MAX6652
PRODUCTIONTemperature Sensor and System Monitor in a 10-Pin µMAX
Temperature Sensor and System Monitor in a 10-pin µMax
- Part Models
- 2
- 1ku List Price
- Starting From $2.33
Overview
- Monitors Four Voltages (2.5V, 3.3V, 12V, VCC)
- Monitors Local Temperature
- Temperature Measurement Accuracy, ±2°C (TA = +25°C)
- User-Programmable Voltage and Temperature Thresholds
- Alert Function with Ability to Respond to SMB Alert Response Address
- +2.7V to +5.5V Supply Range
- -40°C to +125°C Temperature Range
- 60Hz or 50Hz Line-Frequency Rejection
- Tiny 10-Pin µMAX Package
The MAX6652 system supervisor monitors multiple power-supply voltages, including its own, and also features an on-board temperature sensor. Voltages and temperature are converted to an 8-bit code using an analog-to-digital converter (ADC). A multiplexer automatically sequences through the voltage and temperature measurements. The digitized signals are then stored in registers and compared to the over/under threshold limits programmed over the 2-wire serial interface.
When a temperature measurement exceeds the programmed threshold, or when an input voltage falls outside the programmed voltage limits, the MAX6652 generates a latched interrupt output active-low ALERT. Three interrupt modes are available for temperature excursions: default mode, one-time interrupt mode, and comparator mode. The active-low ALERT output is cleared, except for temperature interrupts generated in comparator mode, by reading the interrupt status register (Table 5). The active-low ALERT output can also be masked by writing to the appropriate bits in the interrupt mask register (Table 6) or by setting bit 1 of the configuration register (Table 4) to 0. The MAX6652 I²C*-compatible/SMBus™ interface also responds to the SMB alert response address.
The 2-wire serial interface accepts both I²C and standard system management bus (SMBus) write byte, read byte, send byte, and receive byte commands to program the alarm thresholds and to read voltage and temperature data. Voltage data is scaled so that when the nominal voltage is present at a pin (e.g., 3.3V for the 3.3VIN pin), the conversion result is equal to 3/4 of the ADC full-scale range or a decimal count of 192 (Table 3). The temperature data format is 7 bits plus sign, with each data bit representing 1°C, in two's complement format (Table 2).
The MAX6652 has only one address pin, ADD. One of four different address codes can be selected by connecting the ADD pin to GND, VCC, SDA, or SCL. Whenever an I²C-compatible/SMBus transaction is initiated, the two LSBs of the slave address register are determined by connection, setting the chip address to one of four possible values. In addition, an address code can also be directly written to the serial address register. This code will overwrite the code set by connection of the ADD pin, until the MAX6652 is taken through a power-on reset cycle.
The MAX6652 features 60Hz or 50Hz line-frequency rejection for optimal performance. The device operates from +2.7V to +5.5V and is specified for operation from -40°C to +125°C. It is available in a tiny 10-pin µMAX® package.
Applications
- Computers: Desktop, Workstation, Server
Documentation
Data Sheet 1
Reliability Data 1
Design Note 1
Technical Articles 2
ADI has always placed the highest emphasis on delivering products that meet the maximum levels of quality and reliability. We achieve this by incorporating quality and reliability checks in every scope of product and process design, and in the manufacturing process as well. "Zero defects" for shipped products is always our goal. View our quality and reliability program and certifications for more information.
| Part Model | Pin/Package Drawing | Documentation | CAD Symbols, Footprints, and 3D Models |
|---|---|---|---|
| MAX6652AUB+ | 10-MINI_SO-N/A | ||
| MAX6652AUB+T | 10-MINI_SO-N/A |
| Part Models | Product Lifecycle | PCN |
|---|---|---|
|
Sep 19, 2018 - 1753N ASSEMBLY |
||
| MAX6652AUB+ | PRODUCTION | |
| MAX6652AUB+T | PRODUCTION | |
This is the most up-to-date revision of the Data Sheet.