9 ROUT- Description The TS4997 is designed for top-class stereo audio applications. Thanks to its compact and power-dissipation efficient QFN16 package with exposed pad, it suits a variety of applications. With a BTL configuration, this audio power amplifier is capable of delivering 1W per channel of continuous RMS output power into an 8 load @ 5V. 3D effects enhancement is programmed through a two digital input pin interface that allows more flexibility on each output audio sound channel. 5 6 7 8 GND GND STBYR STBYL Each output channel (left and right), also has its own external controlled standby mode pin to reduce the supply current to less than 10nA per channel. The device also features an internal thermal shutdown protection. The gain of each channel can be configured by external gain setting resistors. February 2007 Rev 2 1/34 www.st.com 34 Contents TS4997 Contents 1 2 3 4 Typical application schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 4.11 4.12 4.13 4.14 General description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Differential configuration principle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Gain in typical application schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Common mode feedback loop limitations . . . . . . . . . . . . . . . . . . . . . . . . . 21 Low frequency response . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 3D effect enhancement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Power dissipation and efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Footprint recommendation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Decoupling of the circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Standby control and wake-up time tWU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Shutdown time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Pop performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Single-ended input configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Notes on PSRR measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 5 6 7 QFN16 package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 2/34 TS4997 Typical application schematics 1 Typical application schematics Figure 1 shows a typical application for the TS4997 with a gain of +6dB set by the input resistors. Figure 1. Typical application schematics VCC 3D0 Control 3D1 Control Cs 1uF 16 15 TS4997 - QFN16 Diff. input LP1 330nF 24k 1 Cin2 P2 2 Diff. input L+ 330nF 24k LI N+ LI N- Cin1 Rin1 3D0 3D1 13 Vcc Optional LEFT LOUT- 12 Left Speaker Rin2 3D EFFECT RIGHT + + LOUT+ 11 8 Ohms Diff. input RP3 Cin3 Rin3 4 RIN- ROUT- 9 Right Speaker 330nF 24k 3 RIN+ ROUT+ 10 8 Ohms Cin4 P4 Rin4 Bypass Diff. input R+ 330nF 24k 14 BIAS STBYL STBY STBYR GND GND 5 6 8 1uF Cb STBYL Control Table 1. External component descriptions Functional description Input resistors that set the closed loop gain in conjunction with a fixed internal feedback resistor (Gain = Rfeed/RIN, where Rfeed = 50k). Input coupling capacitors that block the DC voltage at the amplifier input terminal. Thanks to common mode feedback, these input capacitors are optional. However, if they are added, they form with RIN a 1st order high pass filter with -3dB cut-off frequency (fcut-off = 1 / (2 x x RIN x CIN)). Supply bypass capacitors that provides power supply filtering. Bypass pin capacitor that provides half supply filtering. Components RIN CIN CS CB STBYR Control 7 3/34 Absolute maximum ratings TS4997 2 Absolute maximum ratings Table 2. Symbol VCC Vi Toper Tstg Tj Rthja Pd ESD ESD Supply voltage (1) Input voltage (2) Absolute maximum ratings Parameter Value 6 GND to VCC -40 to + 85 -65 to +150 150 120 Internally limited 2 1.5 200 200 kV V mA Unit V V C C C C/W Operating free air temperature range Storage temperature Maximum junction temperature Thermal resistance junction to ambient Power dissipation Human body model (3) Digital pins STBYL, STBYR, 3D0, 3D1 Machine model Latch-up immunity 1. All voltage values are measured with respect to the ground pin. 2. The magnitude of the input signal must never exceed VCC + 0.3V / GND - 0.3V. 3. All voltage values are measured from each pin with respect to supplies. Table 3. Symbol VCC VICM VIL VIH VSTBY RL Operating conditions Parameter Supply voltage Common mode input voltage range 3D0 - 3D1 maximum low input voltage 3D0 - 3D1 minimum high input voltage Standby voltage input: Device ON Device OFF Load resistor Value 2.7 to 5.5 GND to VCC - 1V 0.4 1.3 1.3 VSTBY VCC GND VSTBY 0.4 4 1 150 45 85 Unit V V V V V M C C/W ROUT/GND Output resistor to GND (VSTBY = GND) TSD Rthja 1. 2. Thermal shutdown temperature Thermal resistance junction to ambient QFN16(1) QFN16(2) When mounted on a 4-layer PCB with vias. When mounted on a 2-layer PCB with vias. 4/34 TS4997 Electrical characteristics 3 Table 4. Symbol ICC ISTBY Voo Po THD + N Electrical characteristics VCC = +5V, GND = 0V, Tamb = 25C (unless otherwise specified) Parameter Supply current No input signal, no load, left and right channel active Standby current (1) No input signal, VSTBYL = GND, VSTBYR = GND, RL = 8 Output offset voltage No input signal, RL = 8 Output power THD = 1% Max, F = 1kHz, RL = 8 Total harmonic distortion + noise Po = 700mWrms, G = 6dB, RL = 8, 20Hz F 20kHz Power supply rejection ratio(2), inputs grounded RL = 8, G = 6dB, Cb = 1F, Vripple = 200mVpp, 3D effect off F = 217Hz F = 1kHz Common mode rejection ratio(3) RL = 8, G = 6dB, Cb = 1F, Vincm = 200mVpp, 3D effect off F = 217Hz F = 1kHz SNR Signal-to-noise ratio A-weighted, G = 6dB, Cb = 1F, RL = 8, 3D effect off (THD + N 0.5%, 20Hz < F < 20kHz) , Channel separation, RL = 8 G = 6dB, 3D effect off F = 1kHz F = 20Hz to 20kHz Output voltage noise, F = 20Hz to 20kHz, RL = 8, G=6dB Cb = 1F, 3D effect off Unweighted A-weighted Gain value (RIN in k) Wake-up time (Cb = 1F) Standby time (Cb = 1F) Phase margin at unity gain , RL = 8 CL = 500pF , Gain margin, RL = 8 CL = 500pF Gain bandwidth product, RL = 8 40k --------------R IN Min. Typ. 7.4 10 1 Max. 9.6 2000 35 Unit mA nA mV mW % 800 1000 0.5 PSRR 80 75 dB CMRR 57 57 dB 108 dB Crosstalk 105 80 dB VN 15 10 50k --------------R IN Vrms Gain tWU tSTBY M GM GBP 60k --------------R IN V/V ms s Degrees dB MHz 46 10 65 15 1.5 1. Standby mode is active when VSTBY is tied to GND. 2. Dynamic measurements - 20*log(rms(Vout)/rms(Vripple)). Vripple is the sinusoidal signal superimposed upon VCC. 3. Dynamic measurements - 20*log(rms(Vout)/rms(Vincm)). 5/34 Electrical characteristics TS4997 Table 5. Symbol ICC ISTBY Voo Po THD + N VCC = +3.3V, GND = 0V, Tamb = 25C (unless otherwise specified) Parameter Supply current No input signal, no load, left and right channel active Standby current (1) No input signal, VSTBYL = GND, VSTBYR = GND, RL = 8 Output offset voltage No input signal, RL = 8 Output power THD = 1% Max, F = 1kHz, RL = 8 Total harmonic distortion + noise Po = 300mWrms, G = 6dB, RL = 8, 20Hz F 20kHz Power supply rejection ratio(2), inputs grounded RL = 8, G = 6dB, Cb = 1F, Vripple = 200mVpp, 3D effect off F = 217Hz F = 1kHz Common mode rejection ratio(3) RL = 8, G = 6dB, Cb = 1F, Vincm = 200mVpp, 3D effect off F = 217Hz F = 1kHz 57 57 370 Min. Typ. 6.6 10 1 460 0.5 Max. 8.6 2000 35 Unit mA nA mV mW % PSRR 80 75 dB CMRR dB SNR Signal-to-noise ratio A-weighted, G = 6dB, Cb = 1F, RL = 8, 3D effect off (THD + N 0.5%, 20Hz < F < 20kHz) , Channel separation, RL = 8 G = 6dB, 3D effect off F = 1kHz F = 20Hz to 20kHz Output voltage noise, F = 20Hz to 20kHz, RL = 8, G=6dB Cb = 1F, 3D effect off Unweighted A-weighted Gain value (RIN in k) Wake-up time (Cb = 1F) Standby time (Cb = 1F) Phase margin at unity gain , RL = 8 CL = 500pF Gain margin , RL = 8 CL = 500pF Gain bandwidth product RL = 8 40k --------------R IN 104 dB Crosstalk 105 80 dB VN 15 10 50k --------------R IN Vrms Gain tWU tSTBY M GM GBP 60k --------------R IN V/V ms s Degrees dB MHz 47 10 65 15 1.5 1. Standby mode is active when VSTBY is tied to GND. 2. Dynamic measurements - 20*log(rms(Vout)/rms(Vripple)). Vripple is the sinusoidal signal superimposed upon VCC. 3. Dynamic measurements - 20*log(rms(Vout)/rms(Vincm)). 6/34 TS4997 Electrical characteristics Table 6. Symbol ICC ISTBY Voo Po THD + N VCC = +2.7V, GND = 0V, Tamb = 25C (unless otherwise specified) Parameter Supply current No input signal, no load, left and right channel active Standby current (1) No input signal, VSTBYL = GND, VSTBYR = GND, RL = 8 Output offset voltage No input signal, RL = 8 Output power THD = 1% Max, F = 1kHz, RL = 8 Total harmonic distortion + noise Po = 200mWrms, G = 6dB, RL = 8, 20Hz F 20kHz Power supply rejection ratio(2), inputs grounded RL = 8, G = 6dB, Cb = 1F, Vripple = 200mVpp, 3D effect off F = 217Hz F = 1kHz Common mode rejection ratio(3) RL = 8, G = 6dB, Cb = 1F, Vincm = 200mVpp, 3D effect off F = 217Hz F = 1kHz 57 57 220 Min. Typ. 6.2 10 1 295 0.5 Max. 8.1 2000 35 Unit mA nA mV mW % PSRR 76 73 dB CMRR dB SNR Signal-to-noise ratio A-weighted, G = 6dB, Cb = 1F, RL = 8, 3D effect off (THD + N 0.5%, 20Hz < F < 20kHz) , Channel separation, RL = 8 G = 6dB, 3D effect off F = 1kHz F = 20Hz to 20kHz Output voltage noise, F = 20Hz to 20kHz, RL = 8, G=6dB Cb = 1F, 3D effect off Unweighted A-weighted Gain value (RIN in k) Wake-up time (Cb = 1F) Standby time (Cb = 1F) Phase margin at unity gain , RL = 8 CL = 500pF Gain margin , RL = 8 CL = 500pF Gain bandwidth product RL = 8 40k --------------R IN 102 dB Crosstalk 105 80 dB VN 15 10 50k --------------R IN Vrms Gain tWU tSTBY M GM GBP 60k --------------R IN V/V ms s Degrees dB MHz 46 10 65 15 1.5 1. Standby mode is active when VSTBY is tied to GND. 2. Dynamic measurements - 20*log(rms(Vout)/rms(Vripple)). Vripple is the sinusoidal signal superimposed upon VCC. 3. Dynamic measurements - 20*log(rms(Vout)/rms(Vincm)). 7/34 Electrical characteristics Table 7. Index of graphics Description THD+N vs. output power THD+N vs. frequency PSRR vs. frequency PSRR vs. common mode input voltage CMRR vs. frequency CMRR vs. common mode input voltage Crosstalk vs. frequency SNR vs. power supply voltage Differential DC output voltage vs. common mode input voltage Current consumption vs. power supply voltage Current consumption vs. standby voltage Standby current vs. power supply voltage Frequency response Output power vs. load resistance Output power vs. power supply voltage Power dissipation vs. output power Power derating curves Figure Figure 2 to 13 Figure 14 to 19 Figure 20 to 28 Figure 29 Figure 30 to 35 Figure 36 Figure 37 to 39 Figure 40 to 45 Figure 46 to 48 Figure 49 Figure 50 to 52 Figure 53 Figure 54 to 56 Figure 57 Figure 58 to 59 Figure 60 to 62 Figure 63 TS4997 Page page 9 to page 10 page 11 page 12 to page 13 page 13 page 13 to page 14 page 14 page 14 to page 15 page 15 to page 16 page 16 page 16 page 17 page 17 page 17 to page 18 page 18 page 18 page 18 to page 19 page 19 8/34 TS4997 Electrical characteristics Figure 2. 10 THD+N vs. output power Figure 3. 10 THD+N vs. output power Vcc=2.7V THD + N (%) THD + N (%) RL = 4 G = +6dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V RL = 4 G = +12dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V 0.1 0.1 0.01 1E-3 0.01 0.1 Output power (W) 1 0.01 1E-3 0.01 0.1 Output power (W) 1 Figure 4. 10 THD+N vs. output power Figure 5. 10 THD+N vs. output power Vcc=2.7V 0.1 THD + N (%) THD + N (%) RL = 8 G = +6dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V RL = 8 G = +12dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V 0.1 0.01 1E-3 0.01 0.1 Output power (W) 1 0.01 1E-3 0.01 0.1 Output power (W) 1 Figure 6. 10 THD+N vs. output power Figure 7. 10 THD+N vs. output power THD + N (%) Vcc=2.7V 0.1 THD + N (%) RL = 16 G = +6dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V RL = 16 G = +12dB F = 1kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V 0.1 0.01 1E-3 0.01 0.1 1 0.01 1E-3 0.01 0.1 1 Output power (W) Output power (W) 9/34 Electrical characteristics TS4997 Figure 8. 10 THD+N vs. output power Figure 9. 10 THD+N vs. output power THD + N (%) Vcc=2.7V THD + N (%) RL = 4 G = +6dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V RL = 4 G = +12dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V 0.1 0.1 0.01 1E-3 0.01 0.1 Output power (W) 1 0.01 1E-3 0.01 0.1 Output power (W) 1 Figure 10. THD+N vs. output power 10 RL = 8 G = +6dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Figure 11. THD+N vs. output power 10 RL = 8 G = +12dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Vcc=3.3V THD + N (%) THD + N (%) Vcc=3.3V Vcc=2.7V 0.1 Vcc=2.7V 0.1 0.01 1E-3 0.01 0.1 Output power (W) 1 0.01 1E-3 0.01 0.1 Output power (W) 1 Figure 12. THD+N vs. output power 10 RL = 16 G = +6dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V Figure 13. THD+N vs. output power 10 RL = 16 G = +12dB F = 10kHz Cb = 1F 1 BW < 125kHz Tamb = 25C Vcc=5V THD + N (%) THD + N (%) Vcc=3.3V Vcc=3.3V Vcc=2.7V 0.1 Vcc=2.7V 0.1 0.01 1E-3 0.01 0.1 1 0.01 1E-3 0.01 0.1 1 Output power (W) Output power (W) 10/34 TS4997 Electrical characteristics Figure 14. THD+N vs. frequency 10 RL = 4 G = +6dB Cb = 1F BW < 125kHz Tamb = 25C Figure 15. THD+N vs. frequency 10 RL = 4 G = +12dB Cb = 1F BW < 125kHz Tamb = 25C Vcc=5V Pout=950mW 1 THD + N (%) Vcc=5V Pout=950mW Vcc=3.3V Pout=430mW 1 THD + N (%) Vcc=3.3V Pout=430mW 0.1 0.1 Vcc=2.7V Pout=260mW Vcc=2.7V Pout=260mW 0.01 100 1000 Frequency (Hz) 10000 0.01 100 1000 Frequency (Hz) 10000 Figure 16. THD+N vs. frequency 10 RL = 8 G = +6dB Cb = 1F BW < 125kHz 1 Tamb = 25C Figure 17. THD+N vs. frequency 10 RL = 8 G = +12dB Cb = 1F BW < 125kHz Tamb = 25C Vcc=5V Pout=700mW 1 THD + N (%) Vcc=5V Pout=700mW Vcc=3.3V Pout=300mW Vcc=2.7V Pout=200mW THD + N (%) Vcc=3.3V Pout=300mW Vcc=2.7V Pout=200mW 0.1 0.1 0.01 100 1000 Frequency (Hz) 10000 0.01 100 1000 Frequency (Hz) 10000 Figure 18. THD+N vs. frequency 10 RL = 16 G = +6dB Cb = 1F BW < 125kHz 1 Tamb = 25C Figure 19. THD+N vs. frequency 10 RL = 16 G = +12dB Cb = 1F BW < 125kHz 1 Tamb = 25C Vcc=5V Pout=450mW THD + N (%) Vcc=5V Pout=450mW Vcc=3.3V Pout=200mW Vcc=2.7V Pout=120mW THD + N (%) Vcc=3.3V Pout=200mW Vcc=2.7V Pout=120mW 0.1 0.1 0.01 100 1000 Frequency (Hz) 10000 0.01 100 1000 Frequency (Hz) 10000 11/34 Electrical characteristics TS4997 Figure 20. PSRR vs. frequency 0 -10 -20 -30 PSRR (dB) Figure 21. PSRR vs. frequency 0 Vcc = 5V Vripple = 200mVpp G = +12dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C 3D MEDIUM -50 -60 -70 -80 3D OFF 3D LOW 3D MEDIUM 3D LOW -50 -60 -70 -80 -90 -100 100 1000 Frequency (Hz) PSRR (dB) -40 Vcc = 5V Vripple = 200mVpp G = +6dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C -10 -20 3D HIGH -30 -40 3D HIGH 3D OFF 10000 -90 -100 100 1000 10000 Frequency (Hz) Figure 22. PSRR vs. frequency 0 -10 -20 -30 PSRR (dB) Figure 23. PSRR vs. frequency 0 Vcc = 3.3V Vripple = 200mVpp G = +6dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C 3D MEDIUM -50 -60 -70 -80 -90 3D OFF 3D OFF 100 1000 Frequency (Hz) Vcc = 5V Vripple = 200mVpp Cb = 1F Inputs Floating Tamb = 25C 3D MEDIUM -10 -20 3D HIGH PSRR (dB) -30 -40 3D HIGH -40 -50 -60 -70 -80 -90 -100 100 1000 Frequency (Hz) 3D LOW 3D LOW 10000 -100 10000 Figure 24. PSRR vs. frequency 0 -10 -20 -30 PSRR (dB) Figure 25. PSRR vs. frequency 0 Vcc = 3.3V Vripple = 200mVpp Cb = 1F Inputs Floating Tamb = 25C 3D MEDIUM -50 -60 -70 -80 3D OFF -90 10000 -100 3D OFF 100 1000 Frequency (Hz) 3D MEDIUM 3D LOW -50 -60 -70 -80 -90 -100 100 1000 Frequency (Hz) PSRR (dB) -40 Vcc = 3.3V Vripple = 200mVpp G = +12dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C -10 -20 3D HIGH -30 -40 3D HIGH 3D LOW 10000 12/34 TS4997 Electrical characteristics Figure 26. PSRR vs. frequency 0 -10 -20 -30 PSRR (dB) Figure 27. PSRR vs. frequency 0 Vcc = 2.7V Vripple = 200mVpp G = +12dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C 3D MEDIUM 3D LOW 3D MEDIUM 3D LOW -50 -60 -70 -80 -90 -100 100 1000 Frequency (Hz) PSRR (dB) -40 Vcc = 2.7V Vripple = 200mVpp G = +6dB Cb = 1F, Cin = 4.7F Inputs Grounded Tamb = 25C -10 -20 3D HIGH -30 -40 -50 -60 -70 -80 3D OFF 10000 -90 -100 3D HIGH 3D OFF 100 1000 Frequency (Hz) 10000 Figure 28. PSRR vs. frequency Figure 29. PSRR vs. common mode input voltage 0 Vripple = 200mVpp F = 217Hz, G = +6dB Cb = 1F, RL 8 3D Effect OFF Tamb = 25C 0 -10 -20 -30 PSRR (dB) Vcc = 2.7V Vripple = 200mVpp Cb = 1F Inputs Floating Tamb = 25C 3D MEDIUM -10 -20 3D HIGH PSRR (dB) -30 -40 -50 -60 -70 -80 -40 -50 -60 -70 -80 -90 -100 3D OFF 100 1000 Frequency (Hz) 3D LOW Vcc=2.7V Vcc=3.3V Vcc=5V 10000 -90 0 1 2 3 4 5 Common Mode Input Voltage (V) Figure 30. CMRR vs. frequency 0 -10 -20 CMRR (dB) Figure 31. CMRR vs. frequency 0 Vcc = 5V RL 8 G = +12dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW -40 -50 -60 3D OFF -70 3D OFF 100 1000 Frequency (Hz) -30 -40 -50 -60 -70 CMRR (dB) Vcc = 5V RL 8 G = +6dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW 3D MEDIUM -10 -20 3D HIGH -30 3D HIGH 3D MEDIUM 100 1000 Frequency (Hz) 10000 10000 13/34 Electrical characteristics TS4997 Figure 32. CMRR vs. frequency 0 -10 -20 CMRR (dB) Figure 33. CMRR vs. frequency 0 Vcc = 3.3V RL 8 G = +12dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW -40 -50 -60 3D OFF -70 3D OFF 100 1000 Frequency (Hz) -30 -40 -50 -60 -70 3D HIGH CMRR (dB) Vcc = 3.3V RL 8 G = +6dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW 3D MEDIUM -10 -20 -30 3D HIGH 3D MEDIUM 100 1000 Frequency (Hz) 10000 10000 Figure 34. CMRR vs. frequency 0 -10 -20 CMRR (dB) Figure 35. CMRR vs. frequency 0 Vcc = 2.7V RL 8 G = +12dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW -40 -50 -60 3D OFF -70 3D OFF 100 1000 Frequency (Hz) CMRR (dB) -30 -40 -50 -60 -70 Vcc = 2.7V RL 8 G = +6dB Vic = 200mVpp Cb = 1F, Cin = 4.7F Tamb = 25C 3D LOW 3D MEDIUM -10 -20 3DHIGH -30 3D HIGH 3D MEDIUM 100 1000 Frequency (Hz) 10000 10000 Figure 36. CMRR vs. common mode input voltage 20 10 0 -10 CMRR (dB) Figure 37. Crosstalk vs. frequency 0 Crosstalk Level (dB) Vripple = 200mVpp F = 217Hz, G = +6dB Cb = 1F, RL 8 3D Effect OFF Tamb = 25C -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 4 5 RL = 4 G = +6dB Cin = 1F, Cb = 1F 3D Effect OFF Tamb = 25C -20 -30 -40 -50 -60 -70 -80 0 1 2 Vcc=2.7V Vcc=3.3V Vcc=5V Vcc=3.3V Vcc=2.7V Vcc=5V 3 100 1000 Frequency (Hz) 10000 Common Mode Input Voltage (V) 14/34 TS4997 Electrical characteristics Figure 38. Crosstalk vs. frequency 0 -10 -20 Crosstalk Level (dB) Figure 39. Crosstalk vs. frequency 0 RL = 16 G = +6dB Cin = 1F, Cb = 1F 3D Effect OFF Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V -40 -50 -60 -70 -80 -90 -100 -110 -120 Crosstalk Level (dB) -30 RL = 8 G = +6dB Cin = 1F, Cb = 1F 3D Effect OFF Tamb = 25C Vcc=5V Vcc=3.3V Vcc=2.7V -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 100 1000 Frequency (Hz) 10000 100 1000 Frequency (Hz) 10000 Figure 40. SNR vs. power supply voltage 110 108 3D OFF 106 104 102 100 3D LOW 98 96 94 92 90 88 86 3D HIGH 84 82 80 2.5 3.0 Figure 41. SNR vs. power supply voltage 110 108 3D OFF 106 104 102 3D LOW 100 98 96 94 92 3D MIDDLE 90 3D HIGH 88 86 84 82 80 2.5 3.0 3.5 4.0 Singnal to Noise Ratio (dB) 3D MEDIUM A - Weighted filter F = 1kHz G = +6dB, RL = 4 THD + N < 0.5% Tamb = 25C 3.5 4.0 4.5 5.0 5.5 Singnal to Noise Ratio (dB) A - weighted filter F = 1kHz G = +6dB ,RL = 8 THD + N < 0.5% Tamb = 25C 4.5 5.0 5.5 Supply Voltage (V) Supply Voltage (V) Figure 42. SNR vs. power supply voltage 110 108 3D OFF 106 104 102 3D LOW 100 98 96 94 92 3D MIDDLE 90 3D HIGH 88 86 84 82 80 2.5 3.0 3.5 4.0 Figure 43. SNR vs. power supply voltage 110 108 106 3D OFF 104 102 100 98 3D LOW 96 94 92 90 88 86 84 3D HIGH 82 80 78 76 2.5 3.0 Singnal to Noise Ratio (dB) Singnal to Noise Ratio (dB) 3D MEDIUM A - Weighted filter F = 1kHz G = +6dB ,RL = 16 THD + N < 0.5% Tamb = 25C 4.5 5.0 5.5 Unweighted filter (20Hz to 20kHz) F = 1kHz G = +6dB, RL = 4 THD + N < 0.5% Tamb = 25C 3.5 4.0 4.5 5.0 5.5 Supply Voltage (V) Supply Voltage (V) 15/34 Electrical characteristics TS4997 Figure 44. SNR vs. power supply voltage 110 108 3D OFF 106 104 102 100 3D LOW 98 96 94 92 90 88 86 3D HIGH 84 82 80 2.5 3.0 Figure 45. SNR vs. power supply voltage 110 108 3D OFF 106 104 102 100 3D LOW 98 96 94 92 90 88 3D HIGH 86 84 82 80 2.5 3.0 Singnal to Noise Ratio (dB) Singnal to Noise Ratio (dB) 3D MEDIUM 3D MEDIUM Unweighted filter (20Hz to 20kHz) F = 1kHz G = +6dB, RL = 8 THD + N < 0.5% Tamb = 25C 3.5 4.0 4.5 5.0 5.5 Unweighted filter (20Hz to 20kHz) F = 1kHz G = +6dB, RL = 16 THD + N < 0.5% Tamb = 25C 3.5 4.0 4.5 5.0 5.5 Supply Voltage (V) Supply Voltage (V) Figure 46. Differential DC output voltage vs. common mode input voltage 1000 Vcc = 5V G = +6dB Tamb = 25C 100 3D MEDIUM 10 |Voo| (mV) Figure 47. Differential DC output voltage vs. common mode input voltage 1000 Vcc = 3.3V G = +6dB Tamb = 25C 100 3D MEDIUM 10 |Voo| (mV) 3D HIGH 3D LOW 3D HIGH 3D LOW 1 0.1 0.01 1E-3 1 0.1 0.01 1E-3 0.0 3D OFF 3D OFF 0 1 2 3 4 5 0.5 1.0 1.5 2.0 2.5 3.0 Common Mode Input Voltage (V) Common Mode Input Voltage (V) Figure 48. Differential DC output voltage vs. common mode input voltage 1000 Vcc = 2.7V G = +6dB Tamb = 25C 100 10 |Voo| (mV) Figure 49. Current consumption vs. power supply voltage 8 7 Current Consumption (mA) No load Tamb = 25C 6 5 4 3 2 1 One channel active Both channels active 3D HIGH 3D MEDIUM 3D LOW 1 0.1 3D OFF 0.01 1E-3 0.0 0.5 1.0 1.5 2.0 2.5 0 0 1 2 3 4 5 Common Mode Input Voltage (V) Power Supply Voltage (V) 16/34 TS4997 Electrical characteristics Figure 50. Current consumption vs. standby voltage 8 7 Current Consumption (mA) Figure 51. Current consumption vs. standby voltage 7 6 6 5 4 3 2 1 0 0 1 2 Both channels active Current Consumption (mA) 5 4 3 Both channels active One channel active One channel active 2 1 0 0.0 Vcc = 3.3V No load Tamb = 25C 0.5 1.0 1.5 2.0 2.5 3.0 Vcc = 5V No load Tamb = 25C 3 4 5 Standby Voltage (V) Standby Voltage (V) Figure 52. Current consumption vs. standby voltage 7 6 Current Consumption (mA) Figure 53. Standby current vs. power supply voltage 1.0 No load 0.9 Tamb = 25C 0.8 Both channels active 4 3 One channel active 2 1 0 0.0 Vcc = 2.7V No load Tamb = 25C 0.5 1.0 1.5 2.0 2.5 Standby Current (nA) 5 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 0 1 2 3 4 5 Standby Voltage (V) Power Supply Voltage (V) Figure 54. Frequency response 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Cin=4.7F, Rin=12k Figure 55. Frequency response 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Cin=4.7F, Rin=12k Cin=680nF, Rin=12k Cin=4.7F, Rin=24k Vcc = 5V Po = 700mW 3D Effect OFF ZL = 8 + 500pF Tamb = 25C 10000 20k Gain (dB) Cin=680nF, Rin=12k Cin=4.7F, Rin=24k Vcc = 3.3V Po = 300mW 3D Effect OFF ZL = 8 + 500pF Tamb = 25C 10000 20k Gain (dB) Cin=330nF, Rin=24k Cin=330nF, Rin=24k 20 100 1000 Frequency (Hz) 20 100 1000 Frequency (Hz) 17/34 Electrical characteristics TS4997 Figure 56. Frequency response 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Cin=4.7F, Rin=12k Figure 57. Output power vs. load resistance 1800 1600 1400 Output power (mW) Vcc=5.5V Vcc=5V Vcc=4.5V Vcc=4V Vcc=3.3V Cin=680nF, Rin=12k Cin=4.7F, Rin=24k Vcc = 2.7V Po = 200mW 3D Effect OFF ZL = 8 + 500pF Tamb = 25C 10000 20k 1200 1000 800 THD+N = 1% F = 1kHz Cb = 1F BW < 125kHz Tamb = 25C Gain (dB) Vcc=3V 600 400 200 0 4 Vcc=2.7V 8 12 16 20 24 28 32 Cin=330nF, Rin=24k 20 100 1000 Frequency (Hz) Load Resistance () Figure 58. Output power vs. power supply voltage 1800 F = 1kHz Cb = 1F BW < 125 kHz Tamb = 25C Figure 59. Output power vs. power supply voltage 2200 Output power at 10% THD + N (mW) Output power at 1% THD + N (mW) 1600 1400 1200 1000 800 600 400 200 2000 1800 1600 1400 1200 1000 800 600 400 200 RL=4 F = 1kHz Cb = 1F BW < 125 kHz Tamb = 25C RL=4 RL=8 RL=16 RL=32 3.0 3.5 4.0 Vcc (V) RL=8 RL=16 RL=32 3.0 3.5 4.0 Vcc (V) 0 2.5 4.5 5.0 5.5 0 2.5 4.5 5.0 5.5 Figure 60. Power dissipation vs. output power Figure 61. Power dissipation vs. output power 1500 1400 1300 1200 1100 1000 900 800 700 600 500 400 300 200 100 0 600 550 500 RL=4 RL=8 Power Dissipation (mW) Power Dissipation (mW) 450 400 350 300 250 200 150 100 50 0 0 100 200 300 400 RL=16 RL=8 RL=4 RL=16 Vcc = 5V F = 1kHz THD+N < 1% 0 200 400 600 800 1000 1200 1400 1600 Vcc = 3.3V F = 1kHz THD+N < 1% 500 600 700 Output Power (mW) Output Power (mW) 18/34 TS4997 Electrical characteristics Figure 62. Power dissipation vs. output power Figure 63. Power derating curves 400 QFN16 Package Power Dissipation (W) 350 Power Dissipation (mW) 300 250 200 150 RL=16 100 50 0 0 50 100 150 200 250 300 RL=8 RL=4 Vcc = 2.7V F = 1kHz THD+N < 1% 350 400 450 3.0 2.8 2.6 2.4 2.2 2.0 1.8 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0.0 Mounted on 4-layer PCB with vias Mounted on 2-layer PCB with vias No Heat sink -AMR value 0 25 50 75 100 125 150 Output Power (mW) Ambiant Temperature (C) Table 8. Output noise, Tamb = 25C Unweighted filter 3D effect level (20Hz to 20kHz) VCC = 2.7V to 5.5V A-weighted filter VCC = 2.7V to 5.5V 6Vrms 12Vrms 15Vrms 22Vrms 10Vrms 19Vrms 24Vrms 35Vrms 14Vrms 26Vrms 33Vrms 48Vrms Conditions Inputs floating Inputs floating Inputs floating Inputs floating Inputs grounded, G=6dB Inputs grounded, G=6dB Inputs grounded, G=6dB Inputs grounded, G=6dB Inputs grounded, G=12dB Inputs grounded, G=12dB Inputs grounded, G=12dB Inputs grounded, G=12dB OFF LOW MEDIUM HIGH OFF LOW MEDIUM HIGH OFF LOW MEDIUM HIGH 10Vrms 18Vrms 24Vrms 34Vrms 15Vrms 28Vrms 36Vrms 52Vrms 20Vrms 39Vrms 50Vrms 71Vrms 19/34 Application information TS4997 4 4.1 Application information General description The TS4997 integrates two monolithic full-differential input/output power amplifiers with two selectable standby pins dedicated for each channel. The gain of each channel is set by external input resistors. The TS4997 also features 3D effect enhancements that can be programmed through a two digital input pin interface that allows changing 3D effect levels in three steps. 4.2 Differential configuration principle The TS4997 also includes a common mode feedback loop that controls the output bias value to average it at VCC/2 for any DC common mode input voltage. This allows maximum output voltage swing, and therefore, to maximize the output power. Moreover, as the load is connected differentially instead of single-ended, output power is four times higher for the same power supply voltage. The advantages of a full-differential amplifier are: High PSRR (power supply rejection ratio), High common mode noise rejection, Virtually no pops&clicks without additional circuitry, giving a faster startup time compared to conventional single-ended input amplifiers, Easier interfacing with differential output audio DAC, No input coupling capacitors required due to common mode feedback loop. In theory, the filtering of the internal bias by an external bypass capacitor is not necessary. However, to reach maximum performance in all tolerance situations, it is recommended to keep this option. The only constraint is that the differential function is directly linked to external resistor mismatching, therefore you must pay particular attention to this mismatching in order to obtain the best performance from the amplifier. 4.3 Gain in typical application schematic A typical differential application is shown in Figure 1 on page 3. The value of the differential gain of each amplifier is dependent on the values of external input resistors RIN1 to RIN4 and of integrated feedback resistors with fixed value. In the flat region of the frequency-response curve (no CIN effect), the differential gain of each channel is expressed by the relation given in Equation 1. Equation 1 AV diff R feed V O+ - V O= ----------------------------------------------------- = ------------- = 50k ------------Diff input+ - Diff inputR IN R IN where RIN = RIN1 = RIN2 = RIN3 = RIN4 expressed in k and Rfeed = 50k (value of internal feedback resistors). 20/34 TS4997 Application information Due to the tolerance on the internal 50k feedback resistors, the differential gain will be in the range (no tolerance on RIN): 40k ------------- A V 60k ------------diff R IN R IN The difference of resistance between input resistors of each channel have direct influence on the PSRR, CMRR and other amplifier parameters. In order to reach maximum performance, we recommend matching the input resistors RIN1, RIN2, RIN3, and RIN4 with a maximum tolerance of 1%. Note: For the rest of this section, Avdiff will be called AV to simplify the mathematical expressions. 4.4 Common mode feedback loop limitations As explained previously, the common mode feedback loop allows the output DC bias voltage to be averaged at VCC/2 for any DC common mode bias input voltage. Due to the VICM limitation of the input stage (see Table 3 on page 4), the common mode feedback loop can fulfil its role only within the defined range. This range depends upon the values of VCC, RIN and Rfeed (AV). To have a good estimation of the VICM value, use the following formula: Equation 2 V CC x R IN + 2 x V ic x 50k V CC x R IN + 2 x V ic x R feed V ICM = -------------------------------------------------------------------------- = -------------------------------------------------------------------------- ( V ) 2 x ( R IN + R feed ) 2 x ( R IN + 50k) with VCC in volts, RIN in k and Diff input+ + Diff inputV ic = -----------------------------------------------------2 (V) The result of the calculation must be in the range: GND V ICM V CC - 1V Due to the +/-20% tolerance on the 50k feedback resistors Rfeed (no tolerance on RIN), it is also important to check that the VICM remains in this range at the tolerance limits: V CC x R IN + 2 x V ic x 60k V CC x R IN + 2 x V ic x 40k ------------------------------------------------------------------------- V ICM ------------------------------------------------------------------------- ( V ) 2 x ( R IN + 40k) 2 x ( R IN + 60k) If the result of the VICM calculation is not in this range, an input coupling capacitor must be used. Example: VCC = 2.7V, AV = 2, and Vic = 2.2V. With internal resistors Rfeed = 50k, calculated external resistors are RIN = Rfeed/AV = 25k , VCC = 2.7V and Vic = 2.2V, which gives VICM = 1.92V. Taking into account the tolerance on the feedback resistors, with Rfeed = 40k the common mode input voltage is VICM = 1.87V and with Rfeed = 60k it is VICM = 1.95V. , These values are not in range from GND to VCC - 1V = 1.7V, therefore input coupling capacitors are required. Alternatively, you can change the Vic value. 21/34 Application information TS4997 4.5 Low frequency response The input coupling capacitors block the DC part of the input signal at the amplifier inputs. In the low frequency region, CIN starts to have an effect. CIN and RIN form a first-order high pass filter with a -3dB cut-off frequency. 1 F CL = ---------------------------------------------- ( Hz ) 2 x x R IN x C IN with RIN expressed in and CIN expressed in F. So, for a desired -3dB cut-off frequency we can calculate CIN: 1 C IN = ----------------------------------------------- ( F ) 2 x x R IN x F CL From Figure 64, you can easily establish the CIN value required for a -3 dB cut-off frequency for some typical cases. Figure 64. -3dB lower cut-off frequency vs. input capacitance Tamb=25C Low -3dB Cut Off Frequency (Hz) 100 Rin=6.2k G~18dB Rin=12k G~12dB 10 Rin=24k G~6dB 0.2 0.4 0.6 0.8 1 0.1 Input Capacitor Cin (F) 4.6 3D effect enhancement The TS4997 features 3D audio effect which can be programmed at three discrete levels (LOW, MEDIUM, HIGH) through input pins 3D1 and 3D0 which provide a digital interface. The correspondence between the logic levels of this interface and 3D effect levels are shown in Table 9. The 3D audio effect applied to stereo audio signals evokes perception of spatial hearing and improves this effect in cases where the stereo speakers are too close to each other, such as in small handheld devices, or mobile equipment. The perceived amount of 3D effect is also dependent on many factors such as speaker position, distance between speakers and listener, frequency spectrum of audio signal, or difference of signal between left and right channel. In some cases, the volume can increase when switching on the 3D effect. This factor is dependent on the composition of the stereo audio signal and its frequency spectrum. 22/34 TS4997 Table 9. 3D effect settings 3D effect level OFF LOW MEDIUM HIGH 3D0 0 0 1 1 Application information 3D1 0 1 0 1 4.7 Power dissipation and efficiency Assumptions: Load voltage and current are sinusoidal (Vout and Iout) Supply voltage is a pure DC source (VCC) The output voltage is: V out = V peak sint (V) and V out I out = ------------ (A) RL and V peak 2 P out = -------------------- (W) 2R L Therefore, the average current delivered by the supply voltage is: Equation 3 V peak I ccAVG = 2 ---------------- (A) R L The power delivered by the supply voltage is: Equation 4 Psupply = VCC IccAVG (W) Therefore, the power dissipated by each amplifier is: Pdiss = Psupply - Pout (W) 2 2V CC P diss = ---------------------- P out - P out ( W ) RL 23/34 Application information and the maximum value is obtained when: Pdiss -------------------- = 0 P out TS4997 and its value is: Equation 5 Pdiss max = 2 Vcc2 2RL (W) Note: This maximum value is only dependent on the power supply voltage and load values. The efficiency is the ratio between the output power and the power supply: Equation 6 P out V peak = ------------------ = -------------------P supply 4Vcc The maximum theoretical value is reached when Vpeak = VCC, so: = - = 78.5% ---4 The TS4997 is stereo amplifier so it has two power amplifiers. Each amplifier produces heat due to its power dissipation. Therefore, the maximum die temperature is the sum of each amplifier's maximum power dissipation. It is calculated as follows: Pdiss 1 = Power dissipation of left channel power amplifier Pdiss 2 = Power dissipation of right channel power amplifier Total Pdiss =Pdiss 1 + Pdiss 2 (W) In most cases, Pdiss 1 = Pdiss 2, giving: 4 2V CC TotalP diss = 2 x P diss1 = ---------------------- P out - 2P out ( W ) RL The maximum die temperature allowable for the TS4997 is 150C. In case of overheating, a thermal shutdown protection set to 150C, puts the TS4997 in standby until the temperature of the die is reduced by about 5C. To calculate the maximum ambient temperature Tamb allowable, you need to know: the power supply voltage value, VCC the load resistor value, RL the package type, RTHJA Example: VCC=5V, RL=8, RTHJAQFN16=85C/W (with 2-layer PCB with vias). Using the power dissipation formula given in Equation 5, the maximum dissipated power per channel is: Pdissmax = 633mW And the power dissipated by both channels is: Total Pdissmax = 2 x Pdissmax = 1266mW 24/34 TS4997 Tamb is calculated as follows: Equation 7 T amb = 150 C - R TJHA x TotalPdissmax Application information Therefore, the maximum allowable value for Tamb is: Tamb = 150 - 85 x 2 x 1.266=42.4C If a 4-layer PCB with vias is used, RTHJAQFN16 = 45C/W and the maximum allowable value for Tamb in this case is: Tamb = 150 - 45 x 2 x 1.266 = 93C 4.8 Footprint recommendation Footprint soldering pad dimensions are given in Figure 72 on page 31. As discussed in the previous section, the maximum allowable value for ambient temperature is dependent on the thermal resistance junction to ambient RTHJA. Decreasing the RTHJA value causes better power dissipation. Based on best thermal performance, it is recommended to use 4-layer PCBs with vias to effectively remove heat from the device. It is also recommended to use vias for 2-layer PCBs to connect the package exposed pad to heatsink cooper areas placed on another layer. For proper thermal conductivity, the vias must be plated through and solder-filled. Typical thermal vias have the following dimensions: 1.2mm pitch, 0.3mm diameter. Figure 65. QFN16 footprint recommendation 4.9 Decoupling of the circuit Two capacitors are needed to correctly bypass the TS4997: a power supply bypass capacitor CS and a bias voltage bypass capacitor Cb. 25/34 Application information TS4997 The CS capacitor has particular influence on the THD+N at high frequencies (above 7kHz) and an indirect influence on power supply disturbances. With a value for CS of 1F, one can expect THD+N performance similar to that shown in the datasheet. In the high frequency region, if CS is lower than 1F, then THD+N increases and disturbances on the power supply rail are less filtered. On the other hand, if CS is greater than 1F, then those disturbances on the power supply rail are more filtered. The Cb capacitor has an influence on the THD+N at lower frequencies, but also impacts PSRR performance (with grounded input and in the lower frequency region). 4.10 Standby control and wake-up time tWU The TS4997 has two dedicated standby pins (STBYL, STBYR). These pins allow to put each channel in standby mode or active mode independently. The amplifier is designed to reach close to zero pop when switching from one mode to the other. When both channels are in standby (VSTBYL = VSTBYR = GND), the circuit is in shutdown mode. When at least one of the two standby pins is released to put the device ON, the bypass capacitor Cb starts to be charged. Because Cb is directly linked to the bias of the amplifier, the bias will not work properly until the Cb voltage is correct. The time to reach this voltage is called the wake-up time or tWU and is specified in Table 4 on page 5, with Cb=1F. During the wake-up phase, the TS4997 gain is close to zero. After the wake-up time, the gain is released and set to its nominal value. If Cb has a value different from 1F, then refer to the graph in Figure 66 to establish the corresponding wake-up time. When a channel is set to standby mode, the outputs of this channel are in high impedance state. Figure 66. Typical startup time vs. bypass capacitor 100 90 Startup Time (ms) Tamb=25C Vcc=2.7V Vcc=3.3V 80 70 60 50 40 30 0.0 Vcc=5V 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Bypass Capacitor Cb (F) 4.0 4.5 26/34 TS4997 Application information 4.11 Shutdown time When the standby command is activated (both channels put into standby mode), the time required to put the two output stages of each channel in high impedance and the internal circuitry in shutdown mode is a few microseconds. Note: In shutdown mode when both channels are in standby, the Bypass pin and LIN+, LIN-, RIN+, RIN- pins are shorted to ground by internal switches. This allows a quick discharge of Cb and CIN capacitors. 4.12 Pop performance Due to its fully differential structure, the pop performance of the TS4997 is close to perfect. However, due to mismatching between internal resistors Rfeed, external resistors RIN and external input capacitors CIN, some noise might remain at startup. To eliminate the effect of mismatched components, the TS4997 includes pop reduction circuitry. With this circuitry, the TS4997 is close to zero pop for all possible common applications. In addition, when the TS4997 is in standby mode, due to the high impedance output stage in this configuration, no pop is heard. 4.13 Single-ended input configuration It is possible to use the TS4997 in a single-ended input configuration. However, input coupling capacitors are needed in this configuration. The schematic diagram in Figure 67 shows an example of this configuration for a gain of +6dB set by the input resistors. 27/34 Application information Figure 67. Typical single-ended input application VCC TS4997 3D0 Control 3D1 Control Cs 1uF 16 15 TS4997 - QFN16 Diff. input LP1 330nF 24k 1 Cin2 Rin2 2 330nF 24k LI N+ LI N- Cin1 Rin1 3D0 3D1 13 Vcc LEFT LOUT- 12 Left Speaker 3D EFFECT RIGHT + + LOUT+ 11 8 Ohms Diff. input RP2 Cin3 Rin3 4 RIN- ROUT- 9 Right Speaker 330nF 24k 3 RIN+ ROUT+ 10 8 Ohms Cin4 Rin4 Bypass 330nF 24k 14 BIAS STBYL STBY STBYR GND GND 5 6 8 1uF Cb STBYL Control The component calculations remain the same for the gain. In single-ended input configuration, the formula is: V O+ - V OR feed 50k Av SE = ------------------------- = ------------- = ------------Ve R IN R IN with RIN expressed in k . 4.14 Notes on PSRR measurement What is the PSRR? The PSRR is the power supply rejection ratio. The PSRR of a device is the ratio between a power supply disturbance and the result on the output. In other words, the PSRR is the ability of a device to minimize the impact of power supply disturbance to the output. How is the PSRR measured? The PSRR is measured as shown in Figure 68. 28/34 STBYR Control 7 TS4997 Figure 68. PSRR measurement Application information Vripple 3D0 Control 3D1 Control Vcc 16 15 TS4997 - QFN16 Cin1 Rin1 3D0 4.7uF 1 Cin2 Rin2 2 4.7uF LI N+ LI N- 3D1 13 Vcc LEFT LOUT- 12 RL 8Ohms 3D EFFECT RIGHT + + LOUT+ 11 Cin3 Rin3 4 RIN- ROUT- 9 RL 8Ohms 4.7uF 3 Cin4 Rin4 RIN+ ROUT+ 10 Bypass 4.7uF 14 BIAS STBYL STBY STBYR GND GND 5 6 8 1uF Cb STBYL Control Principles of operation The DC voltage supply (VCC) is fixed The AC sinusoidal ripple voltage (Vripple) is fixed No bypass capacitor CS is used The PSRR value for each frequency is calculated as: RMS ( Output ) PSRR = 20 x Log --------------------------------- ( dB ) RMS ( Vripple ) RMS is an rms selective measurement. STBYR Control 7 29/34 QFN16 package information TS4997 5 QFN16 package information In order to meet environmental requirements, STMicroelectronics offers these devices in ECOPACK(R) packages. These packages have a Lead-free second level interconnect. The category of second level interconnect is marked on the package and on the inner box label, in compliance with JEDEC Standard JESD97. The maximum ratings related to soldering conditions are also marked on the inner box label. ECOPACK is an STMicroelectronics trademark. ECOPACK specifications are available at: www.st.com. Figure 69. QFN16 package Figure 70. Pinout (top view) 3D0 3D1 BYP VCC 16 15 14 13 LINLIN+ RIN+ RIN- 1 2 3 4 12 LOUT11 LOUT+ 10 ROUT+ 9 ROUT- 5 6 7 8 GND GND STBYR STBYL 30/34 TS4997 Figure 71. QFN16 4x4mm QFN16 package information Dimensions Millimeters (mm) Ref Min A A1 A3 b D 0.18 3.85 2.1 3.85 2.1 0.65 0.2 0.30 0.11 0.40 0.50 4.0 0.8 Typ 0.9 0.02 0.20 0.25 4.0 0.30 4.15 2.6 4.15 2.6 Max 1.0 0.05 * D2 E E2 * The Exposed Pad is connected to Ground. e K L r Figure 72. Footprint soldering pad Footprint data Ref A B C D E F mm 4.2 4.2 0.65 0.35 0.65 2.70 31/34 Ordering information TS4997 6 Ordering information Table 10. Order codes Temperature range -40C, +85C Package QFN16 4x4mm Packaging Tape & reel Marking Q997 Part number TS4997IQT 32/34 TS4997 Revision history 7 Revision history Date 10-Jan-2007 20-Feb-2007 Revision 1 2 Preliminary data. First release. Changes 33/34 TS4997 Please Read Carefully: Information in this document is provided solely in connection with ST products. STMicroelectronics NV and its subsidiaries ("ST") reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any time, without notice. All ST products are sold pursuant to ST's terms and conditions of sale. Purchasers are solely responsible for the choice, selection and use of the ST products and services described herein, and ST assumes no liability whatsoever relating to the choice, selection or use of the ST products and services described herein. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted under this document. If any part of this document refers to any third party products or services it shall not be deemed a license grant by ST for the use of such third party products or services, or any intellectual property contained therein or considered as a warranty covering the use in any manner whatsoever of such third party products or services or any intellectual property contained therein. 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Resale of ST products with provisions different from the statements and/or technical features set forth in this document shall immediately void any warranty granted by ST for the ST product or service described herein and shall not create or extend in any manner whatsoever, any liability of ST. ST and the ST logo are trademarks or registered trademarks of ST in various countries. Information in this document supersedes and replaces all information previously supplied. The ST logo is a registered trademark of STMicroelectronics. All other names are the property of their respective owners. (c) 2007 STMicroelectronics - All rights reserved STMicroelectronics group of companies Australia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of America www.st.com 34/34 |
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