PMIC - Battery Management

Part Number	Description / PDF	Quantity
MAX17211X+T0E Maxim Integrated	IC BATT MONITOR 1CELL 15WLP	0
MAX17201X+T Maxim Integrated	IC BATT MONITOR 1CELL 15WLP	0
MAX17823BGCB/V+T Maxim Integrated	IC BATT MFUNC MULTI 12C 64LQFP	0
MAX16916GUB/V+T Maxim Integrated	IC BATT USB DATA LINE PROT UMAX	0
MAX17320X20+ Maxim Integrated	IC BATT FUEL LI-ION 2-4C 30WLP	9841100
MAX17205X+T Maxim Integrated	IC BATT MFUNC 2-3CELL 15WLP	10000
MAX17823BGCB/V+ Maxim Integrated	IC BATT MFUNC MULTI 12C 64LQFP	1600
MAX17303X+T Maxim Integrated	IC BATT FUEL LI-ION 1C 15WLP	0
MAX17311X+T Maxim Integrated	IC BATT FUEL LI-ION 1C 15WLP	10000
MAX17300X+ Maxim Integrated	MODELGAUGE M5 1S WLP	1000
MAX17828EUN+ Maxim Integrated	IC BATT 12 CH HIGH VOLT SENSOR	0
MAX17823BGCB+ Maxim Integrated	IC BATT MFUNC MULTI 12C 64LQFP	0
MAX17301X+T Maxim Integrated	IC BATT FUEL LI-ION 1C 15WLP	27500
MAX14670EWL+T Maxim Integrated	IC BAT OVERVOLT PROTECTION 15WLP	0
MAX14671EWL+T Maxim Integrated	IC BATT PROTECTION 15WLP	0
MAX17201X+T0E Maxim Integrated	IC BATT MONITOR 1CELL 15WLP	0
MAX17852ACB/V+T Maxim Integrated	IC BATT INTERFACE SENSOR LQFP	0
MAX17830GUN+T Maxim Integrated	IC BATT MFUNC 56TSSOP	0
MAX17841BGUE+T Maxim Integrated	IC BATT INTERFACE AUTO SPI TSSOP	0
MAX17215X+T Maxim Integrated	IC BATT MFUNC 2-3CELL 15WLP	0

PMIC - Battery Management

1. Overview

Power Management Integrated Circuits (PMICs) with Battery Management functionality are specialized semiconductor devices designed to monitor, control, and optimize battery operations in electronic systems. These ICs handle critical tasks including charging control, discharge regulation, capacity monitoring, and safety protection. Their importance has grown exponentially with the proliferation of portable electronics, electric vehicles, and energy-harvesting systems, where battery efficiency and safety are paramount.

2. Major Types & Functional Classification

Type	Functional Features	Application Examples
Battery Charge Management ICs	Support Li-ion/Polymer, NiMH, and lead-acid chemistries; implement CC/CV charging, thermal regulation	Smartphones, power banks
Fuel Gauge ICs	Impedance tracking, voltage-based SOC estimation, data logging	Laptops, medical devices
Battery Protection ICs	Overvoltage, overcurrent, short-circuit, and temperature protection	E-bikes, battery packs
Power Path Management ICs	Dynamic power distribution between charger and system load	Tablets, drones

3. Structure & Composition

A typical PMIC Battery Management IC integrates:

Analog Front-End (AFE) with precision ADC/DAC
Digital control logic (state machines or embedded microcontrollers)
Communication interfaces (I2C, SMBus, SPI)
High-side/low-side MOSFET drivers
Temperature sensing elements
Non-volatile memory for calibration data

Advanced packages (QFN, BGA) enable high integration while maintaining thermal performance.

4. Key Technical Specifications

Parameter	Typical Range	Importance
Charging Current Range	100mA - 5A	Determines charge speed and battery size compatibility
SOC Estimation Accuracy	1-5%	Impacts runtime prediction reliability
Quiescent Current	1-20 A	Crucial for standby power efficiency
Communication Speed	400kHz - 3.4MHz (I2C)	Affects system responsiveness
Operating Temperature	-40 C to +125 C	Determines environmental robustness

5. Application Fields

Consumer Electronics: Smartphones (Apple iPhone PMICs), Smartwatches (Fitbit Charge series)
Medical Devices: Portable ultrasound machines (Philips Lumify), infusion pumps
Automotive: EV battery packs (Tesla Model 3 BMS), start-stop systems
Industrial: Robotics (Boston Dynamics Atlas), energy storage systems

6. Leading Manufacturers & Products

Manufacturer	Representative Product	Key Features
Texas Instruments	BQ25790	Single-chip solution with USB PD 3.0, 3.5A charging
Analog Devices	MAX17055	ModelGauge m3 algorithm, 60s runtime prediction
STMicroelectronics	STM32F051x	Cortex-M0 core with integrated Li-ion charger
NXP Semiconductors	PF1550	PMIC for i.MX8 processors with dynamic voltage scaling

7. Selection Guidelines

Key considerations:

Battery chemistry compatibility (Li-ion requires CC/CV profile)
System voltage requirements (USB PD needs 5-20V support)
Form factor constraints (Wearable devices demand WCSP packages)
Communication protocol compatibility (I2C vs. SMBus vs. HDQ)
Safety certifications (UL 1642 for lithium batteries)
Software ecosystem (development tools and reference designs)

Example: For a 2-cell Li-ion notebook battery, select a multi-cell fuel gauge (e.g., BQ30z55) with SHA-256 authentication and PC companion software support.

8. Industry Trends

Integration of wireless charging (Qi standard) with battery management
Adoption of AI algorithms for adaptive charging profiles
Development of ultra-low-power PMICs for IoT edge devices
Increase in ASIL-D rated automotive-grade PMICs for EVs
Transition to 3D packaging for higher functional density
Growing adoption of battery health analysis (BHA) algorithms