Interface - Filters

Interface - Filters - Active

Part Number	Description / PDF	Quantity
HSP43220JC-25 Intersil (Renesas Electronics America)	DECIMATING DIGITAL FILTER	420
HSP43168JC-33 Intersil (Renesas Electronics America)	DAUL FIR FILTER	822
HSP43124SI-40 Intersil (Renesas Electronics America)	DIGITAL FILTER, MOS	1006
HSP48901JC-30 Intersil (Renesas Electronics America)	DIGITAL FILTER, 8-BIT PQCC68	742
HSP43216JC-52 Intersil (Renesas Electronics America)	HALFBAND FILTER	1135
HSP43124SC-45 Intersil (Renesas Electronics America)	SERIAL I/O FILTER	0
HSP43168JI-40 Intersil (Renesas Electronics America)	DIGITAL FILTER, 10-BIT PQCC84	710
HSP43220JC-33 Intersil (Renesas Electronics America)	DIGITAL FILTER, 16-BI	155
HSP43881JC-25 Intersil (Renesas Electronics America)	DIGITAL FILTER, 8-BIT PQCC84	615
HSP43216JC-52S2485 Intersil (Renesas Electronics America)	HALFBAND FILTER	75
HSP43220JC-25Z Intersil (Renesas Electronics America)	IC FILTER DIGITAL 84PLCC	0
HSP43220JC-33Z Intersil (Renesas Electronics America)	IC FILTER DIGITAL 84PLCC	0
HSP43216JC-52Z Intersil (Renesas Electronics America)	IC FILTER HALF BAND 84PLCC	0
HSP43124SC-45Z Intersil (Renesas Electronics America)	IC FILTER SERIAL I/O 28SOIC	0
HSP43168JC-33Z Intersil (Renesas Electronics America)	IC FILTER FIR 84PLCC	0
HSP43216VC-52Z Intersil (Renesas Electronics America)	IC FILTER HALF BAND 100MQFP	0

Interface - Filters - Active

1. Overview

Active filters are electronic integrated circuits (ICs) that use active components (e.g., operational amplifiers) combined with passive elements (resistors, capacitors) to selectively attenuate or amplify specific frequency ranges. Unlike passive filters, active filters can provide gain, high input impedance, and low output impedance. They are critical in modern electronics for signal conditioning, noise suppression, and frequency domain processing in communication systems, audio equipment, and industrial control systems.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Low-Pass Filter (LPF)	Attenuates frequencies above cutoff; smooths signals	Audio DAC output filtering, ECG signal processing
High-Pass Filter (HPF)	Blocks DC components and low-frequency noise	Speaker crossover networks, AC coupling circuits
Band-Pass Filter (BPF)	Allows frequencies within a specific range	Wireless receiver front-ends, spectral analysis
Band-Reject Filter (BRF)	Attenuates a specific frequency band	Power line noise cancellation (50/60Hz), RFID systems
All-Pass Filter	Phase shifting without amplitude modification	Phase equalization in data transmission, delay equalizers

3. Structure and Components

Active filters typically consist of:
- Operational Amplifiers (Op-Amps): Provide gain and buffering.
- RC Networks: Define frequency response through resistor-capacitor combinations.
- Feedback Circuits: Stabilize performance and control Q-factor.
- Power Supply Pins: For biasing active components.
Modern IC implementations integrate these elements in monolithic packages, such as 8-pin SOIC or TSSOP, with laser-trimmed precision components.

4. Key Technical Specifications

Parameter	Description	Importance
Cutoff Frequency (f_c)	Frequency at -3dB point	Determines passband boundary
Voltage Gain (A_v)	Amplification factor	Signal strength adjustment
Quality Factor (Q)	Selectivity of frequency response	Controls transition band steepness
Input/Output Impedance	Matching with external circuits	Minimizes signal reflection
Power Supply Rejection Ratio (PSRR)	Noise immunity from power rails	Improves signal integrity

5. Application Areas

Telecommunications: DSL line drivers, 5G transceivers
Consumer Electronics: Equalizers in smartphones, noise-canceling headphones
Industrial: Sensor signal conditioning in PLCs
Medical Devices: Biopotential amplifiers for EMG/EKG
Automotive: Radar signal processing in ADAS

6. Leading Manufacturers and Products

Manufacturer	Representative Products	Key Features
Texas Instruments	LMV721, PGA2500	Rail-to-rail output, programmable gain
Analog Devices	LTC1564, MAX275	Low-power operation, tunable cutoff
STMicroelectronics	TS272, LMC662	CMOS technology, high precision
NXP Semiconductors	SAF7741, TDA7409	Audio-specific filtering with DSP integration

7. Selection Guidelines

Key considerations include:
- Required frequency range and stability over temperature
- Power consumption constraints (e.g., portable devices)
- Package size for space-constrained applications
- Component tolerance and aging effects
- Cost vs. performance trade-offs (e.g., using switched-capacitor filters for adjustable cutoff)

8. Industry Trends

Future developments focus on:
- Higher integration with ADC/DACs and DSP cores
- Miniaturization via 3D packaging and MEMS technology
- Adaptive filters using AI-driven parameter optimization
- Enhanced radiation hardness for automotive/aerospace applications
- Energy-efficient designs for IoT edge devices