Microchip Technology MCP6V01DM-VOS 数据表

Analog & Interface Product Selector Guide

The LIN Serial Analyzer development 

system enables a Personal Computer 

(PC) to communicate with a LIN (Local 

Interface Network) bus . The PC program 

uses a graphical user interface to enter 

and display message frames occurring on the target bus .

The MCP2200EV-VCP is a USB-to-RS232 

development and evaluation board for 

the MCP2200 USB-to-UART device . The 

board allows for easy demonstration and 

evaluation of the MCP2200 . The accompanying software 

allows the special device features to be configured and 

controlled . The board is powered from USB and has a test 

point associated with each GPIO pin . In addition, two of 

these pins are connected to LEDs which can be used to 

indicate USB-to-UART traffic when the associated pins are 

configured as TxLED and RxLED pins respectively .

The MCP6V01 design board 

demonstrates how to use a difference 

amplifier system to measure 

Electromotive Force (EMF) voltage at 

the cold junction of thermocouple in order to accurately 

measure temperature of the thermocouple bead . This 

can be done by using the MCP6V01 auto-zeroed op amp 

because of its ultra low offset Voltage (VOS) and high 

Common Mode Rejection Ratio (CMRR) .

This board demonstrates the performance 

of Microchip’s MCP6N11 instrumentation 

amplifier (INA) and a traditional three op 

amp INA using Microchip’s MCP6V26 

and MCP6V27 auto-zeroed op amps . The 

input signal comes from an RTD temperature sensor in 

a Wheatstone bridge . Real world interference is added 

to the bridge’s output, to provide realistic performance 

comparisons . Data is gathered and displayed on a PC, for 

ease of use .

The MCP6H04 Evaluation Board is intended 

to support an instrumentation amplifier 

and show the capability of the MCP6H04 

operational amplifier . It uses a quad op amp 

in a difference amplifier configuration with 

input buffers and voltage reference . The test points for the 

power supply, ground, input signals, output signals, and 

voltage reference allow lab equipment to be connected to 

the board .

The MCP73X23 Lithium Iron 

Phosphate Battery Charger Evaluation 

board demonstrates the features of 

Microchip’s MCP73123 and MCP73223 

Lithium Iron Phosphate (LiFePO4) Battery Charge 

Management Controller with Input Overvoltage Protection .

This reference design is developed to 

assist product designers in reducing 

product design cycle and time by 

utilizing Microchip’s stand-alone Li-Ion 

battery charge management controllers 

with system power path management . Due to the natural 

characteristics of Li-Ion/Li-Polymer batteries, they are the 

most popular power sources for mobile devices, however, 

extra care in design is always important . System Power 

Path Management allows end-users to charge their 

batteries without interruption .

The MCP1640 Synchronous Boost 

Converter Evaluation board demonstrates 

the MCP1640 in two boost-converter 

applications with multiple output voltages . 

It can be used to evaluate both package 

options (SOT-23-6 and 2 × 3-8 DFN) . This 

board was developed to help engineers 

reduce the product design cycle time .

The MCP1252 board demonstrates 

the use of a charge pump device in 

an LED application and acts as a 

platform to evaluate the MCP1252 

device in general . Light intensity is 

controlled uniformly through the use of ballast resistors . 

A PIC10F206 MCU provides an enable signal to the 

MCP1252 and accepts a push-button input that allows the 

white LEDs to be adjusted to five different light intensities .

The MCP2515 CAN Bus Monitor Demo 

board kit contains two identical boards 

which can be connected together to 

create a simple two node Controller 

Area Network (CAN) bus, which can be 

controlled and/or monitored via the included PC interface . 

The board(s) can also be connected to an existing CAN bus .