| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
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NXP Semiconductors |
IC AMP CLASS AB STEREO 1.5W 20SO |
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NXP Semiconductors |
IC AMP CLASS B QUAD 40W DBS23P |
0 |
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NXP Semiconductors |
IC AMP CLASS B STEREO 55W DBS17P |
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NXP Semiconductors |
IC AMP CLASS B QUAD 45W DBS23P |
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NXP Semiconductors |
IC AMPLIFIER CLASS D 100HLQFP |
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NXP Semiconductors |
IC AMP CLASS AB QUAD 28W DBS27P |
0 |
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NXP Semiconductors |
IC AMP CLSS AB STER 2.2W 20HVQFN |
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NXP Semiconductors |
IC AMP CLASS AB QUAD 64W DBS27P |
0 |
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NXP Semiconductors |
IC AMP B MONO/STEREO 8W 20HTSSOP |
0 |
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NXP Semiconductors |
IC AMP CLASS D STER 15W 48HVQFN |
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NXP Semiconductors |
IC AMP B/H MONO 70W DBS17P |
0 |
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NXP Semiconductors |
IC AMP D MONO/STEREO 88W 24HSOP |
0 |
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NXP Semiconductors |
IC AMP B MONO/STEREO 8W 20HTSSOP |
0 |
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NXP Semiconductors |
IC AMP D MONO/STEREO 160W 24HSOP |
0 |
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NXP Semiconductors |
IC AMP CLASS D MONO 3W 10HVSON |
0 |
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NXP Semiconductors |
IC AMP B DUAL/QUAD 24W DBS17P |
0 |
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NXP Semiconductors |
IC AMP CLASS D MONO 3.4W 9WLCSP |
0 |
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NXP Semiconductors |
IC AMP CLASS AB MONO 15W 9SIL |
0 |
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NXP Semiconductors |
IC AMP CLASS AB STEREO 7W 9PDBS |
0 |
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NXP Semiconductors |
IC AMP CLSS B MONO/STER 22W 9SMS |
0 |
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Linear audio amplifiers are electronic devices designed to amplify low-level audio signals while maintaining signal integrity and minimizing distortion. They operate in the linear region of transistor characteristics, ensuring high-fidelity sound reproduction. These amplifiers are critical in audio systems for applications ranging from consumer electronics to professional audio equipment, enabling clear sound amplification in devices such as smartphones, home theaters, and musical instruments.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Class AB Amplifiers | Combines efficiency of Class B with low distortion of Class A | Home audio systems, guitar amplifiers |
| Class D Amplifiers | Switching amplifiers with high power efficiency (typically >90%) | Portable speakers, automotive audio systems |
| Class G/H Amplifiers | Uses multiple power rails to improve efficiency | Professional audio mixers, high-power amplifiers |
| Class A Amplifiers | Full-cycle conduction with minimal distortion | High-end audiophile equipment, preamplifiers |
Typical linear audio amplifiers consist of: - Input Stage: Differential amplifier for signal reception - Gain Stage: Voltage amplification using transistors or op-amps - Output Stage: Push-pull configuration for power delivery - Power Supply: Symmetrical voltage rails ( Vcc) - Thermal Management: Heat sinks or thermal pads for power dissipation Packaged in DIP, SOIC, or surface-mount (SMT) formats with 8-14 pins.
| Parameter | Description | Importance |
|---|---|---|
| Gain Bandwidth Product (GBW) | Product of amplifier gain and operational bandwidth | Determines frequency response capability |
| Total Harmonic Distortion + Noise (THD+N) | Measure of signal distortion and noise | Indicates audio quality (typically <0.1%) |
| Output Power | Maximum power delivered to load (Watts) | Defines application suitability (e.g., 2x15W for stereo) |
| Power Supply Rejection Ratio (PSRR) | Ability to reject power supply noise | Impacts noise immunity (typically >60dB) |
| Quiescent Current | Current consumption at no-load condition | Affects power efficiency and thermal design |
| Manufacturer | Representative Product | Key Specifications |
|---|---|---|
| TI (Texas Instruments) | TPA3255 | 2x75W Class D amplifier, 102dB PSRR |
| STMicroelectronics | TDA7294 | 100W Hi-Fi amplifier, DMOS output stage |
| Analog Devices | AD822 | Low noise JFET input amplifier |
| NXP Semiconductors | TDA1541A | 192kHz DAC with integrated headphone amplifier |
Key considerations for selection: 1. Application Requirements: Output power, frequency range, and load impedance 2. Power Supply Constraints: Available voltage/current capacity 3. Thermal Management: Operating temperature range and cooling methods 4. Form Factor: Package size for PCB integration 5. Cost vs. Performance: Balancing THD+N, efficiency, and budget
Future developments include: - Increased integration with digital signal processing (DSP) - Adoption of GaN (Gallium Nitride) technology for higher efficiency - Development of AI-powered noise cancellation algorithms - Miniaturization through 3D packaging techniques - Enhanced Class D amplifier designs with reduced electromagnetic interference (EMI)