Electronica Azi & Microchip MPLAB ICD 4 In-Circuit Debugger

Win a Microchip MPLAB ICD 4 In-Circuit Debugger (DV164045) from Electronica Azi and if you don’t win, receive a 20% off voucher, plus free shipping for one of these products.

The new MPLAB ICD 4 introduces a faster processor and increased RAM to deliver up to twice the speed of ICD 3 for the in-circuit debugging of PIC® microcontrollers and dsPIC® digital signal controllers. The MPLAB ICD 4 also introduces a wider target voltage range and an optional 1 A of power via an external power supply.

For maximum flexibility, MPLAB ICD 4 features a selectable pull-up/pull-down option to the target interface and programmable adjustment of debugging speed for greater productivity The MPLAB ICD 4’s significant improvement in speed is accomplished through a 32-bit MCU running at 300 MHz. Faster processing, together with an increased buffer memory of 2 MB, results in a product that is up to twice as fast as its predecessor.

Microchip’s MPLAB ICD 4 is easy to use and supports many PIC microcontrollers and dsPIC digital signal controllers in Microchip’s portfolio through the MPLAB X Integrated Development Environment (IDE). This simplifies the design process for customers when they choose to migrate from one PIC MCU to another to meet the needs of their application.

The MPLAB ICD 4 connects to the PC using a high-speed USB 2.0 interface and is connected to the target with a debugging connector which is also compatible with the MPLAB ICD 3 or MPLAB REAL ICE™ In-Circuit Emulator systems. The MPLAB ICD 4 also works with JTAG interfaces.

Faster and more flexible real-time in-circuit debugging

  • Supports many PIC microcontrollers and dsPIC DSCs
  • x2 faster than ICD 3
  • Reduced wait time improves debugging productivity
  • Simplifies migration between PIC MCUs

Win a Microchip MPLAB ICD 4 In-Circuit Debugger!

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Highlights

  • Using high-precision architectures enables superior DC performance, regardless of operating conditions
  • Low noise and additional EMI filtering on the inputs provide additional protection in electrically noisy environments
  • Small packages, such as leadless DFNs, are ideal for space-constrained designs
  • A wide operating temperature range of –40°C to +125°C provides a robust solution even at extreme temperatures

Microchip Instrumentation Amplifier with mCAL Technology

The MCP6N11 and MCP6V2x Wheatstone Bridge Reference Design 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 USB PIC® microcontroller and included Graphical User Interface (GUI) provides the means to configure the board and collect sample data.