Figure 1 shows the basic setup for a Single-Ended (SE) to Differential (Diff) input stage used with the TPA32xx amplifier. In this use case, the amplifier is configured for BTL output and requires “Input_A” and “Input_B” to be driven differentially. A pair of inverting Op-amps is used where the Op-amp gain is set to –1. By cascading the operational-amplifiers as shown, the analog signal from the RCA jack labeled “SE Input” appears on both “Input_A” and “Input_B” of the TPA32xx amplifier out of phase with each other.
These operational-amplifiers also run from a single 12 V supply rail to reduce cost. In order to pass analog signals that swing below ground, the operational-amplifiers are biased to the mid rail (6 V) using a resistor divider and filter. Then DC blocking capacitors are used to isolate the Op-amp bias voltage from a ground referenced analog input.
This cost effective SE to Diff converter works quite well; however, since this design is not using a truly differential operational-amplifier stage, there will always be some imbalance between “Input_A” and “Input_B” with this configuration and less than ideal common mode (CM) rejection.
Figure 1. Cost Effective SE to Diff Input Stage
Now suppose that all of the ground points for the input stage are tied to the ground plane at the most convenient locations, as typically done in PCB layout (Figure 2).
At high output power, the ground plane used for the TPA32xx amplifier will start to see heavy current flow and switching noise. This is generally worse at lower audio frequencies where the sustained amplitude of the audio signal peaks is longer when compared to higher frequency signals. This can cause lots of noise on the ground plane.
Figure 2. SE to Diff Input Stage Ground Plane Noise
Due to the heavy current flow into the ground plane as represented by the arrow “Ipower” noise voltages Vn1, Vn2, and Vn3 develop across the ground plane. Therefore, the ground nodes for the input stage G2, G3, and G4 will all be at different potentials relative to the TPA32xx amplifier analog ground reference G1.
Since our Op-amp input stage is not truly differential with poor CM rejection, signal imbalance is inevitable. It is likely that a differential noise voltage due to Vn1, Vn2, and Vn3 develop between “Input_A” and “Input_B” and is amplified by the TPA32xx amplifier.
This results in degraded low frequency audio performance.
To fix this issue of different THD+N results between stereo channels at 100 Hz is simply ground plane noise, G2, G3, and G4 input stage ground nodes were connected with separate traces directly to the TPA32xx amplifier analog ground reference, G1. With this star ground connection scheme, G1 G2 G3 and G4 are well coupled and share the same ground potential. Therefore, no noise voltage can be developed between the input stage grounds and the TPA32xx analog ground. Figure 3 shows this connection scheme.
Figure 3. SE to Diff Input Stage Star Ground
For reference, the pinout of the analog and power ground pins on the TPA32xx devices are listed below.
| TPA32xx Class-D Amplifier Ground Pins | ||
| Amplifier | Analog Ground Pins | Power Ground Pins |
| TPA3244 | 10, 11 | 25, 26, 33, 34, 41, 42 |
| TPA3245 | 12, 13 | 25, 26, 33, 34, 41, 42 |
| TPA3250 | 10, 11 | 25, 26, 33, 34, 41, 42 |
| TPA3251 | 12, 13 | 25, 26, 33, 34, 41, 42 |
| TPA3255 | 12, 13 | 25, 26, 33, 34, 41, 42 |
| 部品番号 | 説明 | |
|---|---|---|
| TPA3200D1DCPR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR 20W D 44TSSOP | RFQ |
| TPA3200D1DCPG4 Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR 20W D 44TSSOP | RFQ |
| TPA3200D1DCP Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR 20W D 44TSSOP | RFQ |
| TPA3250D2DDW Texas Instruments |
リニア - アンプ - オーディオ, IC POWER AMP CLASS D 44HTSSOP | RFQ |
| TPA3244DDW Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO CLASS D 44HTSSOP | RFQ |
| TPA3251D2DDVR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR 44HTSSOP | RFQ |
| TPA321DG4 Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8SOIC | RFQ |
| TPA321DGNRG4 Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8MSOP | RFQ |
| TPA321DGNR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8MSOP | RFQ |
| TPA321DGN Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8MSOP | RFQ |
| TPA3255DDV Texas Instruments |
リニア - アンプ - オーディオ, IC AUDIO AMP CLASS D 44HTSSOP | RFQ |
| TPA3245DDV Texas Instruments |
リニア - アンプ - オーディオ, IC AUDIO AMP CLASS D 44HTSSOP | RFQ |
| TPA3255DDVR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO CLASS D 44HTSSOP | RFQ |
| TPA3250D2DDWR Texas Instruments |
リニア - アンプ - オーディオ, IC POWER AMP CLASS D 44HTSSOP | RFQ |
| TPA3245DDVR Texas Instruments |
リニア - アンプ - オーディオ, IC AUDIO AMP CLASS D 44HTSSOP | RFQ |
| TPA3244DDWR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO CLASS D 44-HTSSOP | RFQ |
| TPA321DR Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8SOIC | RFQ |
| TPA321D Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR .7W MONO 8SOIC | RFQ |
| TPA3251D2DDV Texas Instruments |
リニア - アンプ - オーディオ, IC AMP AUDIO PWR 44HTSSOP | RFQ |
Traction inverters are the main battery drain components in electric vehicles (EVs), with power levels up to 150kW or higher. The efficiency and performance of traction inverter directly affect the driving range of electric vehicle after a single charge. Therefore, in order to build the next generation of traction inverter systems, silicon carbide (SiC) field effect transistor (FET) is widely used in the industry to achieve higher reliability, efficiency and power density.
Do you know the 8 application circuits of operational amplifiers?
This technical presentation requires an understanding of how to configure an operational amplifier in a typical gain control circuit. The applications of linear and nonlinear digital potentiometers are discussed. This article gives an overview of the basic techniques required to convert audio and other potentiometer/op amp applications from conventional mechanical potentiometers to solid state potentiometers
The current in an electronic circuit usually has to be limited. In USB ports, for example, excessive current must be prevented to provide reliable protection for the circuit. Also in the power bank, the battery must be prevented from discharging. Too high discharge current results in too large voltage drop of the battery and insufficient supply voltage of downstream devices
Using advanced real-time control technologies such as motor control circuits with higher power density, higher integration and more efficient systems, better acoustic performance of the system can be achieved
Brushless direct current (BLDC) motors have been widely used in household appliances, industrial equipment and automobiles. While brushless DC motors offer a more reliable and maintainable alternative to traditional brushless motors, they require more sophisticated electronics to drive them
How to achieve precise motion control in industrial actuators
The NCP51820 is a 650 V, high-speed, half-bridge driver capable of driving gallium nitride (" GaN ") power switches at dV/dt rates up to 200 V/ns. The full performance advantages of high voltage, high frequency and fast dV/dt edge rate switches can only be realized if the printed circuit board (PCB) can be properly designed to support this power switch. This paper will briefly introduce NCP51820 and the key points of PCB design of high performance GaN half bridge grid driver circuit using NCP51820
