TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 3.1-W MONO FULLY DIFFERENTIAL AUDIO POWER AMPLIFIER FEATURES APPLICATIONS • • • • • • • Designed for Wireless or Cellular Handsets and PDAs 3.1 W Into 3Ω From a 5-V Supply at THD = 10% (Typ) Low Supply Current: 4 mA Typ at 5 V Shutdown Current: 0.01 µA Typ Fast Startup With Minimal Pop Only Three External Components – Improved PSRR (-80 dB) and Wide Supply Voltage (2.5 V to 5.5 V) for Direct Battery Operation – Fully Differential Design Reduces RF Rectification – -63 dB CMRR Eliminates Two Input Coupling Capacitors Ideal for Wireless Handsets, PDAs, and Notebook Computers DESCRIPTION The TPA6211A1 is a 3.1-W mono fully-differential amplifier designed to drive a speaker with at least 3-Ω impedance while consuming only 20 mm2 total printed-circuit board (PCB) area in most applications. The device operates from 2.5 V to 5.5 V, drawing only 4 mA of quiescent supply current. The TPA6211A1 is available in the space-saving 3-mm × 3-mm QFN (DRB) and the 8-pin MSOP (DGN) PowerPAD™ packages. Features like -80 dB supply voltage rejection from 20 Hz to 2 kHz, improved RF rectification immunity, small PCB area, and a fast startup with minimal pop makes the TPA6211A1 ideal for PDA/smart phone applications. APPLICATION CIRCUIT VDD 6 In From DAC RI + RI 4 3 ININ+ _ C(BYPASS)(1) (1) 1 VO+ 5 VO- 8 GND 7 SHUTDOWN 1 8 V O- BYPASS 2 7 GND IN+ 3 6 VDD IN- 4 5 VO+ + 40 kΩ SHUTDOWN To Battery Cs 40 kΩ - 8-PIN QFN (DRB) PACKAGE (TOP VIEW) Bias Circuitry 100 kΩ 2 DGN PACKAGE (TOP VIEW) SHUTDOWN BYPASS IN+ IN- 1 8 2 7 3 6 4 5 VOGND VDD VO+ C(BYPASS) is optional. Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PowerPAD is a trademark of Texas Instruments. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2003–2004, Texas Instruments Incorporated TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. ORDERING INFORMATION PACKAGED DEVICES (1) (1) TA SMALL OUTLINE (DRB) MSOP PowerPAD™ (DGN) EVALUATION MODULES -40°C to 85°C TPA6211A1DRB TPA6211A1DGN TPA6211A1EVM The DGN and DRB are available taped and reeled. To order taped and reeled parts, add the suffix R to the part number (TPA6211A1DGNR or TPA6211A1DRBR). Terminal Functions TERMINAL NAME DRB, DGN I/O DESCRIPTION IN- 4 I Negative differential input IN+ 3 I Positive differential input VDD 6 I Power supply VO+ 5 O Positive BTL output GND 7 I High-current ground VO- 8 O Negative BTL output SHUTDOWN 1 I Shutdown terminal (active low logic) BYPASS 2 Thermal Pad - Mid-supply voltage, adding a bypass capacitor improves PSRR - Connect to ground. Thermal pad must be soldered down in all applications to properly secure device on the PCB. ABSOLUTE MAXIMUM RATINGS over operating free-air temperature range unless otherwise noted (1) UNIT VDD Supply voltage VI Input voltage -0.3 V to 6 V -0.3 V to VDD + 0.3 V Continuous total power dissipation See Dissipation Rating Table TA Operating free-air temperature -40°C to 85°C TJ Junction temperature -40°C to 150°C Tstg Storage temperature -65°C to 85°C Lead temperature 1,6 mm (1/16 Inch) from case for 10 seconds (1) DRB 260°C DGN 235°C Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under "recommended operating conditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. PACKAGE DISSIPATION RATINGS (1) 2 PACKAGE TA ≤ 25°C POWER RATING DERATING FACTOR (1) TA= 70°C POWER RATING TA= 85°C POWER RATING DGN 2.13 W 17.1 mW/°C 1.36 W 1.11 W DRB 2.7 W 21.8 mW/°C 1.7 W 1.4 W Derating factor based on high-k board layout. TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 RECOMMENDED OPERATION CONDITIONS MIN VDD Supply voltage VIH High-level input voltage SHUTDOWN VIL Low-level input voltage SHUTDOWN TA Operating free-air temperature TYP MAX 2.5 5.5 1.55 UNIT V V 0.5 V 85 °C -40 ELECTRICAL CHARACTERISTICS TA = 25°C PARAMETER TEST CONDITIONS VOS Output offset voltage (measured differentially) VI = 0 V differential, Gain = 1 V/V, VDD = 5.5 V PSRR Power supply rejection ratio VDD = 2.5 V to 5.5 V VIC Common mode input range VDD = 2.5 V to 5.5 V CMRR Common mode rejection ratio Low-output swing High-output swing MIN TYP -9 MAX UNIT 0.3 9 mV -85 -60 dB VDD-0.8 V 0.5 VDD = 5.5 V, VIC = 0.5 V to 4.7 V -63 -40 VDD = 2.5 V, VIC = 0.5 V to 1.7 V -63 -40 RL = 4 Ω, VIN+ = VDD, VIN+ = 0 V, VDD = 5.5 V Gain = 1 V/V, VIN- = 0 V or VDD = 3.6 V VIN- = VDD VDD = 2.5 V 0.45 RL = 4 Ω, VIN+ = VDD, VIN- = VDD VDD = 5.5 V Gain = 1 V/V, VIN- = 0 V or VDD = 3.6 V VIN+ = 0 V VDD = 2.5 V 4.95 0.37 0.26 V 0.4 3.18 2 dB V 2.13 | IIH | High-level input current, shutdown VDD = 5.5 V, VI = 5.8 V 58 100 | IIL | Low-level input current, shutdown VDD = 5.5 V, VI = -0.3 V 3 100 µA IQ Quiescent current VDD = 2.5 V to 5.5 V, no load 4 5 mA I(SD) Supply current V(SHUTDOWN) ≤ 0.5 V, VDD = 2.5 V to 5.5 V, RL = 4Ω 0.01 1 µA Gain RL = 4Ω Resistance from shutdown to GND 38 k RI 40 k RI 100 42 k RI µA V/V kΩ 3 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 OPERATING CHARACTERISTICS TA = 25°C, Gain = 1 V/V PARAMETER TEST CONDITIONS THD + N= 1%, f = 1 kHz, RL = 3 Ω PO Output power THD + N= 1%, f = 1 kHz, RL = 4 Ω THD + N= 1%, f = 1 kHz, RL = 8 Ω MIN THD+N Total harmonic distortion plus noise f = 1 kHz, RL = 4 Ω f = 1 kHz, RL = 8 Ω MAX VDD = 5 V 2.45 VDD = 3.6 V 1.22 VDD = 2.5 V 0.49 VDD = 5 V 2.22 VDD = 3.6 V 1.1 VDD = 2.5 V 0.47 VDD = 5 V 1.36 VDD = 3.6 V 0.72 VDD = 2.5 V f = 1 kHz, RL = 3 Ω TYP VDD = 5 V 0.045% PO = 1 W VDD = 3.6 V 0.05% PO = 300 mW VDD = 2.5 V 0.06% PO = 1.8 W VDD = 5 V 0.03% PO = 0.7 W VDD = 3.6 V 0.03% PO = 300 mW VDD = 2.5 V 0.04% PO = 1 W VDD = 5 V 0.02% PO = 0.5 W VDD = 3.6 V 0.02% PO = 200 mW VDD = 2.5 V 0.03% f = 217 Hz -80 f = 20 Hz to 20 kHz -70 kSVR Supply ripple rejection ratio VDD = 3.6 V, Inputs ac-grounded with Ci = 2 µF, V(RIPPLE) = 200 mVpp SNR Signal-to-noise ratio VDD = 5 V, PO = 2 W, RL = 4 Ω Vn Output voltage noise VDD = 3.6 V, f = 20 Hz to 20 kHz, Inputs ac-grounded with Ci = 2 µF No weighting 15 A weighting 12 CMRR Common mode rejection ratio VDD = 3.6 V, VIC = 1 Vpp f = 217 Hz -65 ZI Input impedance Start-up time from shutdown 4 dB 105 38 VDD = 3.6 V, CBYPASS = 0.1 µF W 0.33 PO = 2 W VDD = 3.6 V, No CBYPASS UNIT 40 dB µVRMS dB 44 kΩ 4 µs 27 ms TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 TYPICAL CHARACTERISTICS Table of Graphs FIGURE PO Output power PD Power dissipation THD+N Total harmonic distortion + noise vs Supply voltage 1 vs Load resistance 2 vs Output power 3, 4 vs Output power 5, 6, 7 vs Frequency 8-12 vs Common-mode input voltage 13 KSVR Supply voltage rejection ratio vs Frequency KSVR Supply voltage rejection ratio vs Common-mode input voltage 18 GSM Power supply rejection vs Time 19 GSM Power supply rejection vs Frequency 20 vs Frequency 21 vs Common-mode input voltage 22 Closed loop gain/phase vs Frequency 23 Open loop gain/phase vs Frequency 24 vs Supply voltage 25 vs Shutdown voltage 26 vs Bypass capacitor 27 CMRR IDD Common-mode rejection ratio Supply current Start-up time 14, 15, 16, 17 OUTPUT POWER vs SUPPLY VOLTAGE OUTPUT POWER vs LOAD RESISTANCE 3.5 3 3.5 f = 1 kHz Gain = 1 V/V 3 VDD = 5 V, THD 1% PO = 3 Ω, THD 1% PO - Output Power - W PO - Output Power - W PO = 4 Ω, THD 10% 2.5 PO = 4 Ω, THD 1% 2 1.5 PO = 8 Ω, THD 10% PO = 8 Ω, THD 1% 1 0.5 0 2.5 f = 1 kHz Gain = 1 V/V VDD = 5 V, THD 10% PO = 3 Ω, THD 10% 2.5 VDD = 3.6 V, THD 10% 2 VDD = 3.6 V, THD 1% 1.5 VDD = 2.5 V, THD 10% VDD = 2.5 V, THD 1% 1 0.5 0 3 3.5 4 VDD - Supply Voltage - V Figure 1. 4.5 5 3 8 13 18 23 28 RL - Load Resistance - Ω Figure 2. 5 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 POWER DISSIPATION vs OUTPUT POWER POWER DISSIPATION vs OUTPUT POWER 1.4 0.8 VDD = 3.6 V 1.2 4Ω 0.6 PD - Power Dissiaption - W PD - Power Dissiaption - W 0.7 0.5 0.4 8Ω 0.3 0.2 0 0 0.3 0.6 0.9 1.2 PO - Output Power - W 1.5 8Ω 0.6 0.4 0 0.3 0.6 0.9 1.2 PO - Output Power - W 1.5 1.8 Figure 3. Figure 4. TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT POWER TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT POWER 20 RL = 3 Ω, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V THD+N - Total Harmonic Distortion + Noise - % THD+N - Total Harmonic Distortion + Noise - % 0.8 0 1.8 10 5 1 0.2 0.1 2 1 0.5 0.2 2.5 V 3.6 V 0.1 5V 0.05 0.02 0.01 20m 50m 100m 200m 500m 1 PO - Output Power - W Figure 5. 6 4Ω VDD = 5 V 2 3 10 5 RL = 4 Ω, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V 2 1 0.5 2.5 V 0.2 3.6 V 5V 0.1 0.05 0.02 0.01 10m 20m 50m 100m 200m 500m 1 PO - Output Power - W Figure 6. 2 3 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT POWER TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY 10 5 10 RL = 8 Ω, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V THD+N - Total Harmonic Distortion + Noise - % THD+N - Total Harmonic Distortion + Noise - % 20 2 1 2.5 V 0.5 3.6 V 0.2 5V 0.1 0.05 0.02 0.01 10m 20m 2 1 0.5 1W 0.2 0.1 2W 0.05 0.02 0.01 0.005 50m 100m 200m 500m 1 PO - Output Power - W 20 2 3 50 100 200 500 1k 2k f - Frequency - Hz 5k 10k 20k Figure 7. Figure 8. TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY 10 10 VDD = 5 V, RL = 4 Ω,, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V, CI = 2 µF 5 2 1 THD+N - Total Harmonic Distortion + Noise - % THD+N - Total Harmonic Distortion + Noise - % VDD = 5 V, RL = 3 Ω,, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V, CI = 2 µF 5 2W 0.5 1.8 W 0.2 1W 0.1 0.05 0.02 0.01 VDD = 3.6 V, RL = 4 Ω,, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V, CI = 2 µF 5 2 1 0.5 1W 0.1 W 0.2 0.5 W 0.1 0.05 0.02 0.01 0.005 0.002 0.001 0.005 20 50 100 200 500 1k 2k f - Frequency - Hz Figure 9. 5k 10k 20k 20 50 100 200 500 1k 2k f - Frequency - Hz 5k 10k 20k Figure 10. 7 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY 10 VDD = 2.5 V, RL = 4 Ω,, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V, CI = 2 µF 5 2 1 THD+N - Total Harmonic Distortion + Noise - % THD+N - Total Harmonic Distortion + Noise - % 10 TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY 0.5 0.4 W 0.2 0.28 W 0.1 0.05 0.02 0.01 0.005 0.002 0.001 50 100 200 500 1k 2k f - Frequency - Hz 5k 1 0.5 0.25 W 0.6 W 0.2 0.1 W 0.1 0.05 0.02 0.01 0.005 0.002 10k 20k 20 k SVR - Supply Voltage Rejection Ratio - dB VDD = 2.5 V 0.05 VDD = 5 V 0.048 0.046 VDD = 3.6 V 0.044 0.042 0.04 10k 20k SUPPLY VOLTAGE REJECTION RATIO vs FREQUENCY 0.054 0.052 5k TOTAL HARMONIC DISTORTION + NOISE vs COMMON MODE INPUT VOLTAGE +0 0.056 100 200 500 1k 2k f - Frequency - Hz Figure 12. f = 1 kHz PO = 200 mW, RL = 1 kHz 0.058 50 Figure 11. 0.06 THD+N - Total Harmonic Distortion + Noise - % 2 0.001 20 -10 -20 RL = 4 Ω,, C(BYPASS) = 0.47 µF, Gain = 1 V/V, CI = 2 µF, Inputs ac Grounded -30 -40 -50 -60 VDD = 3.6 V VDD = 2.5 V -70 -80 -90 VDD = 5 V -100 0 1 2 3 4 VIC - Common Mode Input Voltage - V Figure 13. 8 VDD = 3.6 V, RL = 8 Ω,, C(BYPASS) = 0 to 1 µF, Gain = 1 V/V, CI = 2 µF 5 5 20 50 100 200 500 1k f - Frequency - Hz Figure 14. 2k 5k 10k 20k TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 SUPPLY VOLTAGE REJECTION RATIO vs FREQUENCY -10 -20 -30 +0 RL = 4 Ω,, C(BYPASS) = 0.47 µF, Gain = 5 V/V, CI = 2 µF, Inputs ac Grounded k SVR - Supply Voltage Rejection Ratio - dB k SVR - Supply Voltage Rejection Ratio - dB +0 -40 -50 VDD = 2.5 V -60 VDD = 3.6 V -70 -80 VDD = 5 V -90 -100 20 50 100 200 SUPPLY RIPPLE REJECTION RATIO vs FREQUENCY 500 1k 2k 5k RL = 4 Ω,, C(BYPASS) = 0.47 µF, CI = 2 µF, VDD = 2.5 V to 5 V Inputs Floating -10 -20 -30 -40 -50 -60 -70 -80 -90 -100 10k 20k 20 50 100 200 f - Frequency - Hz −10 −20 SUPPLY VOLTAGE REJECTION RATIO vs DC COMMON MODE INPUT 0 RL = 4 Ω,, CI = 2 µF, Gain = 1 V/V, VDD = 3.6 V C(BYPASS) = 0.1 µF −60 No C(BYPASS) −70 −80 −100 20 10k 20k SUPPLY VOLTAGE REJECTION RATIO vs FREQUENCY −40 −90 5k Figure 16. −30 −50 2k Figure 15. k SVR − Supply Voltage Rejection Ratio − dB k SVR − Supply Voltage Rejection Ratio − dB +0 500 1k f - Frequency - Hz C(BYPASS) = 1 µF C(BYPASS) = 0.47 µF 50 100 200 500 1k 2k f − Frequency − Hz Figure 17. 5k 10k 20k RL = 4 Ω,, CI = 2 µF, Gain = 1 V/V, C(BYPASS) = 0.47 µF VDD = 3.6 V, f = 217 Hz, Inputs ac Grounded −10 −20 −30 −40 VDD = 2.5 V VDD = 3.6 V −50 −60 −70 VDD = 5 V −80 −90 −100 0 1 2 3 4 DC Common Mode Input − V 5 6 Figure 18. 9 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 GSM POWER SUPPLY REJECTION vs TIME VDD Voltage − V C1 Frequency 217 Hz C1 − Duty 20% C1 Pk−Pk 500 mV RL = 8 Ω CI = 2.2 µF VOUT C(BYPASS) = 0.47 µF 2 ms/div Ch1 100 mV/div Ch4 10 mV/div t − Time − ms Figure 19. 0 −50 VO − Output Voltage − dBV −100 VDD Shown in Figure 19, RL = 8 Ω, CI = 2.2 µF, Inputs Grounded −100 −120 −140 −160 −180 0 C(BYPASS) = 0.47 µF 400 800 1200 f − Frequency − Hz 1600 Figure 20. 10 −150 2000 VDD − Supply Voltage − dBV GSM POWER SUPPLY REJECTION vs FREQUENCY TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 COMMON MODE REJECTION RATIO vs FREQUENCY -20 -30 -40 VDD = 2.5 V -50 -60 -70 VDD = 5 V -80 -90 -100 20 50 100 200 500 1k 2k 5k -20 -30 -40 -50 VDD = 2.5 V -60 -80 0 0.5 180 100 150 90 3.5 -20 0 -30 -30 -40 -60 -50 -90 VDD = 5 V RL = 8 Ω AV = 1 -120 -150 -180 -80 Figure 23. 5 1M 10 M 120 90 60 Gain 50 Gain − dB 30 Phase - Degrees 60 Gain -10 1 k 10 k 100 k f - Frequency - Hz 4.5 150 70 90 100 4 180 VDD = 5 V, RL = 8 Ω 80 120 10 Gain - dB 3 OPEN LOOP GAIN/PHASE vs FREQUENCY 20 10 2.5 CLOSED LOOP GAIN/PHASE vs FREQUENCY 30 1 2 Figure 22. Phase -70 1.5 Figure 21. 40 -60 1 VIC - Common Mode Input Voltage - V f - Frequency - Hz 0 VDD = 5 V VDD = 3.5 V -70 -90 10k 20k RL = 4 Ω,, Gain = 1 V/V, dc Change in VIC -10 60 40 30 30 0 20 −30 10 −60 Phase 0 −10 Phase − Degrees -10 0 RL = 4 Ω,, VIC = 200 mV Vp-p, Gain = 1 V/V, CMRR - Common Mode Rejection Ratio - dB CMRR - Common-Mode Rejection Ratio - dB +0 COMMON-MODE REJECTION RATIO vs COMMON-MODE INPUT VOLTAGE −90 −20 −120 −30 −150 −40 100 1k 10 k 100 k f − Frequency − Hz −180 1M Figure 24. 11 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 SUPPLY CURRENT vs SUPPLY VOLTAGE 5 10 VDD = 5 V TA = 125°C 4.5 VDD = 5 V 1 4 I DD - Supply Current - mA I DD - Supply Current - mA SUPPLY CURRENT vs SHUTDOWN VOLTAGE TA = 25°C 3.5 3 TA = -40°C 2.5 2 1.5 1 VDD = 3.6 V 0.1 VDD = 2.5 V 0.01 0.001 0.0001 0.5 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 0.00001 VDD - Supply Voltage - V 1 2 3 4 5 Voltage on SHUTDOWN Terminal - V Figure 25. Figure 26. 0 START-UP TIME vs BYPASS CAPACITOR 300 Start-Up Time - ms 250 200 150 100 50 0 0 0.2 0.4 0.6 0.8 C(Bypass) - Bypass Capacitor - µF Figure 27. 12 1 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 APPLICATION INFORMATION • Mid-supply bypass capacitor, C(BYPASS), not required: The fully differential amplifier does not require a bypass capacitor. Any shift in the mid-supply voltage affects both positive and negative channels equally, thus canceling at the differential output. Removing the bypass capacitor slightly worsens power supply rejection ratio (kSVR), but a slight decrease of kSVR may be acceptable when an additional component can be eliminated (See Figure 17). Better RF-immunity: GSM handsets save power by turning on and shutting off the RF transmitter at a rate of 217 Hz. The transmitted signal is picked-up on input and output traces. The fully differential amplifier cancels the signal much better than the typical audio amplifier. FULLY DIFFERENTIAL AMPLIFIER The TPA6211A1 is a fully differential amplifier with differential inputs and outputs. The fully differential amplifier consists of a differential amplifier and a common- mode amplifier. The differential amplifier ensures that the amplifier outputs a differential voltage that is equal to the differential input times the gain. The common-mode feedback ensures that the common-mode voltage at the output is biased around VDD/2 regardless of the common- mode voltage at the input. • Advantages of Fully Differential Amplifiers • Input coupling capacitors not required: A fully differential amplifier with good CMRR, like the TPA6211A1, allows the inputs to be biased at voltage other than mid-supply. For example, if a DAC has a lower mid-supply voltage than that of the TPA6211A1, the common-mode feedback circuit compensates, and the outputs are still biased at the mid-supply point of the TPA6211A1. The inputs of the TPA6211A1 can be biased from 0.5 V to VDD - 0.8 V. If the inputs are biased outside of that range, input coupling capacitors are required. APPLICATION SCHEMATICS Figure 28 through Figure 31 show application schematics for differential and single-ended inputs. Typical values are shown in Table 1. Table 1. Typical Component Values COMPONENT VALUE RI 40 kΩ C(BYPASS) (1) 1 µF CI 0.22 µF C(BYPASS) is optional. 4 IN− + RI 3 IN+ _ VO− 8 1 C(BYPASS)(1) 2 (1) VO+ 5 + 40 kΩ SHUTDOWN To Battery Cs 40 kΩ In From DAC 0.22 µF CS VDD 6 − RI (1) GND 7 Bias Circuitry 100 kΩ C(BYPASS) is optional Figure 28. Typical Differential Input Application Schematic 13 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 VDD 6 CI − 4 IN− + RI 3 IN+ CI _ VO+ 5 VO− 8 + 40 kΩ 1 SHUTDOWN C(BYPASS)(1) (1) Cs 40 kΩ RI To Battery GND 7 Bias Circuitry 100 kΩ 2 C(BYPASS) is optional Figure 29. Differential Input Application Schematic Optimized With Input Capacitors VDD 6 CI IN 4 IN− RI 3 IN+ CI 40 kΩ SHUTDOWN C(BYPASS)(1) (1) Cs 40 kΩ RI 1 To Battery _ VO+ 5 VO− 8 + GND 7 Bias Circuitry 100 kΩ 2 C(BYPASS) is optional Figure 30. Single-Ended Input Application Schematic 14 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 CF CF VDD 6 Ra − CI Ca Ra 4 IN− RI 3 IN+ CI + _ SHUTDOWN C(BYPASS)(1) VO+ 5 VO− 8 + 40 kΩ Ca (1) Cs 40 kΩ RI To Battery 1 GND 7 Bias Circuitry 100 kΩ 2 C(BYPASS) is optional Figure 31. Differential Input Application Schematic With Input Bandpass Filter Input Capacitor (CI) Selecting Components Resistors (RI) The input resistor (RI) can be selected to set the gain of the amplifier according to equation 1. Gain = RF/RI (1) The internal feedback resistors (RF) are trimmed to 40 kΩ. Resistor matching is very important in fully differential amplifiers. The balance of the output on the reference voltage depends on matched ratios of the resistors. CMRR, PSRR, and the cancellation of the second harmonic distortion diminishes if resistor mismatch occurs. Therefore, 1%-tolerance resistors or better are recommended to optimize performance. The TPA6211A1 does not require input coupling capacitors when driven by a differential input source biased from 0.5 V to VDD - 0.8 V. Use 1% tolerance or better gain-setting resistors if not using input coupling capacitors. In the single-ended input application, an input capacitor, CI, is required to allow the amplifier to bias the input signal to the proper dc level. In this case, CI and RI form a high-pass filter with the corner frequency defined in Equation 2. 1 fc 2 R C I I (2) -3 dB Bypass Capacitor (CBYPASS) and Start-Up Time The internal voltage divider at the BYPASS pin of this device sets a mid-supply voltage for internal references and sets the output common mode voltage to VDD/2. Adding a capacitor filters any noise into this pin, increasing kSVR. C(BYPASS)also determines the rise time of VO+ and VO- when the device exits shutdown. The larger the capacitor, the slower the rise time. fc 15 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 The value of CI is an important consideration. It directly affects the bass (low frequency) performance of the circuit. Consider the example where RI is 10 kΩ and the specification calls for a flat bass response down to 100 Hz. Equation 2 is reconfigured as Equation 3. 1 C I 2 R f c I (3) In this example, CI is 0.16 µF, so the likely choice ranges from 0.22 µF to 0.47 µF. Ceramic capacitors are preferred because they are the best choice in preventing leakage current. When polarized capacitors are used, the positive side of the capacitor faces the amplifier input in most applications. The input dc level is held at VDD/2, typically higher than the source dc level. It is important to confirm the capacitor polarity in the application. Band-Pass Filter (Ra, Ca, and Ca) It may be desirable to have signal filtering beyond the one-pole high-pass filter formed by the combination of CI and RI. A low-pass filter may be added by placing a capacitor (CF) between the inputs and outputs, forming a band-pass filter. An example of when this technique might be used would be in an application where the desirable pass-band range is between 100 Hz and 10 kHz, with a gain of 4 V/V. The following equations illustrate how the proper values of CF and CI can be determined. 1 c(LPF) 2 R C F F where R is the internal 40 k resistor F 1 f c(LPF) 2 40 k C F (8) Therefore, 1 C I 2 10 k f c(HPF) (9) Substituting 100 Hz for fc(HPF) and solving for CI: CI = 0.16 µF At this point, a first-order band-pass filter has been created with the low-frequency cutoff set to 100 Hz and the high-frequency cutoff set to 10 kHz. The process can be taken a step further by creating a second-order high-pass filter. This is accomplished by placing a resistor (Ra) and capacitor (Ca) in the input path. It is important to note that Ra must be at least 10 times smaller than RI; otherwise its value has a noticeable effect on the gain, as Ra and RI are in series. Step 3: Additional Low-Pass Filter Ra must be Set Ra = 1 kΩ f c(LPF) at least 10x smaller than 1 2 R a Ca RI, (10) Therefore, Ca Step 1: Low-Pass Filter f Substituting RI into equation 6. 1 f c(HPF) 2 10 k C I 1 2 1kΩ f c(LPF) (11) Substituting 10 kHz for fc(LPF) and solving for Ca: (4) (5) Therefore, Ca = 160 pF Figure 32 is a bode plot for the band-pass filter in the previous example. Figure 31 shows how to configure the TPA6211A1 as a band-pass filter. AV 1 C F 2 40 k f c(LPF) (6) 12 dB 9 dB Substituting 10 kHz for fc(LPF) and solving for CF: −20 dB/dec +20 dB/dec CF = 398 pF −40 dB/dec Step 2: High-Pass Filter 1 2 R C I I where R is the input resistor I f c(HPF) fc(HPF) = 100 Hz Figure 32. Bode Plot (7) Since the application in this case requires a gain of 4 V/V, RI must be set to 10 kΩ. 16 fc(LPF) = 10 kHz f TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 V Decoupling Capacitor (CS) The TPA6211A1 is a high-performance CMOS audio amplifier that requires adequate power supply decoupling to ensure the output total harmonic distortion (THD) is as low as possible. Power-supply decoupling also prevents oscillations for long lead lengths between the amplifier and the speaker. For higher frequency transients, spikes, or digital hash on the line, a good low equivalent-series-resistance (ESR) ceramic capacitor, typically 0.1 µF to 1 µF, placed as close as possible to the device VDD lead works best. For filtering lower frequency noise signals, a 10-µF or greater capacitor placed near the audio power amplifier also helps, but is not required in most applications because of the high PSRR of this device. USING LOW-ESR CAPACITORS Low-ESR capacitors are recommended throughout this applications section. A real (as opposed to ideal) capacitor can be modeled simply as a resistor in series with an ideal capacitor. The voltage drop across this resistor minimizes the beneficial effects of the capacitor in the circuit. The lower the equivalent value of this resistance the more the real capacitor behaves like an ideal capacitor. DIFFERENTIAL OUTPUT VERSUS SINGLE-ENDED OUTPUT Figure 33 shows a Class-AB audio power amplifier (APA) in a fully differential configuration. The TPA6211A1 amplifier has differential outputs driving both ends of the load. One of several potential benefits to this configuration is power to the load. The differential drive to the speaker means that as one side is slewing up, the other side is slewing down, and vice versa. This in effect doubles the voltage swing on the load as compared to a ground-referenced load. Plugging 2 × VO(PP) into the power equation, where voltage is squared, yields 4× the output power from the same supply rail and load impedance Equation 12. V (rms) V Power O(PP) 2 2 2 (rms) R L (12) VDD VO(PP) RL 2x VO(PP) VDD -VO(PP) Figure 33. Differential Output Configuration In a typical wireless handset operating at 3.6 V, bridging raises the power into an 8-Ω speaker from a singled-ended (SE, ground reference) limit of 200 mW to 800 mW. This is a 6-dB improvement in sound power—loudness that can be heard. In addition to increased power, there are frequency-response concerns. Consider the single-supply SE configuration shown in Figure 34. A coupling capacitor (CC) is required to block the dc-offset voltage from the load. This capacitor can be quite large (approximately 33 µF to 1000 µF) so it tends to be expensive, heavy, occupy valuable PCB area, and have the additional drawback of limiting low-frequency performance. This frequency-limiting effect is due to the high-pass filter network created with the speaker impedance and the coupling capacitance. This is calculated with Equation 13. 1 fc 2 R C L C (13) For example, a 68-µF capacitor with an 8-Ω speaker would attenuate low frequencies below 293 Hz. The BTL configuration cancels the dc offsets, which eliminates the need for the blocking capacitors. Low-frequency performance is then limited only by the input network and speaker response. Cost and PCB space are also minimized by eliminating the bulky coupling capacitor. 17 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 VDD VO(PP) CC RL VO(PP) An easy-to-use equation to calculate efficiency starts out as being equal to the ratio of power from the power supply to the power delivered to the load. To accurately calculate the RMS and average values of power in the load and in the amplifier, the current and voltage waveform shapes must first be understood (see Figure 35). VO -3 dB V(LRMS) IDD fc Figure 34. Single-Ended Output and Frequency Response Increasing power to the load does carry a penalty of increased internal power dissipation. The increased dissipation is understandable considering that the BTL configuration produces 4× the output power of the SE configuration. FULLY DIFFERENTIAL AMPLIFIER EFFICIENCY AND THERMAL INFORMATION Class-AB amplifiers are inefficient, primarily because of voltage drop across the output-stage transistors. The two components of this internal voltage drop are the headroom or dc voltage drop that varies inversely to output power, and the sinewave nature of the output. The total voltage drop can be calculated by subtracting the RMS value of the output voltage from VDD. The internal voltage drop multiplied by the average value of the supply current, IDD(avg), determines the internal power dissipation of the amplifier. 18 IDD(avg) Figure 35. Voltage and Current Waveforms for BTL Amplifiers Although the voltages and currents for SE and BTL are sinusoidal in the load, currents from the supply are different between SE and BTL configurations. In an SE application the current waveform is a half-wave rectified shape, whereas in BTL it is a full-wave rectified waveform. This means RMS conversion factors are different. Keep in mind that for most of the waveform both the push and pull transistors are not on at the same time, which supports the fact that each amplifier in the BTL device only draws current from the supply for half the waveform. The following equations are the basis for calculating amplifier efficiency. TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 P Efficiency of a BTL amplifier P L SUP Where: 2 V rms 2 V V P L , and V P , therefore, P P L LRMS L 2 R 2R L L and P SUP V DD I DDavg and I avg 1 DD 2V V P P sin(t) dt 1 P [cos(t)] 0 R R R L L 0 L V Therefore, 2V P SUP V DD P R L substituting PL and PSUP into equation 6, 2 Efficiency of a BTL amplifier Where: V P VP 2 RL 2 V DD V P RL VP 4 VDD 2 PL RL PL = Power delivered to load PSUP = Power drawn from power supply VLRMS = RMS voltage on BTL load RL = Load resistance VP = Peak voltage on BTL load IDDavg = Average current drawn from the power supply VDD = Power supply voltage ηBTL = Efficiency of a BTL amplifier (14) Therefore, BTL 2 PL RL 4V DD (15) Table 2. Efficiency and Maximum Ambient Temperature vs Output Power Output Power (W) Efficiency (%) Internal Dissipation (W) Power From Supply (W) Max Ambient Temperature (°C) 0.5 27.2 1.34 1.84 85 (2) (1) 5-V, 3-Ω Systems 1 38.4 1.60 2.60 76 2.45 60.2 1.62 4.07 75 3.1 67.7 1.48 4.58 82 5-V, 4-Ω BTL Systems 0.5 31.4 1.09 1.59 85 (2) 1 44.4 1.25 2.25 85 (2) 2 62.8 1.18 3.18 85 (2) 2.8 74.3 0.97 3.77 85 (2) 0.5 44.4 0.625 1.13 85 (2) 1 62.8 0.592 1.60 85 (2) 1.36 73.3 0.496 1.86 85 (2) 1.7 81.9 0.375 2.08 85 (2) 5-V, 8-Ω Systems (1) (2) DRB package Package limited to 85°C ambient 19 TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 Table 2 employs Equation 15 to calculate efficiencies for four different output power levels. Note that the efficiency of the amplifier is quite low for lower power levels and rises sharply as power to the load is increased resulting in a nearly flat internal power dissipation over the normal operating range. Note that the internal dissipation at full output power is less than in the half power range. Calculating the efficiency for a specific system is the key to proper power supply design. For a 2.8-W audio system with 4-Ω loads and a 5-V supply, the maximum draw on the power supply is almost 3.8 W. A final point to remember about Class-AB amplifiers is how to manipulate the terms in the efficiency equation to the utmost advantage when possible. Note that in Equation 15, VDD is in the denominator. This indicates that as VDD goes down, efficiency goes up. A simple formula for calculating the maximum power dissipated, PDmax, may be used for a differential output application: 2V2 DD P Dmax 2R L (16) PDmax for a 5-V, 4-Ω system is 1.27 W. 20 The maximum ambient temperature depends on the heat sinking ability of the PCB system. The derating factor for the 3 mm x 3 mm DRB package is shown in the dissipation rating table. Converting this to θJA: 1 1 θ 45.9°CW JA 0.0218 Derating Factor (17) Given θJA, the maximum allowable junction temperature, and the maximum internal dissipation, the maximum ambient temperature can be calculated with Equation 18. The maximum recommended junction temperature for the TPA6211A1 is 150°C. T A Max T J Max θJA P Dmax 150 45.9(1.27) 91.7°C (18) Equation 18 shows that the maximum ambient temperature is 91.7°C (package limited to 85°C ambient) at maximum power dissipation with a 5-V supply. Table 2 shows that for most applications no airflow is required to keep junction temperatures in the specified range. The TPA6211A1 is designed with thermal protection that turns the device off when the junction temperature surpasses 150°C to prevent damage to the IC. In addition, using speakers with an impedance higher than 4-Ω dramatically increases the thermal performance by reducing the output current. TPA6211A1 www.ti.com SLOS367B – AUGUST 2003 – REVISED AUGUST 2004 PCB LAYOUT Use the following land pattern for board layout with the 8-pin QFN (DRB) package. Note that the solder paste should use a hatch pattern to fill solder paste at 50% to ensure that there is not too much solder paste under the package. 0.7 mm 0.33 mm plugged vias (5 places) 1.4 mm 0.38 mm 0.65 mm 1.95 mm Solder Mask: 1.4 mm x 1.85 mm centered in package Make solder paste a hatch pattern to fill 50% 3.3 mm Figure 36. TPA6211A1 8-Pin QFN (DRB) Board Layout (Top View) 21 PACKAGE OPTION ADDENDUM www.ti.com 18-Apr-2006 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty TPA6211A1DGN ACTIVE MSOPPower PAD DGN 8 80 Green (RoHS & no Sb/Br) CU NIPDAU Level-1-260C-UNLIM TPA6211A1DGNG4 ACTIVE MSOPPower PAD DGN 8 80 Green (RoHS & no Sb/Br) CU NIPDAU Level-1-260C-UNLIM TPA6211A1DGNR ACTIVE MSOPPower PAD DGN 8 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-1-260C-UNLIM TPA6211A1DGNRG4 ACTIVE MSOPPower PAD DGN 8 2500 Green (RoHS & no Sb/Br) CU NIPDAU Level-1-260C-UNLIM TPA6211A1DRB ACTIVE SON DRB 8 121 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR TPA6211A1DRBG4 ACTIVE SON DRB 8 121 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR TPA6211A1DRBR ACTIVE SON DRB 8 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR TPA6211A1DRBRG4 ACTIVE SON DRB 8 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. 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