PMIC - RMS to DC Converters

Part Number	Description / PDF	Quantity
AD736JRZ-R7 Analog Devices, Inc.	RMS TO DC CONVERTER, 0.005MHZ, B	13177
AD8436ARQZ Analog Devices, Inc.	IC RMS TO DC CONVERTER 20QSOP	1314
AD536AKD Analog Devices, Inc.	TRUE RMS-TO-DC CONVERTER	1246
AD737JR-REEL Analog Devices, Inc.	RMS TO DC CONVERTER,0.005MHZ	2500
AD736BRZ Analog Devices, Inc.	IC RMS TO DC CONVERTER 8SOIC	127
AD636JDZ Analog Devices, Inc.	IC RMS TO DC CONVERTER 14CDIP	14
AD536ASE/883B Analog Devices, Inc.	TRUE RMS-TO-DC CONVERTER	150
AD636KD Analog Devices, Inc.	RMS TO DC CONVERTER,0.1MHZ	3530
MX636KCWE Analog Devices, Inc.	MX636 TRUE RMS-TO-DC CONVERTER	23
AD637JR Analog Devices, Inc.	RMS TO DC CONVERTER,0.15MHZ	263
MX636JD Analog Devices, Inc.	MX636 TRUE RMS-TO-DC CONVERTER	1457
LTC1966MPMS8#PBF Analog Devices, Inc.	IC RMS TO DC CONVERTER 8MSOP	106
AD536AKDZ Analog Devices, Inc.	IC RMS TO DC CONVERTER 14CDIP	49
LTC1967IMS8#PBF Analog Devices, Inc.	IC RMS TO DC CONVERTER 8MSOP	1475
AD8436BRQZ-RL Analog Devices, Inc.	IC RMS TO DC CONVERTER 20QSOP	0
AD736JR-REEL7 Analog Devices, Inc.	RMS TO DC CONVERTER,0.005MHZ	10281
AD8436BRQZ Analog Devices, Inc.	IC RMS TO DC CONVERTER 20QSOP	665
AD8436JCPZ-RL Analog Devices, Inc.	IC RMS TO DC CONVERTER 20LFCSP	0
AD536AJQ Analog Devices, Inc.	IC RMS TO DC CONVERTER 14CERDIP	363
MX636KN Analog Devices, Inc.	MX636 TRUE RMS-TO-DC CONVERTER	193

PMIC - RMS to DC Converters

1. Overview

RMS-to-DC converters are specialized Power Management Integrated Circuits (PMICs) that convert alternating current (AC) or time-varying signals into proportional direct current (DC) voltages equivalent to the root mean square (RMS) value of the input. These devices are critical in applications requiring precise power measurement, signal amplitude detection, and energy monitoring. Their ability to accurately capture the effective power of complex waveforms makes them indispensable in modern electronics, including communication systems, industrial automation, and renewable energy management.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Linear RMS-to-DC	High linearity, low noise, and wide bandwidth	RF power measurement, audio signal processing
Dynamic Range Optimized	Supports 60dB+ input range, automatic scaling	Wireless base stations, radar systems
Multi-Channel	Simultaneous conversion of multiple signals	3-phase power monitoring, MIMO systems
Precision Low-Power	0.1% accuracy, sub-10 A quiescent current	IoT sensors, battery-powered instruments

3. Structure and Composition

A typical RMS-to-DC converter IC consists of:

Input Buffer: Impedance matching and signal conditioning
Squaring Circuit: Computes instantaneous square of input signal
Low-Pass Filter: Averages squared signal to extract RMS value
Output Amplifier: Scales DC output to desired voltage range
Temperature Compensation Module: Minimizes thermal drift

Available in QFN, TSSOP, or BGA packaging with die-level options for high-density designs.

4. Key Technical Specifications

Parameter	Description
Input Frequency Range	100Hz - 10GHz (varies by architecture)
Conversion Accuracy	0.05% to 1% of reading
Response Time	1 s - 10ms (determines dynamic range)
Supply Voltage	2.7V - 5.5V (single/dual supply options)
Output Voltage Range	0V - 2.5V/5V scalable
Temperature Stability	5ppm/ C typical drift
Power Consumption	100 A - 10mA operating current

5. Application Areas

Telecommunications: 5G massive MIMO beamforming, optical transceivers
Industrial: Smart grid power quality analyzers, motor drive monitoring
Consumer: High-fidelity audio level meters, smart home energy monitors
Automotive: EV battery management systems, radar obstacle detection
Medical: Ultrasound intensity measurement, patient monitoring equipment

6. Leading Manufacturers and Products

Manufacturer	Key Product	Features
Analog Devices	ADL5511	10GHz bandwidth, 0.3dB error, 15ns response
TI (Texas Instruments)	LMH2110	DC-8GHz, 65dB dynamic range, SPI calibration
STMicroelectronics	LTC6983	Time-domain architecture, 0.1% linearity
Maxim Integrated	MAX21100	3-channel, 1MHz bandwidth, 16-bit resolution
NXP Semiconductors	MC33035	Automotive-grade, -40 C to 150 C operation

7. Selection Guidelines

Determine required input frequency range and signal type (AC/RF/pulse)
Evaluate acceptable error margin (e.g., 0.5% for test equipment)
Assess response time requirements for dynamic signals
Select package type based on PCB space and thermal constraints
Consider temperature rating for industrial/military applications
Balance power consumption against system battery life
Verify calibration support (digital compensation features preferred)

8. Industry Trends

Higher Frequencies: Development of mmWave-compatible converters beyond 30GHz
System-on-Chip Integration: Combining RMS conversion with ADCs and DSP cores
AI-Enhanced Calibration: Machine learning algorithms for self-compensation
Wide Bandgap Compatibility: GaN/SiC-based converters for high-power applications
Energy Harvesting: Sub- W RMS detection for IoT edge devices

Market growth driven by 5G deployment and renewable energy monitoring demands, projected CAGR of 8.2% (2023-2030).