TS4994FC 1.2 W differential input/output audio power amplifier with selectable standby Features TS4994EIJT - Flip-chip (9 bumps) ■ Differential inputs ■ Near-zero pop & click ■ 100dB PSRR @ 217Hz with grounded inputs ■ Operating range from VCC = 2.5V to 5.5V ■ 1.2W rail-to-rail output power @ VCC = 5V, THD = 1%, F = 1kHz, with 8Ω load ■ 90dB CMRR @ 217Hz ■ Ultra-low consumption in standby mode (10nA) ■ Selectable standby mode (active low or active high) ■ Ultra fast startup time: 15ms typ. ■ Available in 9-bump flip-chip (300mm bump diameter) ■ Lead-free package Gnd VO- 7 6 5 VO+ Bypass 8 9 4 Stdby 1 2 3 VIN- VIN+ VCC Stdby Mode The device is equipped with common mode feedback circuitry allowing outputs to be always biased at VCC/2 regardless of the input common mode voltage. Description The TS4994 is an audio power amplifier capable of delivering 1W of continuous RMS output power into an 8Ω load @ 5V. Due to its differential inputs, it exhibits outstanding noise immunity. An external standby mode control reduces the supply current to less than 10nA. An STBY MODE pin allows the standby to be active HIGH or LOW. An internal thermal shutdown protection is also provided, making the device capable of sustaining short-circuits. The TS4994 is designed for high quality audio applications such as mobile phones and requires few external components. Applications ■ Mobile phones (cellular / cordless) ■ Laptop / notebook computers ■ PDAs ■ Portable audio devices Order codes Part number Temperature range Package Packaging -40°C, +85°C FC9 with back coating Tape & reel TS4994EIKJT TS4994EIJT December 2006 Lead free flip-chip9 Rev 2 Marking A94 A94 1/35 www.st.com 35 Contents TS4994FC Contents 1 Application component information . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2 Absolute maximum ratings and operating conditions . . . . . . . . . . . . . 4 3 Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4 Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 4.1 Differential configuration principle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 4.2 Gain in typical application schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 4.3 Common mode feedback loop limitations . . . . . . . . . . . . . . . . . . . . . . . . . 23 4.4 Low and high frequency response . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 4.5 Calculating the influence of mismatching on PSRR performance . . . . . . 25 4.6 CMRR performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 4.7 Power dissipation and efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 4.8 Decoupling of the circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 4.9 Wake-up time: tWU 4.10 Shutdown time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 4.11 Pop performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 4.12 Single-ended input configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 5 Package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 6 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 2/35 TS4994FC Application component information Components Functional description Cs Supply bypass capacitor that provides power supply filtering. Cb Bypass capacitor that provides half supply filtering. Rfeed Feedback resistor that sets the closed loop gain in conjunction with Rin AV = closed loop gain = Rfeed/Rin. Rin Inverting input resistor that sets the closed loop gain in conjunction with Rfeed. Cin Optional input capacitor making a high pass filter together with Rin. (FCL = 1/(2πRinCin). Typical application VCC Rfeed1 20k 2 Cs 1u GND VCC + Diff. input - Cin1 220nF 20k Cin2 Rin2 + GND Rin1 220nF 20k Diff. Input + Optional + Figure 1. + 1 Application component information 3 Vin- - 1 Vin+ + Vo+ 5 Vo7 8 Ohms 8 Bypass Bias Cb 1u Standby Mode Stdby GND 4 6 GND 9 GND TS4994IJ Rfeed2 20k GNDVCC GNDVCC 3/35 Absolute maximum ratings and operating conditions TS4994FC 2 Absolute maximum ratings and operating conditions Table 1. Absolute maximum ratings Symbol VCC Vi Parameter Supply voltage (1) Input voltage (2) Value Unit 6 V GND to VCC V Toper Operating free air temperature range -40 to + 85 °C Tstg Storage temperature -65 to +150 °C 150 °C 250 °C/W internally limited W 2 kV Machine model 200 V Latch-up immunity 200 mA Lead temperature (soldering, 10sec) 260 °C Value Unit Tj Maximum junction temperature Rthja Thermal resistance junction to ambient Pdiss Power dissipation (3) Human body model ESD 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. The device is protected by a thermal shutdown active at 150°C. Table 2. Operating conditions Symbol Parameter VCC Supply voltage 2.5 to 5.5 V VSM Standby mode voltage input: Standby active LOW Standby active HIGH VSM=GND VSM=VCC V 1.5 ≤ VSTBY ≤ VCC GND ≤ VSTBY≤ 0.4 (1) V VSTBY Standby voltage input: Device ON (VSM = GND) or device OFF (VSM = VCC) Device OFF (VSM = GND) or device ON (VSM = VCC) TSD Thermal shutdown temperature 150 °C RL Load resistor ≥4 Ω Thermal resistance junction to ambient 100 °C/W Rthja 1. The minimum current consumption (ISTBY) is guaranteed when VSTBY = GND or VCC (i.e. supply rails) for the whole temperature range. 4/35 TS4994FC Electrical characteristics 3 Electrical characteristics Table 3. Electrical characteristics for VCC = +5V, GND = 0V, Tamb = 25°C (unless otherwise specified) Symbol ICC ISTBY Voo Parameter Min. Typ. Max. Unit Supply current No input signal, no load 4 7 mA Standby current No input signal, VSTBY = VSM = GND, RL = 8Ω No input signal, VSTBY = VSM = VCC, RL = 8Ω 10 1000 nA Differential output offset voltage No input signal, RL = 8Ω 0.1 10 mV VCC - 0.9 V VICM Input common mode voltage CMRR ≤ -60dB 0.6 Pout Output power THD = 1% Max, F= 1kHz, RL = 8Ω 0.8 1.2 W THD + N Total harmonic distortion + noise Pout = 850mW rms, AV = 1, 20Hz ≤ F ≤ 20kHz, RL = 8Ω 0.5 % PSRRIG Power supply rejection ratio with inputs grounded(1) F = 217Hz, R = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vripple = 200mVPP 100 dB CMRR Common mode rejection ratio F = 217Hz, RL = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vic = 200mVPP 90 dB SNR Signal-to-noise ratio (A-weighted filter, AV = 2.5) RL = 8Ω, THD +N < 0.7%, 20Hz ≤ F ≤ 20kHz 100 dB GBP Gain bandwidth product RL = 8Ω 2 MHz VN Output voltage noise, 20Hz ≤ F ≤ 20kHz, RL = 8Ω Unweighted, AV = 1 A-weighted, AV = 1 Unweighted, AV = 2.5 A-weighted, AV = 2.5 Unweighted, AV = 7.5 A-weighted, AV = 7.5 Unweighted, Standby A-weighted, Standby tWU Wake-up time(2) Cb =1μF 6 5.5 12 10.5 33 28 1.5 1 15 μVRMS ms 1. Dynamic measurements - 20*log(rms(Vout)/rms (Vripple)). Vripple is the super-imposed sinus signal relative to VCC. 2. Transition time from standby mode to fully operational amplifier. 5/35 Electrical characteristics Table 4. Electrical characteristics for VCC = +3.3V (all electrical values are guaranteed with correlation measurements at 2.6V and 5V), GND = 0V, Tamb = 25°C (unless otherwise specified) Symbol ICC ISTBY Voo TS4994FC Parameter Min. Typ. Max. Unit Supply current no input signal, no load 3 7 mA Standby current No input signal, VSTBY = VSM = GND, RL = 8Ω No input signal, VSTBY = VSM = VCC, RL = 8Ω 10 1000 nA Differential output offset voltage No input signal, RL = 8Ω 0.1 10 mV VCC - 0.9 V VICM Input common mode voltage CMRR ≤ -60dB 0.6 Pout Output power THD = 1% max, F= 1kHz, RL = 8Ω 300 500 mW THD + N Total harmonic distortion + noise Pout = 300mW rms, AV = 1, 20Hz ≤ F ≤ 20kHz, RL = 8Ω 0.5 % PSRRIG Power supply rejection ratio with inputs grounded(1) F = 217Hz, R = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vripple = 200mVPP 100 dB CMRR Common mode rejection ratio F = 217Hz, RL = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vic = 200mVPP 90 dB SNR Signal-to-noise ratio (A-weighted filter, AV = 2.5) RL = 8Ω, THD +N < 0.7%, 20Hz ≤ F ≤ 20kHz 100 dB GBP Gain bandwidth product RL = 8Ω 2 MHz VN Output voltage noise, 20Hz ≤ F ≤ 20kHz, RL = 8Ω Unweighted, AV = 1 A-weighted, AV = 1 Unweighted, AV = 2.5 A-weighted, AV = 2.5 Unweighted, AV = 7.5 A-weighted, AV = 7.5 Unweighted, Standby A-weighted, Standby tWU Wake-up time(2) Cb =1μF 6 5.5 12 10.5 33 28 1.5 1 15 1. Dynamic measurements - 20*log(rms(Vout)/rms (Vripple)). Vripple is the super-imposed sinus signal relative to VCC. 2. Transition time from standby mode to fully operational amplifier. 6/35 μVRMS ms TS4994FC Table 5. Electrical characteristics Electrical characteristics for VCC = +2.6V, GND = 0V, Tamb = 25°C (unless otherwise specified) Symbol ICC ISTBY Voo Parameter Min. Typ. Max. Unit Supply current No input signal, no load 3 7 mA Standby current No input signal, VSTBY = VSM = GND, RL = 8Ω No input signal, VSTBY = VSM = VCC, RL = 8Ω 10 1000 nA Differential output offset voltage No input signal, RL = 8Ω 0.1 10 mV VCC- 0.9 V VICM Input common mode voltage CMRR ≤-60dB 0.6 Pout Output power THD = 1% max, F= 1kHz, RL = 8Ω 200 300 mW THD + N Total harmonic distortion + noise Pout = 225mW rms, AV = 1, 20Hz ≤ F ≤ 20kHz, RL = 8Ω 0.5 % PSRRIG Power supply rejection ratio with inputs grounded(1) F = 217Hz, R = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vripple = 200mVPP 100 dB CMRR Common mode rejection ratio F = 217Hz, RL = 8Ω, AV = 1, Cin = 4.7μF, Cb =1μF Vic = 200mVPP 90 dB SNR Signal-to-noise ratio (A-weighted filter, AV = 2.5) RL = 8Ω, THD +N < 0.7%, 20Hz ≤ F ≤ 20kHz 100 dB GBP Gain bandwidth product RL = 8Ω 2 MHz VN Output voltage noise, 20Hz ≤ F ≤ 20kHz, RL = 8Ω Unweighted, AV = 1 A-weighted, AV = 1 Unweighted, AV = 2.5 A-weighted, AV = 2.5 Unweighted, AV = 7.5 A-weighted, AV = 7.5 Unweighted, Standby A-weighted, Standby tWU Wake-up time(2) Cb =1μF 6 5.5 12 10.5 33 28 1.5 1 15 μVRMS ms 1. Dynamic measurements - 20*log(rms(Vout)/rms (Vripple)). Vripple is the super-imposed sinus signal relative to VCC. 2. Transition time from standby mode to fully operational amplifier. 7/35 Electrical characteristics Current consumption vs. power supply voltage Figure 3. 4.0 4.0 No load 3.5 Tamb=25°C 3.5 Current Consumption (mA) Current Consumption (mA) Figure 2. TS4994FC 3.0 2.5 2.0 1.5 1.0 0.5 0.0 Current consumption vs. standby voltage 3.0 Standby mode=0V 2.5 Standby mode=5V 2.0 1.5 1.0 Vcc = 5V No load Tamb=25°C 0.5 0 1 2 3 4 0.0 5 0 1 2 Power Supply Voltage (V) Figure 4. Current consumption vs. standby voltage Figure 5. 4 5 Current consumption vs. standby voltage 3.0 3.0 2.5 Standby mode=0V Standby mode=3.3V 2.0 1.5 1.0 Vcc = 3.3V No load Tamb=25°C 0.5 0.0 0.0 0.6 1.2 1.8 2.4 Current Consumption (mA) Current Consumption (mA) 3.5 2.5 Standby mode=0V Standby mode=2.6V 2.0 1.5 1.0 Vcc = 2.6V No load Tamb=25°C 0.5 0.0 0.0 3.0 0.6 Standby Voltage (V) Figure 6. 1.2 1.8 2.4 Standby Voltage (V) Differential DC output voltage vs. common mode input voltage Figure 7. 1000 Power dissipation vs. output power 1.4 Av = 1 Tamb = 25°C 100 Vcc=3.3V Power Dissipation (W) Voo (mV) 3 Standby Voltage (V) Vcc=2.5V 10 Vcc=5V 1 Vcc=5V 1.2 F=1kHz THD+N<1% RL=4Ω 1.0 0.8 0.6 RL=8Ω 0.4 0.1 0.2 RL=16Ω 0.01 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 Common Mode Input Voltage (V) 8/35 4.5 5.0 0.0 0.0 0.2 0.4 0.6 0.8 1.0 1.2 Output Power (W) 1.4 1.6 TS4994FC Electrical characteristics Power dissipation vs. output power Figure 9. 0.6 0.40 Vcc=3.3V F=1kHz 0.5 THD+N<1% 0.35 0.4 0.3 0.2 RL=8Ω 0.1 0.1 Vcc=2.6V F=1kHz THD+N<1% 0.2 0.3 0.4 0.5 0.6 0.25 0.20 0.15 RL=8Ω 0.10 RL=16Ω 0.00 0.0 0.7 RL=4Ω 0.30 0.05 RL=16Ω 0.0 0.0 Power dissipation vs. output power RL=4Ω Power Dissipation (W) Power Dissipation (W) Figure 8. 0.1 0.2 Output Power (W) Figure 10. Output power vs. power supply voltage THD+N=10% 1.4 1.2 1.0 0.8 THD+N=1% 0.6 THD+N=10% 1.2 1.0 0.8 0.6 THD+N=1% 0.4 0.4 0.2 0.2 3.0 3.5 4.0 Vcc (V) 4.5 5.0 0.0 2.5 5.5 Figure 12. Output power vs. power supply voltage 3.0 3.5 4.0 Vcc (V) 4.5 5.0 5.5 Figure 13. Output power vs. power supply voltage 1.2 0.6 RL = 16Ω F = 1kHz 1.0 BW < 125kHz Tamb = 25°C 0.8 0.5 Output power (W) Output power (W) RL = 8Ω F = 1kHz 1.6 BW < 125kHz Tamb = 25°C 1.4 1.8 Output power (W) Output power (W) 2.0 2.2 RL = 4Ω F = 1kHz 2.0 BW < 125kHz 1.8 Tamb = 25°C 1.6 THD+N=10% 0.6 0.4 RL = 32Ω F = 1kHz BW < 125kHz Tamb = 25°C THD+N=10% 0.4 0.3 0.2 THD+N=1% THD+N=1% 0.2 0.0 2.5 0.4 Figure 11. Output power vs. power supply voltage 2.4 0.0 2.5 0.3 Output Power (W) 0.1 3.0 3.5 4.0 Vcc (V) 4.5 5.0 5.5 0.0 2.5 3.0 3.5 4.0 Vcc (V) 4.5 5.0 5.5 9/35 Electrical characteristics TS4994FC Figure 15. Open loop gain vs. frequency 0 1.2 60 2 Heat sink surface ≈ 100mm (See demoboard) 1.0 Gain -40 0.8 0.6 0.4 0.0 0 25 50 75 100 Phase -120 0 -20 No Heat sink 0.2 -80 20 -160 Vcc = 5V ZL = 8Ω + 500pF Tamb = 25°C -40 0.1 125 1 10 100 1000 Figure 16. Open loop gain vs. frequency Figure 17. Open loop gain vs. frequency 0 0 60 60 Gain Gain -40 -40 Phase -120 0 -160 Vcc = 3.3V ZL = 8Ω + 500pF Tamb = 25°C 1 10 100 1000 -120 0 -20 -200 10000 Phase -160 Vcc = 2.6V ZL = 8Ω + 500pF Tamb = 25°C -40 0.1 1 Frequency (kHz) 10 100 Figure 18. Closed loop gain vs. frequency 0 10 Phase Phase -40 -20 -120 Vcc = 5V Av = 1 ZL = 8Ω + 500pF Tamb = 25°C 1 -160 10 100 Frequency (kHz) 10/35 1000 -200 10000 Gain (dB) -80 0 Phase (°) Gain (dB) Gain -10 -40 0.1 -200 10000 Figure 19. Closed loop gain vs. frequency 0 10 -30 1000 Frequency (kHz) Gain -40 -10 -80 -20 -120 -30 -40 0.1 Vcc = 3.3V Av = 1 ZL = 8Ω + 500pF Tamb = 25°C 1 -160 10 100 Frequency (kHz) 1000 -200 10000 Phase (°) -40 0.1 -80 20 Phase (°) -80 20 Gain (dB) 40 Phase (°) Gain (dB) 40 0 -200 10000 Frequency (kHz) Ambiant Temperature ( C) -20 Phase (°) 40 Gain (dB) Flip-Chip Package Power Dissipation (W) Figure 14. Power derating curves TS4994FC Electrical characteristics Figure 20. Closed loop gain vs. frequency 10 Figure 21. PSRR vs. frequency 0 0 Phase -10 Gain 0 Vcc = 5V Vripple = 200mVpp Inputs = Grounded Av = 1, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -20 -40 -80 -20 -120 PSRR (dB) -10 Phase (°) Gain (dB) -30 -40 -50 Cb=0.1μF -60 Cb=0.47μF -70 Cb=1μF -80 Vcc = 2.6V Av = 1 ZL = 8Ω + 500pF Tamb = 25°C -30 -40 0.1 1 -90 -160 -100 Cb=0 -110 10 100 1000 -200 10000 -120 20 100 1000 Frequency (Hz) Frequency (kHz) Figure 22. PSRR vs. frequency Figure 23. PSRR vs. frequency 0 0 -20 -30 PSRR (dB) -10 Vcc = 3.3V Vripple = 200mVpp Inputs = Grounded Av = 1, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -40 -50 -30 Cb=0.1μF -60 Cb=0.47μF -70 Cb=1μF -80 -50 Cb=0.1μF -60 Cb=0.47μF -70 Cb=1μF -90 -100 -100 Cb=0 -110 Cb=0 -110 20 100 1000 Frequency (Hz) -120 10000 20k Figure 24. PSRR vs. frequency 20 100 1000 Frequency (Hz) 10000 20k Figure 25. PSRR vs. frequency 0 0 -10 Vcc = 5V Vripple = 200mVpp Inputs = Grounded Av = 2.5, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -20 -30 -40 -50 -30 Cb=0.1μF Cb=0.47μF -60 -70 Cb=1μF -80 Vcc = 3.3V Vripple = 200mVpp Inputs = Grounded Av = 2.5, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -20 PSRR (dB) -10 PSRR (dB) -40 -80 -90 -40 -50 Cb=0.1μF Cb=0.47μF -60 -70 Cb=1μF -80 -90 -90 Cb=0 -100 -110 -120 Vcc = 2.6V Vripple = 200mVpp Inputs = Grounded Av = 1, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -20 PSRR (dB) -10 -120 10000 20k Cb=0 -100 -110 20 100 1000 Frequency (Hz) 10000 20k -120 20 100 1000 Frequency (Hz) 10000 20k 11/35 Electrical characteristics TS4994FC Figure 26. PSRR vs. frequency Figure 27. PSRR vs. frequency 0 0 -20 -30 -40 PSRR (dB) -10 Vcc = 2.6V Vripple = 200mVpp Inputs = Grounded Av = 2.5, Cin = 4.7μF RL ≥ 8Ω Tamb = 25°C -50 -30 Cb=0.1μF Cb=0.47μF -60 -70 Cb=1μF -80 -40 -50 Cb=1μF -90 Cb=0 -100 -110 Cb=0 -110 20 100 -120 10000 20k 1000 Frequency (Hz) Figure 28. PSRR vs. frequency 20 100 10000 20k 1000 Frequency (Hz) Figure 29. PSRR vs. frequency 0 0 -10 Vcc = 3.3V Vripple = 200mVpp Inputs = Floating Rfeed = 20kΩ RL ≥ 8Ω Tamb = 25°C -20 -30 -40 -50 -30 Cb=0.1μF -60 Cb=0.47μF -70 Cb=1μF -80 Vcc = 2.6V Vripple = 200mVpp Inputs = Floating Rfeed = 20kΩ RL ≥ 8Ω Tamb = 25°C -20 -40 PSRR (dB) -10 PSRR (dB) Cb=0.47μF -70 -80 -100 -50 Cb=0.1μF -60 Cb=0.47μF -70 Cb=1μF -80 -90 -90 -100 -100 Cb=0 -110 -120 Cb=0.1μF -60 -90 -120 Vcc = 5V Vripple = 200mVpp Inputs = Floating Rfeed = 20kΩ RL ≥ 8Ω Tamb = 25°C -20 PSRR (dB) -10 Cb=0 -110 20 100 10000 20k 1000 Frequency (Hz) Figure 30. PSRR vs. common mode input voltage -120 20 100 10000 20k 1000 Frequency (Hz) Figure 31. PSRR vs. common mode input voltage 0 -40 -20 PSRR(dB) PSRR(dB) 0 Vcc = 5V Vripple = 200mVpp Inputs Grounded F = 217Hz Av = 1 RL ≥ 8Ω Tamb = 25°C -20 Cb=1μF Cb=0.47μF Cb=0.1μF -60 -40 Vcc = 3.3V Vripple = 200mVpp Inputs Grounded F = 217Hz Av = 1 RL ≥ 8Ω Tamb = 25°C -60 Cb=0 Cb=0 -80 -80 -100 -100 0 1 2 3 4 Common Mode Input Voltage (V) 12/35 5 0.0 Cb=1μF Cb=0.47μF Cb=0.1μF 0.6 1.2 1.8 2.4 Common Mode Input Voltage (V) 3.0 TS4994FC Electrical characteristics Figure 32. PSRR vs. common mode input voltage PSRR(dB) -20 -40 0 Vcc = 2.5V Vripple = 200mVpp Inputs Grounded F = 217Hz Av = 1 RL ≥ 8Ω Tamb = 25°C -60 -10 -30 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -80 -40 -50 -60 -70 -90 -100 -110 0.5 1.0 1.5 2.0 -120 2.5 20 100 Common Mode Input Voltage (V) Figure 34. CMRR vs. frequency -40 -50 Vcc = 2.6V Vic = 200mVpp Av = 1, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -20 -30 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -60 CMRR (dB) -30 CMRR (dB) 10000 20k 0 -10 Vcc = 3.3V Vic = 200mVpp Av = 1, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -20 -70 -80 -40 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -50 -60 -70 -80 -90 -90 -100 -100 -110 -110 20 100 1000 Frequency (Hz) -120 10000 20k Figure 36. CMRR vs. frequency 20 100 1000 Frequency (Hz) 10000 20k Figure 37. CMRR vs. frequency 0 0 Vcc = 5V Vic = 200mVpp Av = 2.5, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -20 -30 -40 -20 -30 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -50 -60 -70 Vcc = 3.3V Vic = 200mVpp Av = 2.5, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -10 CMRR (dB) -10 CMRR (dB) 1000 Frequency (Hz) Figure 35. CMRR vs. frequency 0 -10 -120 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -80 -100 0.0 Vcc = 5V Vic = 200mVpp Av = 1, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -20 CMRR (dB) 0 Figure 33. CMRR vs. frequency -40 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -50 -60 -70 -80 -80 -90 -90 -100 -100 20 100 1000 Frequency (Hz) 10000 20k 20 100 1000 Frequency (Hz) 10000 20k 13/35 Electrical characteristics TS4994FC Figure 38. CMRR vs. frequency Figure 39. CMRR vs. common mode input voltage 0 -30 -40 Vcc=3.3V -20 CMRR(dB) -20 CMRR (dB) 0 Vcc = 2.6V Vic = 200mVpp Av = 2.5, Cin = 470μF RL ≥ 8Ω Tamb = 25°C -10 Cb=1μF Cb=0.47μF Cb=0.1μF Cb=0 -50 -60 -70 Vcc=2.5V Vic = 200mVpp F = 217Hz Av = 1, Cb = 1μF RL ≥ 8Ω Tamb = 25°C -40 -60 -80 -80 -100 -90 -100 20 100 0.0 10000 20k 1000 Frequency (Hz) Vcc=5V 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 Common Mode Input Voltage (V) Figure 40. CMRR vs. common mode input voltage Figure 41. THD+N vs. output power 10 0 Vcc=3.3V Vcc=2.5V THD + N (%) CMRR(dB) -20 Vic = 200mVpp F = 217Hz Av = 1, Cb = 0 RL ≥ 8Ω Tamb = 25°C -40 -60 RL = 4Ω F = 20Hz Av = 1 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 -80 -100 0.0 0.01 Vcc=5V 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 1E-3 Common Mode Input Voltage (V) Figure 42. THD+N vs. output power Vcc=3.3V THD + N (%) THD + N (%) 10 Vcc=2.6V Vcc=5V 0.1 0.01 1E-3 14/35 1 Figure 43. THD+N vs. output power 10 RL = 4Ω F = 20Hz Av = 2.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C 0.01 0.1 Output Power (W) RL = 4Ω F = 20Hz Av = 7.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 0.1 Output Power (W) 1 0.01 1E-3 0.01 0.1 Output Power (W) 1 5.0 TS4994FC Electrical characteristics Figure 44. THD+N vs. output power Figure 45. THD+N vs. output power 10 10 Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) RL = 8Ω F = 20Hz Av = 1 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=5V 0.1 0.01 1E-3 1E-3 0.01 0.1 Output Power (W) Vcc=3.3V Vcc=5V 0.1 1E-3 1E-3 1 0.01 0.1 Output Power (W) 1 Figure 47. THD+N vs. output power 10 10 Vcc=2.6V THD + N (%) THD + N (%) Vcc=2.6V 0.01 Figure 46. THD+N vs. output power RL = 8Ω F = 20Hz Av = 7.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C RL = 8Ω F = 20Hz Av = 2.5 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=3.3V Vcc=5V RL = 16Ω F = 20Hz 1 Av = 1 Cb = 1μF BW < 125kHz Tamb = 25°C 0.1 Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 0.01 1E-3 0.01 0.1 Output Power (W) 1E-3 1E-3 1 Figure 48. THD+N vs. output power Vcc=3.3V THD + N (%) THD + N (%) 10 Vcc=2.6V Vcc=5V 0.01 1E-3 1E-3 1 Figure 49. THD+N vs. output power 10 RL = 16Ω F = 20Hz 1 Av = 2.5 Cb = 1μF BW < 125kHz Tamb = 25°C 0.1 0.01 0.1 Output Power (W) RL = 16Ω F = 20Hz 1 Av = 7.5 Cb = 1μF BW < 125kHz Tamb = 25°C 0.1 Vcc=2.6V Vcc=3.3V Vcc=5V 0.01 0.01 0.1 Output Power (W) 1 1E-3 1E-3 0.01 0.1 Output Power (W) 1 15/35 Electrical characteristics TS4994FC Figure 50. THD+N vs. output power Figure 51. THD+N vs. output power 10 10 Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) RL = 4Ω F = 1kHz Av = 1 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=5V 0.1 RL = 4Ω F = 1kHz Av = 2.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 1E-3 0.01 0.1 Output Power (W) 1 Figure 52. THD+N vs. output power 0.01 1E-3 10 Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) 1 Figure 53. THD+N vs. output power 10 RL = 4Ω F = 1kHz Av = 7.5 Cb = 1μF BW < 125kHz 1 Tamb = 25°C 0.01 0.1 Output Power (W) Vcc=5V RL = 8Ω F = 1kHz Av = 1 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.1 0.01 1E-3 0.01 0.1 Output Power (W) 1 Figure 54. THD+N vs. output power 1E-3 10 Vcc=2.6V THD + N (%) THD + N (%) 1 Figure 55. THD+N vs. output power 10 RL = 8Ω F = 1kHz Av = 2.5 1 Cb = 1μF BW < 125kHz Tamb = 25°C 0.01 0.1 Output Power (W) Vcc=3.3V Vcc=5V 0.1 RL = 8Ω F = 1kHz Av = 7.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 1E-3 16/35 0.01 0.1 Output Power (W) 1 0.01 1E-3 0.01 0.1 Output Power (W) 1 TS4994FC Electrical characteristics Figure 56. THD+N vs. output power Figure 57. THD+N vs. output power 10 RL = 16Ω F = 1kHz 1 Av = 1 Cb = 1μF BW < 125kHz Tamb = 25°C 0.1 Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) 10 Vcc=5V 0.01 RL = 16Ω F = 1kHz 1 Av = 2.5 Cb = 1μF BW < 125kHz Tamb = 25°C 0.1 0.01 0.1 Output Power (W) 1 Figure 58. THD+N vs. output power 1E-3 1E-3 Vcc=5V 0.01 0.1 Output Power (W) 1 Figure 59. THD+N vs. output power 10 10 RL = 16Ω F = 1kHz Av = 7.5 1 Cb = 1μF BW < 125kHz Tamb = 25°C RL = 4Ω F = 20kHz Av = 1 1 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) Vcc=3.3V 0.01 1E-3 1E-3 Vcc=5V 0.1 0.01 Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 1E-3 0.01 0.1 Output Power (W) 1 Figure 60. THD+N vs. output power 1E-3 0.01 0.1 Output Power (W) 1 Figure 61. THD+N vs. output power 10 10 RL = 4Ω F = 20kHz Av = 2.5 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=3.3V Vcc=5V 1 0.1 1E-3 RL = 4Ω F = 20kHz Av = 7.5 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=2.6V THD + N (%) THD + N (%) Vcc=2.6V 0.01 0.1 Output Power (W) 1 Vcc=2.6V Vcc=3.3V Vcc=5V 1 0.1 1E-3 0.01 0.1 Output Power (W) 1 17/35 Electrical characteristics TS4994FC Figure 62. THD+N vs. output power Figure 63. THD+N vs. output power RL = 8Ω F = 20kHz Av = 1 Cb = 1μF BW < 125kHz 1 Tamb = 25°C 10 Vcc=2.6V THD + N (%) THD + N (%) 10 Vcc=3.3V Vcc=5V 0.1 1E-3 0.01 0.1 Output Power (W) 1 1E-3 Vcc=5V 0.01 0.1 Output Power (W) 1 Figure 65. THD+N vs. output power 10 10 RL = 16Ω F = 20kHz Av = 1 Cb = 1μF 1 BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) Vcc=2.6V Vcc=3.3V 0.1 Figure 64. THD+N vs. output power RL = 8Ω F = 20kHz Av = 7.5 Cb = 1μF BW < 125kHz 1 Tamb = 25°C RL = 8Ω F = 20kHz Av = 2.5 Cb = 1μF BW < 125kHz 1 Tamb = 25°C Vcc=5V Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.1 1E-3 0.01 0.1 Output Power (W) 0.01 1E-3 1 Figure 66. THD+N vs. output power 10 Vcc=2.6V Vcc=3.3V THD + N (%) THD + N (%) 1 Figure 67. THD+N vs. output power 10 RL = 16Ω F = 20kHz Av = 2.5 Cb = 1μF 1 BW < 125kHz Tamb = 25°C 0.01 0.1 Output Power (W) Vcc=5V 1 RL = 16Ω F = 20kHz Av = 7.5 Cb = 1μF BW < 125kHz Tamb = 25°C Vcc=2.6V Vcc=3.3V Vcc=5V 0.1 0.01 1E-3 18/35 0.1 0.01 0.1 Output Power (W) 1 1E-3 0.01 0.1 Output Power (W) 1 TS4994FC Electrical characteristics Figure 68. THD+N vs. frequency Figure 69. THD+N vs. frequency 10 RL = 4Ω Av = 1 Cb = 1μF 1 Bw < 125kHz Tamb = 25°C Vcc=2.6V, Po=350mW THD + N (%) THD + N (%) 10 0.1 RL = 4Ω Av = 7.5 Cb = 1μF Bw < 125kHz 1 Tamb = 25°C 0.1 Vcc=2.6V, Po=350mW 0.01 Vcc=5V, Po=1W Vcc=5V, Po=1W 1E-3 0.01 20 100 1000 Frequency (Hz) 10000 20k Figure 70. THD+N vs. frequency 20 1000 Frequency (Hz) 10000 20k Figure 71. THD+N vs. frequency 10 10 RL = 8Ω Av = 1 Cb = 1μF 1 Bw < 125kHz Tamb = 25°C THD + N (%) THD + N (%) 100 0.1 Vcc=5V, Po=850mW RL = 8Ω Av = 7.5 Cb = 1μF Bw < 125kHz 1 Tamb = 25°C Vcc=2.6V, Po=225mW Vcc=5V, Po=850mW 0.1 0.01 Vcc=2.6V, Po=225mW 1E-3 20 100 1000 Frequency (Hz) 0.01 10000 20k Figure 72. THD+N vs. frequency 20 10000 20k 10 0.1 THD + N (%) RL = 16Ω Av = 1 Cb = 1μF 1 Bw < 125kHz Tamb = 25°C Vcc=2.6V, Po=155mW 0.01 RL = 16Ω Av = 7.5 Cb = 1μF 1 Bw < 125kHz Tamb = 25°C 0.1 Vcc=5V, Po=600mW 0.01 Vcc=5V, Po=600mW 1E-3 1000 Frequency (Hz) Figure 73. THD+N vs. frequency 10 THD + N (%) 100 20 100 1000 Frequency (Hz) 10000 20k Vcc=2.6V, Po=155mW 1E-3 20 100 1000 Frequency (Hz) 10000 20k 19/35 Electrical characteristics TS4994FC Figure 74. THD+N vs. output power Figure 75. THD+N vs. output power 10 RL = 4Ω Vcc = 5V Av = 1 Cb = 0 1 BW < 125kHz Tamb = 25°C F=1kHz 0.1 RL = 4Ω Vcc = 5V Av = 7.5, Cb = 0 BW < 125kHz Tamb = 25°C F=20kHz THD + N (%) THD + N (%) 10 F=20kHz 1 F=1kHz F=20Hz F=20Hz 0.1 0.01 1E-3 0.01 0.1 Output Power (W) 1 Figure 76. THD+N vs. output power 1E-3 1 Figure 77. THD+N vs. output power 10 10 RL = 4Ω Vcc = 2.6V Av = 1, Cb = 0 1 BW < 125kHz Tamb = 25°C F=20kHz THD + N (%) THD + N (%) 0.01 0.1 Output Power (W) F=1kHz 0.1 RL = 4Ω Vcc = 2.6V Av = 7.5, Cb = 0 BW < 125kHz 1 Tamb = 25°C F=20kHz F=20Hz F=1kHz 0.1 0.01 F=20Hz 1E-3 1E-3 0.01 Output Power (W) 0.1 1E-3 Figure 78. THD+N vs. output power 10 F=20kHz THD + N (%) THD + N (%) 0.1 Figure 79. THD+N vs. output power 10 RL = 8Ω Vcc = 5V Av = 1 1 Cb = 0 BW < 125kHz Tamb = 25°C 0.01 Output Power (W) F=1kHz 0.1 RL = 8Ω Vcc = 5V Av = 7.5, Cb = 0 BW < 125kHz 1 Tamb = 25°C F=20kHz F=1kHz 0.1 F=20Hz 0.01 F=20Hz 1E-3 20/35 0.01 0.1 Output Power (W) 1 0.01 1E-3 0.01 0.1 Output Power (W) 1 TS4994FC Electrical characteristics Figure 80. THD+N vs. output power Figure 81. THD+N vs. output power 10 RL = 8Ω Vcc = 2.6V Av = 1, Cb = 0 1 BW < 125kHz Tamb = 25°C F=20kHz THD + N (%) THD + N (%) 10 F=1kHz 0.1 RL = 8Ω Vcc = 2.6V Av = 7.5, Cb = 0 BW < 125kHz 1 Tamb = 25°C F=20kHz 0.1 F=1kHz 0.01 F=20Hz 1E-3 1E-3 F=20Hz 0.01 Output Power (W) 0.01 1E-3 0.1 Figure 82. THD+N vs. output power 0.1 Figure 83. THD+N vs. output power 10 10 RL = 16Ω Vcc = 5V Av = 1, Cb = 0 1 BW < 125kHz Tamb = 25°C F=20kHz THD + N (%) THD + N (%) 0.01 Output Power (W) F=1kHz 0.1 RL = 16Ω Vcc = 5V Av = 7.5, Cb = 0 1 BW < 125kHz Tamb = 25°C F=20kHz 0.1 F=1kHz 0.01 F=20Hz 1E-3 1E-3 1 Figure 84. THD+N vs. output power 1E-3 0.01 0.1 Output Power (W) 1 Figure 85. THD+N vs. output power 10 10 RL = 16Ω Vcc = 2.6V Av = 1, Cb = 0 1 BW < 125kHz Tamb = 25°C F=20kHz THD + N (%) THD + N (%) F=20Hz 0.01 0.01 0.1 Output Power (W) F=1kHz 0.1 RL = 16Ω Vcc = 2.6V Av = 7.5, Cb = 0 BW < 125kHz 1 Tamb = 25°C F=20kHz 0.1 F=20Hz F=1kHz 0.01 F=20Hz 0.01 1E-3 1E-3 0.01 Output Power (W) 0.1 1E-3 0.01 Output Power (W) 0.1 21/35 Electrical characteristics TS4994FC Figure 86. SNR vs. power supply voltage with Figure 87. SNR vs. power supply voltage with unweighted filter A-weighted filter 110 110 RL=16Ω 105 Signal to Noise Ratio (dB) Signal to Noise Ratio (dB) RL=16Ω 100 RL=8Ω 95 RL=4Ω 90 Av = 2.5 85 Cb = 1μF THD+N < 0.7% Tamb = 25°C 80 2.5 3.0 3.5 4.0 4.5 5.0 Power Supply Voltage (V) Tamb=25°C Startup Time (ms) Vcc=5V 15 Vcc=3.3V 10 5 0 0.0 22/35 Vcc=2.6V 0.4 0.8 1.2 1.6 Bypass Capacitor Cb ( F) 100 RL=8Ω RL=4Ω 95 90 Av = 2.5 85 Cb = 1μF THD+N < 0.7% Tamb = 25°C 80 2.5 3.0 3.5 4.0 Power Supply Voltage (V) Figure 88. Startup time vs. bypass capacitor 20 105 2.0 4.5 5.0 TS4994FC Application information 4 Application information 4.1 Differential configuration principle The TS4994 is a monolithic full-differential input/output power amplifier. The TS4994 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 the device to always have a maximum output voltage swing, and by consequence, maximize the output power. Moreover, as the load is connected differentially, compared to a single-ended topology, the output is four times higher for the same power supply voltage. The advantages of a full-differential amplifier are: ● Very high PSRR (power supply rejection ratio). ● High common mode noise rejection. ● Virtually zero pop without additional circuitry, giving a faster start-up time compared with 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. But, to reach maximum performance in all tolerance situations, it is better to keep this option. The main disadvantage is: ● 4.2 As the differential function is directly linked to the mismatch between external resistors, paying particular attention to this mismatch is mandatory in order to get the best performance from the amplifier. Gain in typical application schematic A typical differential application is shown in Figure 1 on page 3. In the flat region of the frequency-response curve (no Cin effect), the differential gain is expressed by the relation: AV diff R feed V O+ – V O - = ------------= ----------------------------------------------------Diff input+ – Diff inputR in where Rin = Rin1 = Rin2 and Rfeed = Rfeed1 = Rfeed2. Note: For the rest of this section, Avdiff will be called AV to simplify the expression. 4.3 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. However, due to VICM limitation of the input stage (see Table 3 on page 5), the common mode feedback loop can play its role only within a defined range. This range depends upon 23/35 Application information TS4994FC the values of VCC, Rin and Rfeed (AV). To have a good estimation of the VICM value, use the following formula: V CC × R in + 2 × V ic × R feed V ICM = -------------------------------------------------------------------------2 × ( R in + R feed ) (V) with Diff input+ + Diff inputV ic = ------------------------------------------------------2 (V) The result of the calculation must be in the range: 0.6V ≤V ICM ≤ V CC – 0.9V If the result of the VICM calculation is not in this range, an input coupling capacitor must be used. Example: With VCC=2.5V, Rin = Rfeed = 20k and Vic = 2V, we find VICM = 1.63V. This is higher than 2.5V - 0.9V = 1.6V, so input coupling capacitors are required. Alternatively, you can change the Vic value. 4.4 Low and high frequency response In the low frequency region, Cin starts to have an effect. Cin forms, with Rin, a high-pass filter with a -3dB cut-off frequency. FCL is in Hz. FCL = 1 2 × π × Rin × Cin (Hz) In the high-frequency region, you can limit the bandwidth by adding a capacitor (Cfeed) in parallel with Rfeed. It forms a low-pass filter with a -3dB cut-off frequency. FCH is in Hz. FCH = 1 2 × π × Rfeed × Cfeed (Hz) While these bandwidth limitations are in theory attractive, in practice, because of low performance in terms of capacitor precision (and by consequence in terms of mismatching), they deteriorate the values of PSRR and CMRR. The influence of mismatching on PSRR and CMRR performance is discussed in more detail in the following sections. Example: A typical application with input coupling and feedback capacitor with FCL = 50Hz and FCH = 8kHz. We assume that the mismatching between Rin1,2 and Cfeed1,2 can be neglected. If we sweep the frequency from DC to 20kHz we observe the following with respect to the PSRR value: ● 24/35 From DC to 200Hz, the Cin impedance decreases from infinite to a finite value and the Cfeed impedance is high enough to be neglected. Due to the tolerance of Cin1,2, we TS4994FC Application information must introduce a mismatch factor (Rin1 x Cin ≠ Rin2 x Cin2) that will decrease the PSRR performance. 4.5 ● From 200Hz to 5kHz, the Cin impedance is low enough to be neglected when compared with Rin, and the Cfeed impedance is high enough to be neglected as well. In this range, we can reach the PSRR performance of the TS4994 itself. ● From 5kHz to 20kHz, the Cin impedance is low to be neglected when compared to Rin, and the Cfeed impedance decreases to a finite value. Due to tolerance of Cfeed1,2, we introduce a mismatching factor (Rfeed1 x Cfeed1 ≠ Rfeed2 x Cfeed2) that will decrease the PSRR performance. Calculating the influence of mismatching on PSRR performance For calculating PSRR performance, we consider that Cin and Cfeed have no influence. We use the same kind of resistor (same tolerance) and ΔR is the tolerance value in %. The following PSRR equation is valid for frequencies ranging from DC to about 1kHz. The PSRR equation is (ΔR in %): ⎡ ΔR × 100 ⎤ PSRR ≤ 20 × Log ⎢ 2 ⎥ ⎣ (10000 − ΔR ) ⎦ (dB ) This equation doesn't include the additional performance provided by bypass capacitor filtering. If a bypass capacitor is added, it acts, together with the internal high output impedance bias, as a low-pass filter, and the result is a quite important PSRR improvement with a relatively small bypass capacitor. The complete PSRR equation (ΔR in %, Cb in microFarad and F in Hz) is: ΔR × 100 PSRR ≤20 × log --------------------------------------------------------------------------------------------------------- ( dB ) 2 2 2 (1000 – ΔR ) × 1 + F × C b × 22.2 Example: With ΔR = 0.1% and Cb = 0, the minimum PSRR is -60dB. With a 100nF bypass capacitor, at 100Hz the new PSRR would be -93dB. This example is a worst case scenario, where each resistor has extreme tolerance. It illustrates the fact that with only a small bypass capacitor, the TS4994 provides high PSRR performance. Note also that this is a theoretical formula. Because the TS4994 has self-generated noise, you should consider that the highest practical PSRR reachable is about -110dB. It is therefore unreasonable to target a -120dB PSRR. 25/35 Application information TS4994FC The three following graphs show PSRR versus frequency and versus bypass capacitor Cb in worst-case conditions (ΔR = 0.1%). 0 -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 -130 -140 Vcc = 5V, Vripple = 200mVpp Av = 1, Cin = 4.7μF ΔR/R = 0.1%, RL ≥ 8Ω Tamb = 25°C, Inputs = Grounded Cb=0 Cb=0.1μF Cb=1μF 20 100 Cb=0.47μF 1000 Frequency (Hz) 10000 20k PSRR (dB) Figure 91. PSRR vs. frequency (worst case conditions) 26/35 0 -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 -130 -140 Vcc = 2.5V, Vripple = 200mVpp Av = 1, Cin = 4.7μF ΔR/R = 0.1%, RL ≥ 8Ω Tamb = 25°C, Inputs = Grounded Cb=0 Cb=0.1μF Cb=1μF 20 100 Cb=0.47μF 1000 Frequency (Hz) Figure 90. PSRR vs. frequency (worst case conditions) PSRR (dB) PSRR (dB) Figure 89. PSRR vs. frequency (worst case conditions) 10000 20k 0 -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 -130 -140 Vcc = 3.3V, Vripple = 200mVpp Av = 1, Cin = 4.7μF ΔR/R = 0.1%, RL ≥ 8Ω Tamb = 25°C, Inputs = Grounded Cb=0 Cb=0.1μF Cb=1μF 20 100 Cb=0.47μF 1000 Frequency (Hz) 10000 20k TS4994FC Application information The two following graphs show typical applications of the TS4994 with a random selection of four ΔR/R values with a 0.1% tolerance. 4.6 0 -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 -130 -140 Figure 93. PSRR vs. frequency with random choice condition Vcc = 5V, Vripple = 200mVpp Av = 1, Cin = 4.7μF ΔR/R ≤ 0.1%, RL ≥ 8Ω Tamb = 25°C, Inputs = Grounded Cb=0.1μF Cb=1μF 20 100 PSRR (dB) PSRR (dB) Figure 92. PSRR vs. frequency with random choice condition Cb=0 Cb=0.47μF 1000 Frequency (Hz) 10000 20k 0 -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 -110 -120 -130 -140 Vcc = 2.5V, Vripple = 200mVpp Av = 1, Cin = 4.7μF ΔR/R ≤ 0.1%, RL ≥ 8Ω Tamb = 25°C, Inputs = Grounded Cb=0.1μF Cb=1μF 20 100 Cb=0 Cb=0.47μF 1000 Frequency (Hz) 10000 20k CMRR performance For calculating CMRR performance, we consider that Cin and Cfeed have no influence. Cb has no influence in the calculation of the CMRR. We use the same kind of resistor (same tolerance) and ΔR is the tolerance value in %. The following CMRR equation is valid for frequencies ranging from DC to about 1kHz. The CMRR equation is (ΔR in %): ⎡ Δ R × 200 ⎤ CMRR ≤ 20 × Log ⎢ 2 ⎥ ⎣ (10000 − Δ R ) ⎦ (dB ) Example: With ΔR = 1%, the minimum CMRR is -34dB. This example is a worst case scenario where each resistor has extreme tolerance. Ut illustrates the fact that for CMRR, good matching is essential. As with the PSRR, due to self-generated noise, the TS4994 CMRR limitation is about -110dB. Figure 94 and Figure 95 show CMRR versus frequency and versus bypass capacitor Cb in worst-case conditions (ΔR=0.1%). 27/35 Application information TS4994FC Figure 94. CMRR vs. frequency (worst case conditions) Figure 95. CMRR vs. frequency (worst case conditions) 0 0 Vcc = 5V Vic = 200mVpp Av = 1, Cin = 470μF ΔR/R = 0.1%, RL ≥ 8Ω Tamb = 25°C -20 -30 -40 -20 -30 -40 Cb=1μF Cb=0 -50 -60 Vcc = 2.5V Vic = 200mVpp Av = 1, Cin = 470μF ΔR/R = 0.1%, RL ≥ 8Ω Tamb = 25°C -10 CMRR (dB) CMRR (dB) -10 Cb=1μF Cb=0 -50 20 100 1000 Frequency (Hz) -60 10000 20k 20 100 1000 Frequency (Hz) 10000 20k Figure 96 and Figure 97 show CMRR versus frequency for a typical application with a random selection of four ΔR/R values with a 0.1% tolerance. Figure 96. CMRR vs. frequency with random selection condition Figure 97. CMRR vs. frequency with random selection condition 0 0 Vcc = 5V Vic = 200mVpp Av = 1, Cin = 470μF ΔR/R ≤ 0.1%, RL ≥ 8Ω Tamb = 25°C CMRR (dB) -20 -30 Cb=1μF Cb=0 -60 -30 -40 -50 -70 -80 -80 20 100 1000 Frequency (Hz) Cb=1μF Cb=0 -60 -70 -90 4.7 -20 -40 -50 Vcc = 2.5V Vic = 200mVpp Av = 1, Cin = 470μF ΔR/R ≤ 0.1%, RL ≥ 8Ω Tamb = 25°C -10 CMRR (dB) -10 -90 10000 20k 20 100 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 sinωt (V) and V out I out = ------------- (A) RL 28/35 1000 Frequency (Hz) 10000 20k TS4994FC Application information and V peak 2 P out = --------------------- (W) 2R L Therefore, the average current delivered by the supply voltage is: Equation 1 V peak I CC AVG = 2 ----------------- (A) πR L The power delivered by the supply voltage is: P supply = V CC ⋅ I CC AVG (W) Therefore, the power dissipated by each amplifier is: P diss = P supply – P out (W) Equation 2 2 2V CC P diss = ---------------------- P out – P out π RL and the maximum value is obtained when: ∂P diss ----------------- = 0 ∂P out and its value is: Equation 3 Pdiss max = Note: 2 Vcc 2 π2RL (W) 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 4 P out πV peak η = ------------------- = -------------------P supply 4V CC The maximum theoretical value is reached when Vpeak = VCC, so: π η = ----- = 78.5% 4 The maximum die temperature allowable for the TS4994 is 125°C. However, in case of overheating, a thermal shutdown set to 150°C, puts the TS4994 in standby until the temperature of the die is reduced by about 5°C. 29/35 Application information TS4994FC To calculate the maximum ambient temperature Tamb allowable, you need to know: ● The value of the power supply voltage, VCC ● The value of the load resistor, RL ● The Rthja value for the package type Example: VCC = 5V, RL = 8Ω, Rthja-flipchip = 100°C/W (100mm² copper heatsink) Using the power dissipation formula given above in Equation 3 this gives a result of: Pdissmax = 633mW Tamb is calculated as follows: Equation 5 T amb = 125° C – R TJHA × P dissmax Therefore, the maximum allowable value for Tamb is: Tamb = 125-80x0.633=62°C 4.8 Decoupling of the circuit Two capacitors are needed to correctly bypass the TS4994. A power supply bypass capacitor Cs and a bias voltage bypass capacitor Cb. Cs has particular influence on the THD+N in the high frequency region (above 7kHz) and an indirect influence on power supply disturbances. With a value for Cs of 1µF, you can expect similar THD+N performance to that shown in the datasheet. In the high frequency region, if Cs is lower than 1µF, it increases THD+N, and disturbances on the power supply rail are less filtered. On the other hand, if Cs is higher than 1µF, the disturbances on the power supply rail are more filtered. Cb has an influence on THD+N at lower frequencies, but its function is critical to the final result of PSRR (with input grounded and in the lower frequency region). 4.9 Wake-up time: tWU When the standby is released to put the device ON, the bypass capacitor Cb is not charged immediately. As 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 3 on page 5, with Cb=1µF. During the wake-up time, the TS4994 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 other than 1µF, refer to the graph in Figure 88 on page 22 to establish the wake-up time. 30/35 TS4994FC 4.10 Application information Shutdown time When the standby command is set, the time required to put the two output stages in high impedance and the internal circuitry in shutdown mode is a few microseconds. Note: In shutdown mode, the Bypass pin and Vin+, Vin- pins are short-circuited to ground by internal switches. This allows a quick discharge of the Cb and Cin capacitors. 4.11 Pop performance Due to its fully differential structure, the pop performance of the TS4994 is close to perfect. However, due to mismatching between internal resistors Rin, Rfeed, and external input capacitors Cin, some noise might remain at startup. To eliminate the effect of mismatched components, the TS4994 includes pop reduction circuitry. With this circuitry, the TS4994 is close to zero pop for all possible common applications. In addition, when the TS4994 is in standby mode, due to the high impedance output stage in this configuration, no pop is heard. Single-ended input configuration It is possible to use the TS4994 in a single-ended input configuration. However, input coupling capacitors are needed in this configuration. The schematic in Figure 98 shows an example of this configuration. Figure 98. Single-ended input typical application VCC + Rfeed1 20k 2 Cs 1u GND VCC Cin1 + Ve Rin1 + 220nF 20k Cin2 Rin2 GND 3 Vin- - 1 Vin+ + Vo+ 5 Vo7 220nF 20k 8 Ohms 8 Bypass + 4.12 Bias Cb 1u Standby Mode Stdby GND 4 6 GND 9 GND TS4994IJ Rfeed2 20k GND VCC GND VCC The component calculations remain the same, except for the gain. In single-ended input configuration, the formula is: Av SE = VO + − VO − Rfeed = Ve Rin 31/35 Package information 5 TS4994FC Package information In order to meet environmental requirements, STMicroelectronics offers these devices in ECOPACK® 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. Flip-chip package (9 bumps) Dimensions in millimeters unless otherwise indicated. Figure 99. Pinout (top view) Gnd VO- 7 6 5 VO+ Bypass 8 9 4 Stdby 1 2 3 VIN- VIN+ VCC Stdby Mode * Balls are underneath Figure 100. Marking (top view) E A94 YWW 32/35 TS4994FC Package information Figure 101. Dimensions ● 1.63 mm ● ● ● 1.63 mm 0.5mm ● ● ● ● 0.5mm ● ∅ 0.25mm Die size: 1.63mm x 1.63mm ± 30µm Die height (including bumps): 600µm Bumps diameter: 315µm ±50µm Bump diameter before reflow: 300µm ±10µm Bump height: 250µm ±40µm Back coating height: 40µm ±10µm Die height: 350µm ±20µm Pitch: 500µm ±50µm Coplanarity: 60µm max 100µm 600µm Figure 102. Tape & reel dimensions 1.5 4 1 1 A Die size Y + 70µm A 8 Die size X + 70µm 4 All dimensions are in mm User direction of feed 33/35 Revision history 6 TS4994FC Revision history Table 6. 34/35 Document revision history Date Revision Changes 17-Mar-2005 1 Initial release. 12-Dec-2006 2 Template update. 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