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MAX1701EEE+T
Product Overview
- Category: Integrated Circuit (IC)
- Use: Battery Management System
- Characteristics: Low-power, high-accuracy fuel gauge for lithium-ion (Li+) batteries
- Package: 16-pin QSOP
- Essence: Accurate battery state-of-charge (SOC) and time-to-empty predictions
- Packaging/Quantity: Tape & Reel, 2500 units per reel
Specifications
- Input Voltage Range: 2.5V to 5.5V
- Operating Temperature Range: -40°C to +85°C
- Battery Types Supported: Single-cell Li+ batteries
- Accuracy: ±1% Voltage, ±3% Current, ±8% SOC
Detailed Pin Configuration
- VSS: Ground
- CE: Chip Enable
- SCL: I2C Serial Clock
- SDA: I2C Serial Data
- TS: Temperature Sense Input
- BAT: Battery Voltage Input
- GND: Ground
- VDD: Power Supply
- D–: Negative Terminal of Current-Sense Resistor
- D+: Positive Terminal of Current-Sense Resistor
- TST: Test Mode
- ALRT: Alert Output
- RST: Reset
- NC: No Connect
- NC: No Connect
- NC: No Connect
Functional Features
- Accurate voltage, current, and temperature measurement
- ModelGauge algorithm for SOC and time-to-empty prediction
- Low quiescent current for minimal impact on battery life
- I2C interface for communication with microcontrollers
Advantages
- High accuracy in battery monitoring
- Low power consumption
- Small form factor
- Easy integration with microcontroller systems
Disadvantages
- Limited to single-cell Li+ battery applications
- Requires understanding of I2C communication protocol for interfacing
Working Principles
The MAX1701EEE+T utilizes the ModelGauge algorithm to accurately estimate the SOC and time-to-empty of a single-cell Li+ battery. It measures battery voltage, current, and temperature to continuously update its predictions. The I2C interface allows seamless communication with microcontrollers for real-time monitoring and control.
Detailed Application Field Plans
- Portable electronic devices
- Wearable technology
- IoT devices
- Handheld instruments
- Medical devices
Detailed and Complete Alternative Models
- MAX17043
- BQ27510-G3
- LTC2943
- DS2777
This integrated circuit, MAX1701EEE+T, is a versatile and accurate solution for monitoring single-cell Li+ batteries in various portable and handheld electronic devices. Its low-power consumption and precise battery management features make it an ideal choice for applications where battery life and performance are critical.
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Enumere 10 preguntas y respuestas comunes relacionadas con la aplicación de MAX1701EEE+T en soluciones técnicas
Sure, here are 10 common questions and answers related to the application of MAX1701EEE+T:
Q: What is the input voltage range for MAX1701EEE+T? A: The input voltage range for MAX1701EEE+T is 4.5V to 28V.
Q: What is the typical output current for MAX1701EEE+T? A: The typical output current for MAX1701EEE+T is 100mA.
Q: Can MAX1701EEE+T be used in battery-powered applications? A: Yes, MAX1701EEE+T is suitable for battery-powered applications due to its low quiescent current and high efficiency.
Q: What is the operating temperature range for MAX1701EEE+T? A: The operating temperature range for MAX1701EEE+T is -40°C to +85°C.
Q: Does MAX1701EEE+T have built-in overcurrent protection? A: Yes, MAX1701EEE+T features built-in overcurrent protection to safeguard the circuit and load.
Q: Can MAX1701EEE+T be used in automotive applications? A: Yes, MAX1701EEE+T is suitable for automotive applications, given its wide input voltage range and robust design.
Q: What type of package does MAX1701EEE+T come in? A: MAX1701EEE+T is available in a 16-pin QSOP package.
Q: Is MAX1701EEE+T suitable for low-power IoT devices? A: Yes, MAX1701EEE+T is well-suited for low-power IoT devices due to its low quiescent current and high efficiency.
Q: Can MAX1701EEE+T be used in industrial control systems? A: Yes, MAX1701EEE+T is suitable for industrial control systems due to its wide input voltage range and robust performance.
Q: Does MAX1701EEE+T require external compensation components? A: No, MAX1701EEE+T features internal compensation, eliminating the need for external compensation components.