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Решения для тестирования и измерений

Описание:
The PIC10F32X Development Board is intended to be a learning tool for individuals interested in PIC ® microcontroller design and developing applications using the Configurable Logic Cell, Complimentary Waveform Generator and Numerically Controlled Oscillator peripherals. The PIC10F322 microcontroller is ideal for use on the PIC10F32X Development Board due to its small size, high efficiency, speed and peripheral configurations.
Возможности:

    • PIC10F320
    • Configurable Logic Cell
    • Complementary Waveform Generator
    • Numerically Controlled Oscillator

Документация:
  • Даташит
  • Програмное обеспечение
  • Тестирование
Описание:
This circuit uses the ADuCM360/ADuCM361 precision analog microcontroller in an accurate thermocouple temperature monitoring application. The ADuCM360/ADuCM361 integrates dual 24-bit sigma-delta (Σ-Δ) analog-to-digital converters (ADCs), dual programmable current sources, a 12-bit digital-to-analog converter (DAC), and a 1.2 V internal reference, as well as an ARM Cortex-M3 core, 128 kB flash, 8 kB SRAM, and various digital peripherals such as UART, timers, SPIs, and I2C interfaces.

In the circuit, the ADuCM360/ADuCM361 is connected to a thermocouple and a 100 Ω platinum resistance temperature detector (RTD). The RTD is used for cold junction compensation.


In the source code, an ADC sampling rate of 4 Hz is chosen. When the ADC input programmable gain amplifier (PGA) is configured for a gain of 32, the noise-free code resolution of the ADuCM360/ ADuCM361 is greater than 18 bits.




Figure 1. ADuCM360/ADuCM361 as a Temperature Monitor Controller with a Thermocouple Interface (Simplified Schematic, All Connections Not Shown)

Возможности:

  • Typical temperature range of -200 C to +400 C
  • Precision Cortex M3 analog microcontroller with 24-bit sigma-delta ADC
  • T-type thermocouple measurement system with cold junction compensation
  • Single chip solution

Документация:
  • Схемотехника
  • Топология платы
Описание:
The circuit shown in Figure 1 is a complete high performance resolver-to-digital (RDC) circuit that accurately measures angular position and velocity in automotive, avionics, and critical industrial applications where high reliability is required over a wide temperature range.


Figure 1. High Performance Resolver-to-Digital (RDC) Circuit. Simplified Schematic: All Components, Connections, and Decoupling Not Shown

The circuit has an innovative resolver rotor driver circuit that has two modes of operation: high performance and low power. In the high performance state, the system operates on a single 12 V supply and can supply 6.4 V rms (18 V p-p) to the resolver. In the low power state, the system operates on a single 6 V supply and can supply 3.2 V rms (9.2 V p-p) to the resolver, with less than 100 mA of current consumption. Active filtering is provided in both the driver and receiver to minimize the effects of quantization noise.

The maximum tracking rate of the RDC is 3125 rps in the 10-bit mode (resolution = 21 arc min) and 156.25 rps in the 16-bit mode (resolution = 19.8 arc sec).

Возможности:

  • 10-bit to 16-bit resolver to digital converter
  • High and low voltage drive options
  • Maximum tracking rate of 3125 rps

Документация:
  • Схемотехника
  • Програмное обеспечение
  • Топология платы
Описание:
This circuit uses the ADuC7060 or the ADuC7061 precision analog microcontroller in an accurate thermocouple temperature monitoring application. The ADuC7060/ ADuC7061 integrate dual 24-bit sigma-delta (Σ-Δ) analog-to-digital converters (ADCs), dual programmable current sources, a 14-bit digital-to-analog converter (DAC), and a 1.2 V internal reference, as well as an ARM7 core, 32 kB flash, 4 kB SRAM, and various digital peripherals such as UART, timers, serial peripheral interface (SPI), and I2C interfaces.


In the circuit, the ADuC7060/ ADuC7061 are connected to a thermocouple and a 100 Ω platinum resistance temperature detector (RTD). The RTD is used for cold junction compensation. As an extra option, the ADT7311 digital temperature sensor can be used to measure the cold junction temperature instead of the RTD.


In the source code, an ADC sampling rate of 4 Hz was chosen. When the ADC input programmable gain amplifier (PGA) is configured for a gain of 32, the noise-free code resolution of the ADuC7060/ ADuC7061 is greater than 18 bits.


The single edge nibble transmission (SENT) interface to the host is implemented by using a timer to control a digital output pin. This digital output pin is then level shifted externally to 5 V using an external NPN transistor. An EMC filter is provided on the SENT output circuit as recommended in Section 6.3.1 of the SENT protocol (SAE J2716 Standard). The data is measured as falling edge to falling edge, and the duration of each pulse is related to the number of system clock ticks. The system clock rate is determined by measuring the SYNC pulse. The SYNC pulse is transmitted at the start of every packet. More details are provided in the SENT Interface section.


Figure 1. ADuC7060/ADuC7061 as a Temperature Monitor Controller with a Thermocouple Interface (Simplified Schematic, All Connections Not Shown)

Возможности:

  • Thermocouple sensor with cold junction compensation
  • Automotive SENT interface

Документация:
  • Схемотехника
  • Топология платы
Описание:
This is a small demo board with a PIC18F45K20 device on board and a small, surface-mount prototype area. Use it with a PICkit 3 In-Circuit Debugger to program your code via a 6-pin ICSP header on the board. This product also includes two bare PCB boards for those interested in customizing their development. This 44-Pin Demo Board also comes bundled with the PICkit 3 Debug Express if you order the DV164131.

Newer version development tools are available now. Please consider Explorer 8 Development Board (DM160228) for new designs
Возможности:

    This is a small demo board with a PIC18F45K20 device on board and a small, surface-mount prototype area. Use it with a PICkit 3 In-Circuit Debugger to program your code via a 6-pin ICSP header on the board. This product also includes two bare PCB boards for those interested in customizing their development. This 44-Pin Demo Board also comes bundled with the PICkit 3 Debug Express if you order the DV164131.

Документация:
  • Даташит
  • Тестирование
Описание:
The Explorer 16 Development Board is a low-cost modular development system for Microchip’s 16-bit and 32-bit microcontrollers. It supports devices from the PIC24, dsPIC and PIC32 families. A variety of families are supported with processor Plug-In Modules (PIMs) for easy device swapping. The board includes a PICtail Plus daughter card connector for expansion boards including USB, CAN, Ethernet, wireless, graphics and many more. Coupled with the MPLAB ICD 3 In Circuit Debugger or MPLAB REAL ICE, real-time emulation and debug facilities speed evaluation and prototyping of application circuitry.

Recommendation for Migration:
For 'New Designs' or advanced features requirement, migrate to refreshed and cost effective "Explorer 16/32 Development Board" with several new features. Offering backwards compatibility, the Explorer 16/32 development board facilitates seamless migration from Explorer 16 development board to the new platform.
For further details explore:
Возможности:

  • Includesprocessor PIMs for both PIC24 and dsPIC families
  • Alpha-numeric 16 x 2 LCD display
  • Interfaces to MPLAB ICD 3, MPLAB REAL ICE and RS-232
  • Includes Microchip's TC1047A high accuracy, analog output temperature sensor
  • Expansion connector to access full devices pin-out and bread board prototyping area
  • PICTailTMPlus connector for expansion boards
  • Full documentation in download section below: user's guide, schematics

Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • Тестирование
Описание:
The Explorer 16/32 Development Board is a flexible and convenientdevelopment, demonstration and testing platform for 16-bit PIC24 MCUs, dsPIC® DSCs and 32-bit PIC32 MCUs from Microchip Technology. It features all the necessary hardware to begin developing and debugging a complete embedded application. The board accepts Processor Plug-In Modules (PIMs) designed for the Explorer 16 or Explorer 16/32 development board for easy device swapping. In addition to the hardware features provided by the board, hardware expansion is possible through the use of PICtail™ Plus daughter cards and mikroBUS™ accessory boards. Coupled with the integrated PICkit™-On-Board (PKOB), MPLAB ICD 3 In-Circuit Debugger or MPLAB REAL ICE™ real-time emulation and debug facilities enable faster evaluation and prototyping of application.

Explorer 16/32 Development Board offers only the main board, giving the option to customize the other necessary components. Choose PIM of your choice based on MCUs and DSCs under consideration from wide range of Processor Plug-In Modules. This board is optimal for customers migrating from Classic Explorer 16 to new Explorer 16/32 platform, while all the necessary additional components like Processor Plug-In Modules and PICtail™ Plus Daughter Boards are already available


Also read about Explorer 16/32 Development Kit



Backwards Compatibility
Explorer 16/32 Development Board is completely backwards compatible with the Classic Explorer 16 Development Board (DM240001 and DM240002) and its associated ecosystem that include:
  • Processor Plug-In Modules (PIMs)
  • PICTail™ Plus Daughter Boards
  • Code Examples, Ptototypes and Software Libraries developed on Classic Explorer 16 development Board

Use all of existing codes, libraries, prototypes, PIMs and the PICtail Plus daughter cards interfaced via side PICtail Plus connector directly. Re-use the PICtail Plus daughter cards interfaced via vertical PICtail Plus connector using additional PICtail Plus Expansion Board (AC240100)


Getting Started
  • Read the Explorer 16/32 User's Manual (available at Documentation and Software section of this page)
  • Download the free MPLAB X IDE
  • Download the suitable MPLAB XC Compiler
  • Download and unzip the appropriate firmware demo code (available at Documentation & Software section of this page)
Возможности:

    • 100 pin Plug-In Module (PIM) socket, supporting a wide variety of 16-bit and 32-bit PIC® MCUs and dsPIC® DSCs
    • Power supply
      • USB Power through PICkit™-On-Board (PKOB), USB Type-C™ or USB-Serial Converter
      • 9-15V DC Power Supply
    • On board USB to UART/I2C™ adapter for data exchange with PC/Mac/Linux based host
    • USB Type-C™ (host/device) and Type-A (host) support for applications using USB microcontroller
    • Hardware functionality extension by attaching accessory boards via
      • PICtail™ Plus interface
      • 2x MikroElektronika mikroBUS™ interface
      • 2x Digilent Pmod™ footprint
    • Alpha-numeric 16 x 2 LCD display, 8x User LEDs, 4x Push Buttons, 10k potentiometer
    • Microchip's TC1047A high accuracy, analog output temperature sensor
    • Programmer/Debugger
      • Integrated USB programmer/debugger - PICkit™-On-Board (PKOB)
      • Interfaces to MPLAB ICD 3, MPLAB REAL ICE™, PICkit™ 3
    • Support for all the existing and new PICtail™ Plus Daughter Cards
      • Interface PICtail™ Plus Daughter Cards connected via side PICtail™ Plus connector directly
      • Interface PICtail™ Plus Daughter Cards connected via vertical PICtail™ Plus connector through additional accessory - PICtail™ Plus Expansion Board

Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • Тестирование
Описание:
The Explorer 16/32 Development Kit is a flexible, convenient and ready to start development, demonstration and testing platform for 16-bit PIC24 MCUs, dsPIC® DSCs and 32-bit PIC32 MCUs from Microchip Technology. It features all the necessary hardware to begin developing and debugging a complete embedded application. The board accepts Processor Plug-In Modules (PIM) designed for the Explorer 16 or Explorer 16/32 development board for easy device swapping. In addition to the hardware features provided by the board, hardware expansion is possible through the use of PICtail™ Plus daughter cards and mikroBUS™ accessory boards. Coupled with the integrated PICkit™-On-Board (PKOB), MPLAB ICD 3 In-Circuit Debugger or MPLAB REAL ICE™ real-time emulation and debug facilities enable faster evaluation and prototyping of application.
The development kit comes with Explorer 16/32 main development board, PIC24FJ1024GB610 PIM (MA240023), USB A to micro-B cable, and USB A to Type-C Cable.For out of the box experience, Explorer 16/32 Development Kit is the right choice that comes with all the necessary components to get started with the evaluation and prototyping right away!

Also read about Explorer 16/32 Development Board

Backwards Compatibility

Explorer 16/32 Development Board is completely backwards compatible with the Classic Explorer 16 Development Board (DM240001 and DM240002) and its associated ecosystem that include:
  • Process or Plug-In Modules (PIMs)
  • PICtail Plus Daughter Boards
  • Code Examples, Prototypes and Software Libraries developed on Classic Explorer 16 Development Board

Use all of existing codes, libraries, prototypes, PIMs and the PICtail Plus daughter cards interfaced via side PICtail Plus connector directly. Re-use the PICtail Plus daughter cards interfaced via vertical PICtail Plus connector using additional PICtail Plus Expansion Board (AC240100)

Getting Started
  • Read the Explorer 16/32 User’s Manual (available at Documentation & Software section of this page)
  • Download the free MPLAB X IDE
  • Download the suitable MPLAB XC Compiler
  • Download and unzip the appropriate firmware demo code (available at Documentation & Software section of this page)

Возможности:

    • 100 pin Plug-In Module (PIM) socket, supporting a wide variety of 16-bit and 32-bit PIC® MCUs and dsPIC® DSCs
    • Power supply
      • USB Power through PICkit™-On-Board (PKOB), USB Type-C™ or USB-Serial Converter
      • 9-15V DC Power Supply
    • On board USB to UART/I2C™ adapter for data exchange with PC/Mac/Linux based host
    • USB Type-C™ (host/device) and Type-A (host) support for applications using USB microcontroller
    • Hardware functionality extension by attaching accessory boards via
      • PICtail™ Plus interface
      • 2x MikroElektronika mikroBUS™ interface
      • 2x Digilent Pmod™ footprint
    • Alpha-numeric 16 x 2 LCD display, 8x User LEDs, 4x Push Buttons, 10k Potentiometer
    • Microchip's TC1047A high accuracy, analog output temperature sensor
    • Programmer/Debugger
      • Integrated USB programmer/debugger - PICkit™-On-Board (PKOB)
      • Interfaces to MPLAB ICD 3, MPLAB REAL ICE™, PICkit™ 3
    • Support for all the existing and new PICtail™ Plus Daughter Cards
      • Interface PICtail™ Plus Daughter Cards connected via sidePICtail™ Plus connector directly
      • Interface PICtail™ Plus Daughter Cards connected via vertical PICtail™ Plus connectorthrough additional accessory - PICtail™ Plus Expansion Board

Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • Тестирование
Описание:
The Explorer 16 Development Board is a low-cost modular development system for Microchip’s 16-bit and 32-bit microcontrollers. It supports devices from the PIC24, dsPIC and PIC32 families. A variety of families are supported with processor Plug-In Modules (PIMs) for easy device swapping. The board includes a PICtail Plus daughter card connector for expansion boards including USB, CAN, Ethernet, wireless, graphics and many more. Coupled with the MPLAB ICD 3 In Circuit Debugger or MPLAB REAL ICE, real-time emulation and debug facilities speed evaluation and prototyping of application circuitry.

Recommendation for Migration:
For 'New Designs' or advanced features requirement, migrate to refreshed and cost effective "Explorer 16/32 Development Board" with several new features. Offering backwards compatibility, the Explorer 16/32 development board facilitates seamless migration from Explorer 16 development board to the new platform.
For further details explore:

Возможности:

    • Includes processor PIMs for both 44 pin PIC24 and dsPIC families
    • Alpha-numeric 16 x 2 LCD display
    • Interfaces to MPLAB ICD 3, MPLAB REAL ICE and RS-232
    • Includes Microchip's TC1047A high accuracy, analog output temperature sensor
    • Expansion connector to access full devices pin-out and bread board prototyping area
    • PICTailTM Plus connector for expansion boards
    • Full documentation in download section below: user's guide, schematics

Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • Тестирование
Описание:
The PIC24F Starter Kit contains everything needed to begin exploring the high performance and versatility of the PIC24F microcontroller family. This inexpensive kit includes an integrated in-circuit debugger and programmer, USB device and host connectors, tri color LED, capacitive touch pad and an OLED display. Menu driven demonstration software supports data logging, thumb drive, and graphics applications to test the PIC24F MCU.

Getting Started:
  • Connect the USB cable from the PC to the demo board, and interact with the custom demo application.
OR

  • MPLAB Start Kit for the PIC24F demo support is now distributed as part of the Legacy Microchip Application Libraries(v2013-06-15) :Legacy MLA.The link to the Legacy libraries can also be found in the Documents/Software section below.
  • Once downloaded and installed, demos for this start kit include ‘PIC24F Starter Kit 1’ and nearly all USB related demo projects, please see the USB library release note for details.
    Older software distribution can be found in our archives.
The PIC24F Starter Kit includes integrated hardware debug and programmer circuitry to develop, program and test applications on the board’s PIC24F MCU device --all from the MPLAB graphical development environment. A USB connection to a host computer supplies communications and power to the board --no additional external power supply is needed.

Demos included:
  • Interactive, menu driven display using Parallel Master Port (PMP)
  • Capacitive touch sensing with the Charge Time Measurement Unit (CTMU)
  • Time and data display using the Real Time Clock and Calendar (RTCC)
  • RGB LED Control with three PWMs and Peripheral Pin Select (PPS)
  • USB Flash drive interface with USB embedded host peripheral
  • Real-time data graphing using the ADC and display multi-tasking
  • Real-time data capture using multi-tasking with USB embedded host
Возможности:

    • Easy and inexpensive way to learn the PIC24F 16-bit MCU family
    • Starter kit features the PIC24FJ256GB106 MCU with 256KB Flash
    • Peripherals including CTMU for capacitive touch and USB OTG
    • Integrated debugger
    • Free MPLAB XC16 Compiler

Документация:
  • Даташит
  • Тестирование
Описание:
The PIC24E USB Starter Kit provides a low cost method for the development and testing of USB OTG, Host and Device applications on the 60 MIPS PIC24E MCU family. The board contains an on-board programming/debugger, standard A USB and micro A/B connectors, three user-programmable LEDs, three push button switches and an expansion header compatible with the Multimedia Expansion Board (DM320005) and I/O Expansion Board (DM320002). The starter kit comes preloaded with basic Communication Device Class (CDC) demonstration software.
Возможности:

    • PIC24E USB Starter Kit Development Board with a PIC24EP512GU810-I/PT MCU
    • PIC24E USB Starter Kit Information Sheet
    • USB mini-B to standard A cable - USB debug cable to debug and power the board
    • USB micro-B to standard A cable - USB cable to communicate with the PIC24E USB

Документация:
  • Даташит
  • Програмное обеспечение
  • Тестирование
Описание:
Microstick for 3V PIC24F K-series (Part #: DM240013-1) is a flexible USB powered development platform. It’s the perfect solution for those looking to get started with Microchip’s lowest cost 16-bit microcontroller families – PIC24F “KL” and “KA” – for extremely cost sensitive consumer, medical and industrial applications.

SUPPORTED PARTS:
Microstick for 3V PIC24F K-series supports the following 3V PIC24F “KL” and “KA” devices (28-pin SPDIP package only)
  • PIC24F16KL402 (included in package)
  • PIC24F16KA102 (included in package)
  • PIC24F08KL302
  • PIC24F08KL402
  • PIC24F08KA102
  • PIC24F16KA302
  • PIC24F32KA302
Возможности:

    • Low Cost
    • Compatible with Microchip’s popular 16-bit XLP Development Board (Part #: DM240311)
    • Integrated Programmer / Debugger – No External Debugger Required
    • USB Powered – Ease of Use, No External Power Supply Required
    • MPLAB IDE Support
    • DUT Socket – Flexible, Easy Device Swapping
    • Works Stand-alone or Plugged into a Prototyping Board
    • Easy Access to all Device Signals for Probing
    • Smaller than a Stick of Gum at 20mm x 69mm – Easily Portable
    • On Board User and Power LEDs
    • Reset Button
    • Demo Code

Документация:
  • Даташит
  • Програмное обеспечение
  • Тестирование
Описание:
Microstick for 5V PIC24F K-series (Part #: DM240013-2) is a flexible USB powered development platform. It’s the perfect solution for those looking to get started with Microchip’s low cost 16-bit microcontroller families – 5V PIC24FV “KM” and “KA” – for extremely cost sensitive consumer, medical and industrial applications.

SUPPORTED PARTS:
Microstick for 5V PIC24F K-series supports the following 5V PIC24FV “KM” and “KA” devices (28-pin SPDIP package only)
  • PIC24FV16KM202 (included in package)
  • PIC24FV08KM202
  • PIC24FV16KM102
  • PIC24FV08KM102
  • PIC24FV32KA302
  • PIC24FV16KA302
Возможности:

    • Low Cost
    • Integrated Programmer / Debugger – No External Debugger Required
    • USB Powered – Ease of Use, No External Power Supply Required
    • MPLAB IDE Support
    • DUT Socket – Flexible, Easy Device Swapping
    • Works Stand-alone or Plugged into a Prototyping Board
    • Easy Access to all Device Signals for Probing
    • Easily Portable
    • On Board User LED
    • Reset Button
    • Demo Code

Документация:
  • Програмное обеспечение
  • Тестирование
Описание:
Showcasing PIC24F “GC” Family with High Resolution Analog, LCD, and USB

Visit theeXtreme Low Powerdesign center

Возможности:

    • 16-bit Sigma-Delta Analog to Digital Converter
    • 12-bit Pipeline 10 Msps Analog to Digital Converter
    • 10-bit 1 Msps Digital to Analog Converter (2)
    • Operational Amplifiers (2)
    • Comparators (3)
    • Voltage References (3)
    • Charge-Time Measurement Unit (CTMU)


    Included demos:

    • Analog 16-bit ADC – precision measurement and display to LCD
    • Analog 12-bit ADC – measure sensor data from Light Sensor, POT, Port Pin and stream via USB
    • Analog 10-bit DAC – generate audio tones
    • LCD Text – Left/Right Scrolling & menuing via touch button control
    • LCD Graphics – Bar graph indicator, Sine Wave
    • LCD Clock – Time, Set Time functions
    • LCD Test – Cycles through Icons and displays associated text
    • Microphone – 12-bit ADC measurement, display with bar graph on LCD
    • Temperature – Display current temperature in °C or °F
    • Sleep – Power down and display time

Документация:
  • Даташит
  • Програмное обеспечение
  • Тестирование
Описание:
The MPLAB Starter Kit for PIC24H MCUs is a complete hardware and software kit for exploring the power of PIC24H family of MCUs for multi-tasking needs. With a built-in debugger on the board, simply install the software and connect the USB cable to the PC. Start up MPLAB IDE and gain full control. Run the accelerometer based sample programs and check out the interaction of the accelerometer and the switches with the MCU on the visual display and listen to the speech playback. Connect your own analog sensor for sensor signal processing. Download and test your own applications.
The starter kit features PIC24HJ128GP504 MCU with 128 KB Flash and 8 KB RAM as the computational unit. A tri-axial accelerometer is provided for acceleration detection. The starter kit also showcases a low cost audio playback with an on-board speaker and an OLED display running Microchip Graphics library. A separate signal conditioning circuit is provided to plug-in a wide range of sensors.
Click here to see a video.
Возможности:

    • Board includes integrated debugger / programmer
    • USB powered
    • PIC24HJ128GP504 MCU with 128 KB Flash and 8 KB RAM
    • Features a tri-axial analog accelerometer, 128x64 OLED display, on-board speaker
    • Low cost speech play back of G.711 compressed speech
    • Visual display on OLED display using Microchip Graphics library
    • Switches for application utility
    • Separate analog conditioning circuitry to plug-in wide range of sensors for sensor signal processing
    • CD contains MPLAB IDE with full editor, programmer and debugger; MPLAB C Compiler; code examples and user’s guide

Документация:
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Описание:
The XLP 16-bit Development Board is designed with eXtreme Low Power in mind. Designed as a true platform for low power development, it enables designs with sleep currents as low as 20nA.

The board is suitable for prototyping many low power applications including RF sensors, data loggers, temperature sensors, electronic door locks, metering sensors, remote controls, security sensors, smart cards, and energy harvesting. The PICtail™ interface supports Microchip’s extensive line of daughter cards for easy evaluation of your next low power application.

This low cost board is the ideal complement to the MPLAB® PICkit 3 or ICD 3 debugger and programmer realizing a fully-featured, economical, PIC24 development environment.

Возможности:

    • PIC24F16KA102 (16KB Flash, 28-pins, XLP Device with 20nA Deep Sleep current )
    • Supports other PIC24F devices in 20 or 28-pins
    • Current measurement terminals allow device or board level current measurements (optional XLP Current Measurement Cable available)
    • PICtail ™ daughter board connector for connection to expansion boards such as RF, SD/MMC Cards, Speech Playback and more
    • mTouch™ capacitive sensing buttons for user input
    • Expansion connector accessing full device pin-out and breadboard prototype area
    • Convenient connections for MPLAB PICkit 3, ICD 3 or REAL ICE for in-circuit programming and debugging
    • USB interface for power and PC communication
    • 24AA256 Low Power (100nA Sleep, 1.7V Vdd) SPI serial-EEPROM
    • Crystal oscillators for main clock and Real-time Clock and Calendar
    • Potentiometer (connected to 10-bit A/D, analog input channel)
    • Analog output temperature sensor and CTMU based diode temperature sensor
    • LEDs for indication
    • Optional RS-232 port (not populated)
    • Power Options: AAA, CR2032, Energy Harvesting, USB, External, or 9V power supply

Документация:
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Описание:
The Curiosity PIC32 MZ EF Development Board is a fully integrated 32-bit development platform featuring the high performance PIC32MZ EF Series (PIC32MZ2048EFM) that has a 2MB Flash, 512KB RAM, integrated FPU, Crypto accelerator and excellent connectivity options.

The Curiosity Development Board includes an integrated programmer/debugger ,an on board Wi-Fi-N module MRF24WN0MA-I/RM100 and is fully integrated with Microchip’s MPLAB® X IDE.

Each board provides two MikroBus® expansion sockets from MicroElektronika and a Microchip X32 header to enable customers seeking accelerated application prototype development. Boards are fully integrated into PIC32’s powerful software framework, MPLAB ® Harmony that a provides flexible and modular interface to application development , a rich set of inter-operable software stack (TCP-IP,USB) and easy to use features.

X32 Boards compatible with Curiosity Board are :
PIC32 Audio Codec Daughter Card - AK4642EN (AC320100)
PIC32 Audio DAC Daughter Board - AK4384VT (AC320032-2)

The boards and ecosystem have been designed to provide an excellent out of the box experience. Customers would be able to download and run example applications /projects instantly on the boards without the need to install the entire ecosystem. The demos have been developed to showcase PIC32 MCU features and application development ecosystem.

The board offers expansion capabilities making it an excellent choice for a rapid prototyping board in Connectivity, IOT and general purpose applications.
Возможности:

    1. PIC32MZ2048EFM100 32-bit microcontroller with 2MB Flash, 512KB RAM, integrated FPU ,Crypto accelerator and excellent connectivity options.

    2. X32 header for audio I/O using Microchip audio daughter boards
    PIC32 Audio Codec Daughter Card - AK4642EN (AC320100)
    PIC32 Audio DAC Daughter Board - AK4384VT (AC320032-2)

    3.On Board WI-FI N Module, MRF24WN0MA, 2.4 GHz IEEE 802.11n compliant wireless module

    4. Header for flexible Ethernet PHY
    Compatible with ETHERNET PHY DAUGHTER BOARD AC320004-3
    The Microchip LAN8720A PHY Daughter Board is populated with a small footprint RMII10/100 Ethernet transceiver (LAN8720A).

    5. GPIO expansion header

    6. Debug USB connector for programming/debugging

    7. Target USB connector for PIC32 USB connectivity (Device/Host mode).

    8. Two mikroBUS click sockets to expand functionality using MikroElektronika ClickAdapter Boards

    9.Header for external 5V input .

    10. On-Board Debugger.

    11. ICSP header for external debugger, such as MPLAB® REAL ICE™ or MPLABICD 3

    12. Three user LEDs , One RGB LED.

    13. One User and Reset Button.

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The dsPIC33E USB Starter Kit provides a low cost method for the development and testing of USB OTG, Host and Device applications on the 60 MIPS dsPIC33E DSC family. The board contains an on-board programming/debugger, standard A USB and micro A/B connectors, three user-programmable LEDs, three push button switches and an expansion header compatible with the Multimedia Expansion Board (DM320005) and I/O Expansion Board (DM320002). The starter kit comes preloaded with basic Communication Device Class (CDC) demonstration software.

Programming, Running and Debugging Applications

Use the following procedure for programming/debugging your application programs (the dsPIC33E Start Kit CDC USB Device Demo software available from the link below is mentioned here as an example):

  • Using MPLAB IDE, open the project C:\dsPIC33E PIC24E USB Starter Kit Demo\Firmware\ USB Device - CDC - Basic Demo - dsPIC33E USB Starter Kit.mcp. (This assumes that the demo was installed in the default location)
  • Connect the starter kit to your PC using the provided USB mini-B to full-sized A cable. Note that the jumper in J5 should not be installed.
  • Choose “Starter Kit On Board” as the debugger tool in MPLAB IDE by selecting Debugger > Select Tool> Starter Kit On Board.
  • Choose the debug build configuration by selecting Project > Build Configuration > Debug.
  • Build the project by selecting Project > Build All.
  • Download the code into the starter kit by selecting Debugger > Program.
  • Run the downloaded application software by selecting Debugger > Run. At this time LED2 on the starter kit should turn on.
  • This demo allows the Starter Kit to appear as a serial (COM) port to the host. The instructions for this demo can be found at C:\dsPIC33E PIC24E USB Starter Kit Demo\Documentation\Getting Started\Getting Started - Running the Device - CDC - Basic Demo. See the Running the Demo section.

Возможности:

    • On-board programming/debugger
    • Standard A USB and micro A/B connectors
    • Three user-programmable LEDs
    • Three push button switches

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The Microstick for dsPIC33F and PIC24H devices is designed to provide designers with an easy to use, economical development environment for 16-bit dsPIC® Digital Signal Controllers and PIC® Microcontrollers.

Microstick provides all you need to get started at a very low cost. It has an integrated programmer / debugger. It can be used stand-alone or plugged into a prototyping board for extremely flexible development. The device under test is socketed for easy change-out, and Microchip’s MPLAB® Integrated Development Environment supports Microstick. It has never been more affordable to get started with Microchip 16-bit devices!

Supported Parts:
dsPIC33FJ64MC802
dsPIC33FJ128MC802
PIC24HJ64GP502
PIC24HJ128GP502
Возможности:

    • Low Cost 16-bit board – Priced at $24.99 at Microchip Direct
    • Integrated USB programmer / debugger – No external debugger required
    • USB Powered – Ease of use, No external power required
    • Socketed dsPIC/PIC24 – Flexible, Easy device replacement
    • 0.025” Pin headers – Enables plug-in to Breadboard with room for jumper wires
    • Easy access to all device signals for probing
    • Small size - Smaller than a stick of gum at 20 x76mm – Easily Portable
    • On board debug LED, Utility LED and Reset Switch
    • Free demo code

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Microstick II delivers a complete development hardware platform for Microchip’s 16-bit and 32-bit microcontrollers and digital signal controllers. It’s the perfect solution to those looking for a low-cost, easy-to-use development platform. (Note: Go to Microstick for dsPIC33F and PIC24H Development Board for information on the Microstick tool.)

The USB-powered kit includes an on-board debugger/programmer, a DUT socket for easy device swapping, a user LED and reset button. It is designed for insertion into a standard prototyping board for easy connection to additional circuitry. The kit is extremely portable as well and is still about the size of a stick of gum!

Supported Parts:
Microstick II supports 3.3V PIC24FJ, PIC24E, PIC24H, dsPIC33, and PIC32 28-pin SPDIP packaged devices shown in the table to the right (see images).
Возможности:

    • Low Cost
    • Integrated USB programmer / debugger – No external debugger required
    • USB Powered – Ease of use, No external power required
    • MPLAB support.
    • DUT Socket – Flexible, Easy device replacement
    • 0.025” Pin headers – Enables plug-in to Breadboard with room for jumper wires
    • Easy access to all device signals for probing
    • Small size - Smaller than a stick of gum at 20 x76mm – Easily Portable
    • On board User LED and Reset Switch
    • Free demo code

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The MPLAB Starter Kit for Digital Powerkit uses the dsPIC33EP64GS502 DSC to implement a buck converter and a boost converter. It is a digitally controlled power supply board that consists of one independent DC/DC synchronous Buck converter and one independent DC/DC Boost converter.Each convertercan drive its on-board MOSFETcontrolled resistive load or an external load. The board hasan LCD display for voltage, current, temperature and faultconditions, and an integrated programmer/debugger, allpowered by the included 9 V power supply.



Возможности:

    • dsPIC33EP64GS502 – Low-cost 16-bit digital power conversion DSC
    • One independent DC/DC synchronous Buck converter
    • One independent DC/DC Boost converter.
    • LCD display for voltage, current, temperature and fault conditions
    • On-board In-Circuit Debugger /Programmer via USB
    • On-board programmable resistive loads of up to 3W (0.5W, 1.25W, 1.25W)
    • Hardware slope compensation for peak current mode implementations
    • On-board temperature sensor
    • Compact Design – 4” x 2.5” board
    • Powered via 9V power supply (included)

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The mTouch AR1100 Development Kit provides everything designers need to get started using AR1100 analog resistive touch controllers for a turnkey, cost effective touch solution. The kit includes the production ready AR1100BRD controller board, USB and Serial communication cables, a 5-wire 7” touch screen, and extra touch screen pinout adapter cables to quickly test most any manufacturer’s 4, 5, or 8 wire touch screen. A CD is also included with the full suite of AR1100 utilities and all the documentation for the chip and board options of the AR1100 touch screen controller.
Возможности:

    • Supports any manufacturer's 4-, 5-, or 8-wire analog resistive touch screen
    • RS-232/UART or USB communication
    • Full suite of software drivers
    • 1024x1024 resolution
    • EEPROM calibration retention
    • Supports any size analog resistive touch screen, 1.5" - 24"
    • Kit includes a 7" 5-wire touch screen and PICKit Serial Analyer

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The PIC24FJ256DA210 Development Kit is a low cost and efficient development kit to evaluate the features and performance of the PIC24FJ256DA210 with integrated graphics, mTouch™ and USB.

This kit is an ideal platform for new graphical human interface developers. It bundles four major components and other accessories as listed below. For those who are not looking to purchase the kit with all the components, each can also be purchased separately.
  • PIC24FJ256DA210 Development Board (DM240312)
  • 3.2” Truly 240x320 TFT Display Board (AC164127-4)
  • Graphics Display Prototype Boards - 3x (AC164139)
  • MPLAB ICD-3 Emulator and Debugger with USB Cable (DV164035)
  • 9V Power Supply (AC162039)
  • USB A-miniB Cable
  • Serial Cable
Возможности:

    • PIC24FJ256DA210 16-bit microcontroller
    • Capacitive touch pads and switches
    • 3.2” Truly TFT Display with resistive touch screen support
    • Prototype graphics boards for prototyping LCD panels of choice
    • USB connectors (embedded host/device/OTG)
    • PICtail™ Plus Modular expansion slot
    • RS-232 serial port and associated hardware
    • MPLAB ICD-3 Emulator and Debugger
    • 9V Power Supply

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The F1 Evaluation Platform is a simple development tool for Enhanced Mid-range PIC microcontrollers (PIC12F1xxx/PIC16F1xxx) and demonstrates the capabilities & low power enhancements of these new PIC microcontrollers. Included with a PICkit3 for quick programming, this kit provides a platform for general purpose development and gives you the ability to develop code for any PIC12F1xxx/PIC16F1xxx microcontroller. Quick & easy development is ensured with the integrated functionality including: prototyping area, LCD control, system current monitoring, temperature sensing, Real-Time-Clock, LED drive, button control, and BLDC motor control.

Newer version development tools are available now. Please consider Curiosity Development Board (DM164137) or Explorer 8 Development Board (DM160228) for new designs


Note: The PICkit 3 In-Circuit Debugger/Programmer is NOT a production programmer. It should be used for development purposes only.
Возможности:

    • 44-pin development board with generous prototyping area
    • Populated with a PIC16LF1937 featuring nanoWatt XLP technology
    • 3 Volt, 40 segment multimeter LCD glass
    • Potentiometer
    • Mechanical button
    • MCP9800 temperature sensor
    • 32kHz low power crystal
    • LEDs
    • Current monitoring connector to measure low power XLP capabilities
    • In Circuit Serial Programming Interface for PICkit3
    • PICkit serial interface
    • Expansion header for the F1 BLDC Motor add-on (other motor add-ons not supported)
    Included Demos:
    Low Power Demonstration
    LCD Demonstration
    Brushless DC (BLDC) motor control (requires F1 BLDC motor add-on)

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The Low Voltage Motor Control Development Bundle provides a cost-effective method of evaluating and developing dual/single motor control power stage targeted to drive two Brushless DC (BLDC) motors or Permanent Magnet Synchronous Motors (PMSM) concurrently. The bundle comes with adsPIC DSC Signal board, Motor Control 10-24V Driver Board and dsPIC33EP512GM710 Dual Motor Control PIM.

The dsPIC (DSC) Signal Board supports both 3.3V and 5V operated devices for various applications andfrequently used human interface features along with the communication ports. The Signal Board has two major connectors, a 120-pin connector and a 60-pin connector to enable connection to the plug-in boards.

The Motor Control 10V–24V Driver Board (Dual/Single) along with the compatible dsPIC DSC Signal Board provides a software development platform to build and evaluate embedded motor control application software using Microchip’s high performance motor control Digital Signal Controllers (DSCs) and Microcontrollers (MCUs).
Возможности:

    dsPIC DSC Signal Board :

    120-pin power board interface connector for power application board
    60-pin expansion connector for adds-on boards
    Two 30-pin connectors for signal monitoring or expansion
    100/105 PIM header that support MCUs and dsPIC DSCs PIM with internal or external Opamp configurations
    Human Interfaces include reset and power buttons along with LED indicators for debugging purposes
    24V power input connector

    10-24V Power Board:

    Two PMSM/BLDC motor control power stages with electrical specifications:
    - Input DC Voltage: 10V–24V DC ±10%
    - Output Phase RMS Current: 10A nominal @ 25°C per phase
    MCP8024 gate drivers with under voltage, over voltage, over current, shoot through and short circuit protection
    Hall sensors or quadrature encoder interface in each motor control stages to enable sensor-based motor control algorithms
    Phase voltage and reconstructed neutral feedback signals in each motor control stages to enable sensorless BLDC operation
    DC bus current sense resistor for over current protection, torque control of BLDC motor and single shunt vector control of PMSMs.
    Phase current sensing resistors for vector control
    DC bus voltage sensing
    Dynamic brake chopper circuit with hardware and software brake control for both the inverter stages
    Over current protection and LED indication for PWM signals and power on status



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With the common use of cards instead of cash, Credit Card Reader (MSR, mag stripe/swipe readers) are an essential part of any POS system. MSRs can read any card with magnetic stripes, including some driver's licenses, gift cards, and other IDs.

Magnetic Card Readers (also known as Magnetic Stripe Readers or MSRs) read data from a 3-track magnetic stripe via a peak detection circuit and process that data for downstream users. After extracting data from the magnetic stripe, it is converted to binary data and formatted for encryption. They feed the swiped information to applications management software and connect through USB, RS-232, or PS/2 connections.

Microchip Magnetic card reader solution reads ISO/IEC-7811 cards (also known as “Frequency/double Frequency” (F2F) encoding standard).The data format encodes 7-bit data on Track1, 5-bit data for Track 2 and 3. Please refer to the features section for an in depth description of the Magnetic card readers capabilities.

Microchip offers 2 solutions, one using the dsPIC33EP family and the other using the PIC24F family of PIC's

  • For card readers that need to optimize for lowest possible power, the PIC24 XLP solution offers the lowest current consumption with sleep currents (Ipd) as low as 20uA
  • For card readers the need to optimize for lowest cost, maximumperformanceand highest level of integration, the dsPIC33 solution provides integrated op amps to save board space and component cost
This demo is not for sale, but can be easily created from components listed in the user's guide.

Возможности:

    Below are the key features of this swipe demo:

    Swipe Feature:

    • Single chip solution for reading all the 3 tracks(Note: some cards may have only Track1 and Track2 and in those cases, an error message “Track Not present” will be shown for Track3)
    • The software solution is tuned to read the swipe speeds anywhere between 60ms - 2 seconds
    • Reads both forward and reverse swipe directions
    Low Power Feature:

    • In order to reduce the power consumption, the device is put into sleep mode after every swipe
    • Even after the device is put to sleep, the swipe speed read range of 60ms - 2 seconds still holds good
    • The device wakes up during swipes by using the on-chip comparator as the wake-up source
    Software solution:

    • Exponential average mechanism is used to design the software filter
    • Interrupt based decoding of tracks
    • Integrated with MCHP AES-128 library where the user can key-in AES key on every power-up
    • The decoded data is presented either on the pin or can be dumped on a serial terminal
    • Calculates and displays the card swipe time
    Hardware Features:

    • No shielded cables are required
    • USB powered
    • On-board MCP2200
    • USB cable for the demo
    On-chip Peripherals used for the demo:

    • ADC
    • Three op-amps (one for each track)
    • Comparator to wake up from sleep
    • Timers (Four 16-bit timers)

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Bluetooth® has emerged as a standard of choice for connecting local embedded applications through a smartphone or tablet. Many applications only need simple command and control, or a quick status update from a sensor. By catering to these needs, Bluetooth Low Energy (BLE) has evolved to support these low-duty cycle applications with lower power consumption. Microchip’s eXtreme Low Power PIC® Microcontrollers and RN4020 Bluetooth low energy module help in achieving low power consumption.The PIC24FJ128GB204 or PIC24FJ256GB410devices used in this demo have an integrated hardware Crypto engine.This demonstration shows the simple communication between the RN4020 module and a Bluetooth Low Energy (BLE) supporting smartphone or tablet. The RN4020 module is controlled by the PIC24FJ128GB204 or PIC24FJ256GB410 MCU which include a hardware crypto engine used for AES encryption in the demonstration. The demo is built using standard development tools from Microchip including the Explorer 16 Board, PIC24FJ128GB204or PIC24FJ256GB410Processor Plug-In Module (PIM), and Bluetooth LE PICtail Plus Daughter Card. These readily available tools can be used to easily replicate this demo on your own. The demo is supported by MCU firmware and an app that will run on an Android phone or tablet. The first application is turning the LEDs on and off using the touch buttons on the tablet. The app can also show the state of the switches on the board, toggling on and off. The demo also includes data security using the crypto engine integrated on the PIC24FJ128GB204 or PIC24FJ256GB410 MCU, with up to128-bit AES. This demo shows a PIC24 XLP MCU working with Bluetooth LE talking to an Android tablet to show basic command and control similar to what would be used for a simple IoT sensor node. This demo can also be built using thePIC24FJ256GB410 Processor Plug-In Module in place of the PIC24FJ128GB204 Processor Plug-in Module.
Возможности:

    • PIC24FJ128GB204 or PIC24FJ256GB410 XLP MCU Plug-In Module
    • Explorer 16 Development Board
    • RN4020 Bluetooth LE Module on PICtail Daughter Card
    • Android Tablet with App
    • Integrated Hardware Encryption / Decryption
    • Bi-directional Communication
      • Basic Command & Control
      • LEDs, Switches, Temp sensor

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The PMP10601 reference design provides all the power supply rails necessary to power Xilinx® Zynq® 7000 series (XC7Z015) FPGA. This design uses several LMZ3 series modules, LDOs, and a DDR termination regulator to provide all the necessary rails to power the FPGA. It also features one LM3880 for power up and power down sequencing. This design uses a 12V input.

Возможности:

Provides all the power supply rails needed for a Xilinx® Zynq® 7000 series (XC7Z015) Design optimized to support a 12V input On board power up and power down sequencing Supports DDR3 memory device Module design for ease of use

Возможность заказа
  • Заказать BOM
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Описание:
The PMP10861 uses active clamp forward converter for an isolated 24V to 12V/3.4A conversion. Reverse input connection, output over-current protection, output over-voltage protection, input inrush current limiting circuit are integrated in this board. With wide 9-36V input voltage range, over 89.5% peak efficiency is achieved with 24V input voltage. All the components temperature rise are less than 30oC at full load condition.
Возможности:

24V to 12V/3.4A active clamp forward converter 9V to 36V input voltage range Integrated protections: reverse input connection, output over-current protection, output over-voltage protection Peak 89.5% efficiency with 24V iinput Test report available

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Эта схема реализует горячую замену с использованием контроллера горячей замены с ограничением мощности TPS2490 и двумя 30-вольтными NexFET CSD17570Q5B. Система может использоваться в серверах безопасности для подключения линейных карт во время работы системы. Постоянный ток запуска, контролируемый dV/dt управлением, поддерживает пусковые токи 1 А и 2 А. Схема может быть размещена на линейной карте. Входное напряжение 12 В, ток 60 А.

 

Возможности:

  • Законченное протестированное решение;
  • Подходит для серверных приложений;
  • Возможность обеспечить до 30 В, 0,56 мОм (типовое при 10 В);
  • CSD17570Q5B в корпусе QFN5х6 мм.

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The electrical performance of data converters depends on the cleanliness of their supply voltages. Linear regulators (LDOs) are commonly used but have low efficiency and high power loss, which is unsuitable for portable applications. Using a switch mode power supply (SMPS) instead, such as the TPS62231 and TPS62237, is a cost-effective and efficient power supply solution. Such a solution does not degrade the performance of the 12-bit ADS540x family of analog to digital converters (ADCs) and does not waste excessive power. The test report shows the Signal to Noise Ratio (SNR) and Spurious-Free Dynamic Range (SFDR) comparisons between the two power supplies, which demonstrate the same performance.

Возможности:

Efficiency increase from 47% to 83% Input current reduced from 620 mA to 350 mA No linear regulators (LDOs) required to cleanly power ADC 12-bit performance maintained Smaller DC/DC solution size than LDOs Supports 5-V input

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This reference design provides an easy method to evaluate the power, and features of SMPS dsPIC® Digital Signal Controllers in high density quarter brick DC-DC converters for intermediate bus architectures(IBA). This reference design is implemented using a single dsPIC33F “GS” digital-power DSCs from Microchip that provides the full digital control of the power conversion and system management functions. As shown in this reference design the dsPIC33F ‘GS’ devices enable designers to easily and cost effectively create products using advanced switching techniques such as Phase Shift Full Bridge (PSFB) topology that lower switching losses and enable efficiencies as high as 94%. The reference design also supports the Full Bridge topology through minor hardware modifications. The Quarter brick DC to DC Converter Reference Design is royalty free when used in accordance with the licensing agreement.

This reference design works with telecom input range 36V – 76V DC and provides 12V with 200W power. Designed with planar magnetics, this reference design implements various non-linear techniques, which improves the performance and efficiency.

Do you want a demonstration?

This reference designs hardware is not currently available for purchase. You can request a demonstration. Please contact local sales office in your geography to request a demonstration.
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Возможности:

    • Primary and Secondary MOSFET control
    • Active Current Share
    • Remote ON/OFF
    • Programmable soft start
    • Controlled Fall time
    • Voltage, Current, Temperature monitoring & Protection
    • Configurable output voltage
    • Full Digital Control
    • Supports both Full Bridge and Phase Shifted Full Bridge topologies

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Using the THS3091 high voltage, low distortion current-feedback op amp, this reference design showcases the technique and the benefits of configuring multiple op-ampsin a load sharing configuration when driving high voltage signals into heavy loads. Supported by a full scale application report, the design can be easily adjusted for a given application.

Возможности:

15V supply voltage Up to 24VPP output swing Third-Harmonic Distortion of 32dBc when driving a 20VPP, 70MHz sine wave into a 100Ω load (double-terminated 50Ω cable) Second-Harmonic Distortion of 38dBc when driving a 20VPP, 70MHz sine wave into a 100Ω load (double-terminated 50Ω cable) High Current Drive Capability (up to 400mA with two THS3091 op amps) This reference design has been lab tested and is supported with design files and a design guide

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Reference Design for a Low Power Fully Differential Programmable Gain Amplifier using the TI OPA2683 Low Power Dual Current Feedback Amplifier. This design guide reviews some of the design challenges necessary to create such a circuit. The design guide reviews the results and provides some recommendations for using/designing a Low Power FDA PGA.

Возможности:

Low Power Fully Differential Amplifier Low Power Programmable Gain Amplifier Wide Bandwidth Relative to High Gain +/-5V supply voltage Gains of 2, 21, 50, and 70 V/V This reference design has been lab tested and is supported with design files and a design guide

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Описание:
Using the LMH6629 and OPA684 op amps, this reference design deals with the difficulties and limitations of developing very high gain, multistage amplifier circuits. Supported by a full scale application report including theory, simulations, board design and evaluation, this design can be easily adjusted for a given application.

Возможности:

High Voltage Gain - up to 120,000 V/V High Bandwidth - Flat Band 100 kHz - 4 MHz @ 120,000 V/V Low Supply Operation (+/-2.5 V) Low Component Count This reference design has been lab tested and is supported with design files and an application report

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This reference design is a guide to the schematics and layout for the system designer using a GSPS ADC in their system. Use this reference design along with the datasheet — the datasheet is always the final authority. Also, the ADC1xDxxxx(RF)RB Reference Board provides a useful reference design. All design source files for the Reference Board as well as the CAD/CAE symbols for the ADC are available on the product web page or TI-Designs for download. For the purpose of this document, ADC or GSPS ADC refers to the ADC12D1800RF, ADC12D1600RF, ADC12D1000RF, ADC12D800RF, ADC12D500RF, ADC12D1800, ADC12D1600, ADC12D1000, ADC10D1500, ADC10D1000, ADC12D1600QML, and ADC10D1000QML.

Возможности:

Analog Input, clock input and Power design issues are discussed Layout concerns on synchronisation of multiple devices Understand the key care abouts of GSPS ADC schematic and layout design Examples are provided in the form of the design layout files

Документация:
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  • Топология платы
Описание:
This reference design shows the ability of the high-speed amplifier, LMH6554, to perform single-ended to differential conversion to drive high-speed analog-to-digital converters (ADCs) while maintaining excellent noise and distortion performance. Performance versus input frequency is shown for both AC and DC coupled applications while interfaced to the ADS4449 quad, 250-MSPS, 14-bit ADC. Various options for common-mode voltages, power supplies, and interfaces are discussed and measured to meet the requirements of a variety of applications. Anti-aliasing filter examples are shown along with the performance improvements that they provide.

Возможности:

High-speed single-ended to differential conversion while maintain excellent performance System performance results for LMH6554 driving ADS4449 SFDR > 82 dBFs, SNR > 71 dBFS in first Nyquist zone SFDR > 80 dBFs, SNR > 68 dBFS in second Nyquist zone Examples of both AC and DC coupled interfaces Demonstrates anti-aliasing filter design and performance gains Amplifier power supply design considerations for best performance are discussed

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Описание:
This reference design shows the ability of the high-speed amplifier, THS4509 to perform single-ended to differential conversion to drive high-speed analog-to-digital converters (ADCs) while maintaining excellent noise and distortion performance. Performance versus input frequency is shown for both AC and DC coupled applications while interfaced to the ADS4449 quad, 250-MSPS, 14-bit ADC. Various options for common-mode voltages, power supplies, and interfaces are discussed and measured to meet the requirements of a variety of applications. Anti-aliasing filter examples are shown along with the performance improvements that they provide.

Возможности:

High-speed single-ended to differential conversion while maintain excellent performance System performance results for THS4509 driving ADS4449 -SFDR > 77 dBFs, SNR > 71 dBFS in first Nyquist zone -SFDR > 69 dBFs, SNR > 67 dBFS in second Nyquist zone Examples of both AC and DC coupled interfaces Demonstrates anti-aliasing filter design and performance gains Amplifier power supply design considerations for best performance are discussed

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This design is intended to help the system designer in understanding tradeoffs and optimizing implementation for driving the Giga-Sample-Per-Second ADC with balun configurations for wideband applications. The tradeoffs considered include balun construction, insertion loss, dynamic performance, configurability, and ease of implementation. Topology and layout play a critical role in optimizing system performance, which is why these designs can help to reduce designs cycles.

Возможности:

Simplifies system design Clarifies ADC operational modes Measured system performance Uses variety of wideband baluns Shows tradeoffs by mode Recommends optimized layout

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  • Топология платы
Описание:
JESD204B links are the latest trend in data-converter digital interfaces. These links take advantage of high-speed serial-digital technology to offer many compelling benefits including improved channel densities. This reference design addresses one of the challenges of adopting the new interface: understanding and designing the link latency. An example achieves deterministic latency and determines the link latency of a system containing the Texas Instruments LM97937 ADC and Xilinx Kintex 7 FPGA.

Возможности:

Guarantee deterministic latency across the JESD204B link Understand the tradeoff between link latency and tolerance to link delay variation Use a formulaic and procedure-based approach to design the link latency Implement a JESD204B link using Texas Instruments' ADC16DX370 or LM97937 ADC and a Xilinx Kintex 7 FPGA

Документация:
  • Схемотехника
  • BOM
  • Топология платы
  • Тестирование
Описание:

Применение методов выравнивания – это эффективный способ компенсирования потерь в канале передачи по последовательному интерфейсу JESD204B в преобразователях данных. В данном базовом проекте использован ADC16DX370, сдвоенный 16-битный аналого-цифровой преобразователь (АЦП) на 370 MSPS, в котором используется метод выравнивания с ослаблением для подготовки последовательных данных для передачи со скоростью 7,4 Гбит/с. У пользователя существует возможность оптимизировать ослабление (DEM) и размах выходного напряжения (VOD) выходного драйвера, чтобы эти параметры канала находились в обратно пропорциональной зависимости. Эксперименты показывают чистый приём сигнала на расстоянии 20 дюймов с использованием материала FR-4.

Возможности:

  • Позволяет добиться высокоточной работы последовательного интерфейса JESD204B с учётом использования недорогих материалов печатной платы
  • Дает возможность прийти к пониманию ограничений, которые накладывают каналы с потерями, и освоить методы выравнивания для снятия этих ограничений
  • Использовать выверенный подход к оптимизации параметров выравнивания ADC16DX370
  • Базовый проект протестирован и включает в себя отладочный модуль, конфигурационное программное обеспечение и руководство пользователя

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
Low cost, high performance clocking solution for GSPS data converters. This reference design discusses the use of a TRF3765, a low noise frequency synthesizer, generating the sampling clock for a 4 GSPS analog-to-digital converter (ADC12J4000). Experiments demonstrate data sheet comparable SNR and SFDR performance.

Возможности:

Frequency ranges from 300MHz to 4.8GHz Low noise VCO ~ 133dBc/Hz Low jitter: 0.35ps This reference design is tested and includes an evaluation board, configuration software and User's Guide

Документация:
  • Схемотехника
  • BOM
  • Топология платы
  • Тестирование
Описание:

Растущий спрос на беспроводные сети для обеспечения быстрой передачи данных пользователям увеличивает производительность приемопередающего оборудования для обеспечения достаточной пропускной способности и поддержки крупнейших стандартизированных несущих частот (с агрегацией частот в некоторых случаях), а также достаточную чувствительность приемника и динамический диапазон для работы в присутствии сильных блокирующих сигналов в рабочем окружении.

Это решение от TI описывает подсистему RF-приемника с 16-битным сэмплером, пропускная способность которого превышает 100 МГц, включающую понижающий микшер, цифровой усилитель с переменным коэффициентом усиления (DVGA), высокоскоростной конвейерный аналого-цифровой преобразователь (ADC), гетеродин (LO), RF-синтезатор и тактовый генератор устранения джиттера.

 

Возможности:

  • Реализует подсистему RF супергетеродинного приемника с входным диапазоном частот 700-2700 МГц, шириной полосы пропускания 100 МГц и 16-битным АЦП;
  • Ускоряет время разработки беспроводной связи, программного обеспечения для радио, военных или тестово-измерительных приложений с проверкой IF сигналов цепи;
  • Оценить этот дизайн легко с поддержкой сбора данных и инструментов анализа;
  • Эта конструкция протестирована и включает оценочный модуль (EVM), приложение для настройки и руководство пользователя.

Документация:
  • Схемотехника
  • BOM
  • Топология платы
  • Тестирование
Описание:

TIDA-00374 – референс-дизайн, использующий наномощный таймер Texas Instruments, ультрамалопотребляющую беспроводную микроконтроллерную платформу SimpleLink™ и технологию зондирования влажности для демонстрации сверхнизкого потребления при использовании определенной скважности в работе датчиков конечных узлов. Использование этих технологий ведет к экстремально долгой длительности жизни батарей: более 10 лет при использовании стандартной литиевой дисковой батареи CR2032. TI дизайн включает в себя технологии проектирования систем, детальные результаты тестов, а также другую необходимую информацию по проекту.

Возможности:

Возможности:

  • Использование наномощного системного таймера для периодического с определенной скважностью получения результатов измерений, что позволяет использовать стандартные литиевые батареи более 10 лет
  • Настраиваемый интервал пробуждения системы
  • Экстремально низкий остаточный ток (183 nA в течение 59.97 sec.)
  • Ультранизкий ток в открытом состоянии благодаря низкой активности процессора и малым токам радиопередачи (4.04 mA в течение 30 ms)
  • Точность измерений относительной влажности ±2%
  • Точность измерения температуры ±0.2°C

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Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Базовый проект TSW38J84 EVM представляет собой платформу для демонстрации решения двухканального передатчика с интегрированным резонатором. В данном базовом проекте используется устройство 2.5 GSPS DAC38J84 с высококлассными модуляторами: TRF3722 (с интегрированными PLL/ VCO) и TRF3705. TRF3722 и TRF3705 можно объединить для создания двухканального решения, в котором TRF3722 будет выступать в роли локального резонатора (LO) для обоих модуляторов. Интерфейс связи между DAC38J84 и модуляторами, а также методы измерения характеристик совместной работы ЦАП и модуляторов могут варьироваться. Приведённые результаты измерений включают в себя измерения полосы пропускания, выходной точки пересечения третьего порядка, искажения гармоник и подавления частот за пределами полосы пропускания.

Возможности:

  • Полноценное решение двухканальной передачи «биты-РЧ» и использованием интерфейса JESD204B
  • Платформа для тестирования 2.5 GSPS DAC38J84 с двумя высококлассными модуляторами
  • Выходная частота TRF3722 и TRF3705 достигает 4 ГГц
  • Решение с поддержкой полосы пропускания до 1 ГГц
  • Решение двухканальной передачи для современных систем связи, военного назначения и контрольно-измерительных приборов

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Широкополосные радиочастотные приемники позволяют значительно расширить возможности радиоаппаратуры. Широкая полоса пропускания позволяет гибко настраивать каналы без внесения изменений в аппаратную часть, а так же принимать несколько каналов на разных частотах одновременно.

Данное типовое решение – широкополосный радиочастотный приемник с АЦП с частотой дискретизации 4 Гвыб./с, дифференциальным усилителем с частотой пропускания от 0 до 8 ГГц. Данный дифференциальный усилитель позволяет работать с низкочастотным сигналом, вплоть до постоянного тока, что невозможно при использовании согласующего трансформатора.

 

Возможности:

  • Типовое решение с полосой пропускания 2 ГГц
  • Поддерживает работу с постоянным током
  • Поддерживает несимметричный и дифференциальный вход
  • Решение включает в себя полноценную систему тактирования и питания

Документация:
  • Схемотехника
  • BOM
Описание:
This system level design shows how two ADC12J4000 evaluation modules (EVMs) can be synchronized together using a Xilinx VC707 platform. The design document describes the required hardware modifications and device configurations, including the clocking scheme. Example configuration files are shown for each EVM. The FPGA firmware is described and the relevant Xilinx IP block configuration parameters are shown. Data taken on the actual hardware is shown and analyzed, showing synchronization within 50 ps without characterized cables or calibrated propagation delays.

Возможности:

Demonstrates a typical phased array radar sub-system by showing synchronization of JESD204B giga-sample ADCs The LMK04828 clocking solution used is described in detail Test results show synchronization within 50 ps without any characterization of cables or calibration of propagation delays Xilinx firmware development is discussed to offer a clear understanding of the requirements This sub-system is tested and includes example configuration files

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
This TPS65218-based reference design is a compact, integrated power solution for Xilinx® Zynq® 7010 SoC/FPGAs (out of the Zynq® 7000 series family of products). This design showcases TPS65218 as an all-in-one PMIC used to supply the five rails needed for powering the Zynq® 7010 SoC/FPGAs. The total board area needed for TPS65218, including passive components, to supply the five power rails to the Zynq® 7010 is just 1.594 in2. The TPS65218 has the flexibility to support either DDR3L or DDR3 memory. This power management IC can be run from a single 5V supply or from a single cell Li-Ion battery. This design is guaranteed to operate across an industrial temperature range (-40°C to 105°C).

Возможности:

Provides 5 supply rails to power the Zynq® 7010 in a compact 1.594 in2 area (includes passive components) TPS65218 offers 4 highly efficient DC-DC converters with integrated FETs and 1 adjustable general purpose LDO Includes an integrated, programmable sequencer for flexible power-up sequencing On-chip GPIOs can be programmed to power sequence additional discrete components, if needed Qualified for Industrial Applications (-40C to 105C) This design includes a test report, an EVM guide, and design files to help accelerate the evaluation process

Документация:
  • Схемотехника
  • BOM
  • Тестирование
Описание:
The ADC12D1600RFRB reference design provides a platform to demonstrate a high speed digitizer application which incorporates clocking, power management, and signal processing. The reference design utilizes the 1.6 GSPS ADC12D1600RF device, onboard FPGA Xilinx Virtex 4, and high performance clock synthesizer LMX2531 to meet the system requirements of a 9 bit ENOB high speed digitizer.

Возможности:

2 Channels of GSPS analog-to-digital conversion Greater than 9 bits ENOB over wide input frequency range Protoype for low cost dual channel high speed digitizer for test and measurement systems

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

TIDA-00484 – референс дизайн на основе системного таймера со сверхнизким энергопотреблением, повышающего преобразователя, суб-1 ГГц беспроводного микроконтроллера SimpleLink со сверхнизким энергопотреблением и датчиком влажности. Дизайн демонстрирует способ высокоэффективных измерений, обеспечивающих чрезвычайно долгую работу от батарейки. Дизайн включает в себя материалы по проектированию системы, подробные результаты испытаний и дополнительную информацию для быстрого создания готового решения. 

Возможности:

  • Системный таймер со сверхнизким энергопотреблением, обеспечивающий работу устройства более десяти лет от батарейки CR2032;
  • Программируемый интервал пробуждения устройства;
  • Чрезвычайно низкий ток в закрытом состоянии ключа (270 нА в течении 59,97 сек.);
  • Ультранизкий ток в открытом состоянии ключа при низкой активности процессора и радиопередатчика (3,376 мА в течении 30 мс);
  • Точность измерения относительной влажности ±2%;
  • Точность измерения температуры ±0,2 °C.

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Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The TIDA-00493 TI design is a fixed gain amplifier stage for measuring low amplitude voltage and current inputs accurately over a wide dynamic range using SAR ADC for power measurement applications. Low-amplitude AC voltage from voltage dividers, current transformers or split core current sensors with a 333-mV output can be accurately measured.

Возможности:

Op-Amp Based Fixed Gain Amplifier Stage for Voltage and Current Inputs With Output Compatible to ADS8688 Input Range of ±2.56, ±5.12, and ±10.24 V. Configurations Provided: Voltage Input With Resistor Divider > 1-MΩ Impedance (No External PT Required) 333-mV AC Voltage Output Type Current Sensor Interface CT Secondary Input With Burden Resistor: Single-Ended & Differential Onboard Programmable Reference Provided for Single-Ended Measurement Applications.

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Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
TIDA-00517 provides a complete reference design for basic fan control leveraging minimal components. This design features a TMP302 temperature switch to detect over temperature conditions in personal electronics, industrial PCs, power distribution units and other applications leveraging fans to control temperature conditions. This simple design can be easily modified for different voltage fans, making it applicable for a broad range of uses.

Возможности:

• Simple temperature switch to activate fan • Flexible design can operate with many fan voltages • Low BOM count and cost • Simple temperature switch to activate fan • Flexible design can operate with many fan voltages • Low BOM count and cost

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Документация:
  • Схемотехника
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  • Топология платы
Описание:
This board allows the LMH5401 to be used as a low gain amplifier or as an attenuator.

Возможности:

DC coupled Minumum gain of 0.5V/V Split Supply voltage 6 GHz Bandwidth

Документация:
  • Схемотехника
  • BOM
Описание:
This design is a 9.8-GHz wideband, low-phase noise, integrated continuous wave (CW) RF signal generator with versatile spur reduction technique. The output level can be programmed from -32 dBm to 14.5 dBm in 0.5-dB steps. This signal generator can be used as local oscillator for applications, such as analog and vector signal generator, and can also be used as a clock generator for RF ADCs. The TIDA-00626 can be controlled from any PC via the TI USB2ANY interface and also using the microcontroller MSP430F5529 launch pad.
Возможности:

Integrated wideband frequency synthesizer with output range of 0.02 GHzto 9.8 GHz Excellent phase-noise performance; synthesizer phase noise at 6 GHz, -110 dBc/Hzat 100-KHz offset, -132 dBc/Hzat 1-MHz offset Low-noise synthesizer, in-band spurs (-75 dBc) Programmable output level 14.5 dBm to -32 dBm, 0.5-dB steps Versatile boundary spurs reduction using LMK61E2

Документация:
  • Схемотехника
  • BOM
Описание:
A wideband single-ended to differential conversion reference design in both DC- and AC- coupled applications is presented. The design evaluates the performance of the LMH5401 and LMH6401 cascade and offers insight into the design.

Возможности:

4.5GHz bandwidth with 30dB maximum total voltage gain Digitally-controlled gain range of 32dB in 1dB steps 50-Ω Input DC- or AC-coupled single-ended to differential conversion Output IP3 at RL = 200Ω: 40dBm at 500MHz 33dBm at 1GHz Output common-mode control capability: VMID ±0.5V Compact design ideal for portable application with PD = 645mW

Документация:
  • Схемотехника
  • BOM
Описание:
This board cascades two LMH5401 or LMH3401 amplifiers for more gain or more DC common mode shift.

Возможности:

DC coupled Two LMH5401 (0r 3401) amplifiers Independent supplies for each amplifier Up to 8 GHZ Bandwidth Gain to 20dB or higher Single or split supply

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Недорогой и гибкий инспектор напряжения, используемый в качестве опорного напряжения для проверки состояния батарей. Решение может быть также использовано для контроля напряжения шин питания в приложениях, требующих точного питания нескольких шин.

Источники опорного напряжения ультранизкой мощности от TI снижают общее энергопотребление системы при сохранении невысокой стоимости BOM.

Тестирование и отображение напряжения батареи служит примером того, насколько легко это может быть выполнено и реализовано в аналогичных приложениях.

Возможности:

  • Шунтирующий регулятор ATL431 обеспечивает регулирование напряжения с минимальным током потребления (60 мкА);
  • Повышающий преобразователь TLV61225 позволяет питать схему от батареи АА (вход от 0,8 В до 3,3 В);
  • Подстроечные резисторы позволяют настраивать несколько шин для контроля;
  • Низкая стоимость разработки супервизора напряжения;
  • Плата помещается на обратную сторону держателя для одной батареи АА;
  • Не требует прошивки и программного обеспечения.

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Документация:
  • Схемотехника
  • BOM
Описание:
A direct RF sampling receiver approach to a radar system operating in S-band is demonstrated using the ADC32RF45, 3-Gsps, 14-bit analog to digital converter (ADC). RF sampling reduces the complexity of a system by removing down conversion and using a high sampling rate enables wider signal bandwidths. The approach is demonstrated by building a receiver based on the ASR-11 air traffic control radar specifications.
Возможности:

S-band radar reference design using RF sampling architecture Example lineup analysis with RF sampling ADC Measurements to verify calculated performance Radar specific measurements with detection scheme Supports greater than 1-GHz instantaneous signal bandwidth

Документация:
  • Схемотехника
  • BOM
Описание:

Разработка представляет собой часть аналогового внешнего интерфейса осциллографа для входной нагрузки 50 Ом. Разработчики могут легко использовать эту платформу оценки для обработки входных сигналов постоянного напряжения до 2 ГГц в частотной и временной области применения.

Возможности:

  • Вход 50 Ом, аналоговый внешний интерфейс с входной пропускной способностью сигнала до 2 ГГц;
  • Система ENOB от 6 до 8 бит достигается с этими цепочками сигналов;
  • Поддерживается максимальный входной сигнал ± 3 В, с возможностью выбора настроек входа переменного или постоянного напряжения;
  • Функция коррекции смещения постоянного напряжения доступна в режиме ввода постоянного напряжения;
  • Коррекция смещения постоянного питания в режиме поддержки постоянного входного напряжения;
  • Три регулируемые амплитуды входного напряжения при условии интерфейсного П-аттенюатора: 1:1, 2:1 и 5:1;
  • Низкий уровень шума, высокопроизводительный дифференциальный усилитель (LMH5401) используется для единого дифференциального преобразования;
  • Высокопроизводительный усилитель с цифровым управлением и переменным коэффициентом усиления (LMH6401) программируется от 26 дБ до -6дБ с шагом 1 дБ для поддержания полного ввода в АЦП 12-бит ADC12J4000, работающий на 4GSPS для выборки входных сигналов;
  • Решение поддерживает напряжение +5 В от адаптера питания или +12 В через внутренний разъем FCM.

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
This reference design implements an IF subsystem for a standard wireless signal tester with an active balun-amplifier (LMH5401), LC bandpass filter, 16-bit ADC (ADC31JB68) and clock cleaner and generator PLL (LMK04828). Measurements using modulated signals demonstrate reception of the signal with high constellation clarity and MER sufficient for testing a wide variety of standard signal types including 802.11ac (Wi-Fi), Bluetooth, Zigbee, and the common cellular standards like UMTS and LTE.
Возможности:

Implements an IF Subsystem for Standard Wireless Signal Tester With 160-MHz Bandwidth Support for Most Standard Wireless Signal Data Types

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
Many products are now becoming connected through the Internet of Things (IoT), including test equipment such as digital multimeters (DMM). Enabled by Texas Instruments’ SimpleLink™ ultra-low power wireless microcontroller (MCU) platform, the TIDA-01012 reference design demonstrates a connected, 4½ Digit, 100kHz true RMS, DMM with Bluetooth® low energy connectivity, NFC Bluetooth pairing, and an Automatic Wake-Up feature enabled by TI’s CapTIvate™ technology.
Возможности:

4 1/2 digit, 50K count resolution Wireless MCU enabling bluetooth low energy (BLE) for IoT wireless Automatic wake-up enabled by CapTIvate capacitive touch technology Low power design and power management systems BLE mobile app pairing enabled by NFC dynamic interface Firmware-based true RMS measurements

Документация:
  • Даташит
  • Схемотехника
  • BOM
Описание:
The TIDA-01015 is a clocking solution reference design for high speed direct RF sampling GSPS ADCs. This design showcases the significance of the sampling clock to achieve high SNR for 2nd Nyquist zone input signal frequencies. ADC12J4000 is a 12-bit, 4-GSPS RF sampling ADC with 3-dB input bandwidth of 3.2 GHz capable of capturing signals up to 4 GHz. This design highlights a clocking solution for the ADC12J4000 using TRF3765, to achieve high SNR performance at high input frequencies used in applications such as digital storage oscilloscopes (DSO) and wireless testers.
Возможности:

12-bit, 4-GSPS RF sampling ADC clocking solution Up to 4-GHz input signal capture capability JESD204B compliant low-phase noise clocking solution for RF sampling ADC

Документация:
  • Схемотехника
  • BOM
Описание:
TIDA-01016 is a clocking solution for high dynamic range high speed ADC. RF input signals are directly captured using the RF sampling approach by high speed ADC. TheADC32RF45 is a dual- channel, 14-bit, 3-GSPS RF sampling ADC. The 3-dB input bandwidth is 3.2 GHz, and it captures signals up to 4 GHz. This design showcases the clocking solution using the LMX2582, to achieve the best SNR performance of ADC32RF45 at higher input frequencies used in microwave backhaul applications.
Возможности:

3 GHz low-phase noise clocking solution for RF sampling ADC with >51 dB SNR @ 3.65 GHz input 4GHz high frequency input signal capture capability Large signal bandwidth, high dynamic range RF sampling receiver solution

Документация:
  • Схемотехника
  • BOM
Описание:
The TIDA-01017 reference design demonstrates the performance of a clocking solution for a high speed multi-channel system, analyzed by measuring the channel to channel skew for the entire input frequency range of the RF sampling ADC. Channel to channel skew is critical for phased array radar and oscilloscope applications. The ADC12J4000 is a low power, 12-bit, 4-GSPS RF-sampling analog to digital converter (ADC) with a buffered analog input, integrated digital down Converter, features a JESD204B interface, and it captures signals up to 4GHz. This design showcases the clocking solution using the LMK04828, to achieve the synchronization between multiple ADC12J4000 signal chains using synchronized SYSREF.
Возможности:

Synchronization of multi-channel high speed ADCs RF sampling ADC clocking solution 4GHz high frequency input signal capture capability Low-phase noise clocking solution for RF sampling ACC

Документация:
  • Схемотехника
  • BOM
Описание:
High speed multi-channel applications require precise clocking solutions capable of managing channel-to-channel skew in order to achieve optimal system SNR, SFDR, and ENOB. This reference design is capable of supporting two high speed channels on separate boards by utilizing TI’s LMX2594 wideband PLL with integrated VCOs to generate a 10 MHz to 15 GHz clock and SYSREF for JESD204B interfaces. The 10 KHz offset phase noise is < -104 dBc/Hz for a 15 GHz clock frequency. By using TI’s ADCDJ3200 high speed converter EVMs, a board-to-board clock skew of <10ps is achieved and a SNR of 49.6 dB with a 5.25 GHz input signal. All key design theories are described, guiding users through the part selection process and design optimization. Finally, schematic, board layout, hardware testing, and results are also presented.
Возможности:

Up to 15GHz sample clock generation Multi-channel JESD204B compliant clock solution Low phase noise clocking for RF sampling ADC/DAC Configurable phase synchronization to achieve low skew in multi-channel system Supports TI’s high-speed converter and capture cards (ADC12DJ3200EVM, TSW14J56 / TSW14J57)

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The TIDA-01050 reference design aims to improve the integration, power consumption, performance, and clocking issues typically associated with automatic test equipment. This design is applicable to any ATE system but most applicable to systems requiring a large number of input channels.
Возможности:

Negative rail input (NRI), rail-to-rail output (RRO) Wide output common-mode control range Low power consumption High THD, SNR and ENOB Dual supply on AFE maximizing system performance

Документация:
  • Схемотехника
  • BOM
Описание:
The TIDA-01084 reference design demonstrates the use of RF sampling DAC to generate continuous phase-aligned multitone waveforms. With four 48-bit independent NCOs, the 14-bit, 9GSPS DAC38RF83 can generate four CW tones placed anywhere within the first Nyquist zone or up to 6 GHz in the second. This reference design covers the theory of operations, explanation of the GUI, and directions for programming NCOs to generate the tones without the requirement of an external pattern generator. This design demonstrates an easy-to-use method which greatly simplifies and reduces the bill of materials (BOM) for continuos waveform generation.

Возможности:

Generates multiple CW tones in the first nyquist and up to 6 GHz supported in the second Digital Single-Side Band Upconversion Multitone phase alignment synchronization

Документация:
  • Схемотехника
  • BOM
Описание:
The RF sampling architecture offers an alternative to the traditional super-heterodyne architecture. An RF sampling analog-to-digital converter (ADC) operates at a high sampling rate and converts signals directly from radio frequencies (RF) to digital. Because of the high sampling rate, the RF sampling architecture supports very wide signal bandwidths. Higher signal bandwidths increase the capacity of the system allowing for faster data transmission or greater user access. The reference design features the ADC32RF45 which is a dual channel,14-bit resolution ADC sampling up to 3-GSPS. The maximum signal bandwidth is set by the ADC sampling rate divided by two. With this reference design the signal bandwidth capability exceeds 1-GHz. The maximum input frequency is set by the input bandwidth of the input buffers of the ADC and the input transformers. This reference design allows direct capture of RF signals up to 4-GHz which is suitable for all of the key telecommunication bands and S-band RADAR applications. The design includes an optimized clocking solution for maintaining the JESD204B serialized data interface and achieving the highest signal-to-noise ratio (SNR) performance.

Возможности:

3-GSPS RF sampling ADC solution 1 -GHz and larger signal bandwidth capability Low noise, high dynamic range RF sampling receiver solution Low-phase noise clocking solution for RF sampling ADC

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The RF sampling receiver captures signals directly in the radio frequency (RF) band. In a multi-band application the desired signals are not very wide band but they are spaced far apart within the spectrum. The reference design captures signals in different RF bands and digitally down-converts them to baseband. The reference design showcases the ADC32RF80 dual channel, 14-bit, 3-GSPS RF sampling telecom receiver. The device includes two digital down converters (DDC) per channel. The DDC offers decimation values from 8 to 32 and includes a 16-bit numerically controlled. With the high sampling rate of the ADC32RF80 the reference design captures a large swatch of RF spectrum which contains signals in multiple bands and potentially undesired interferers. The DDC independently mixes the desired bands to digital baseband. Decimation reduces the output data rate to a lower level and provides digital filtering around the desired band to eliminate interference and to improve signal-to-noise ratio performance. This feature is critical for high end telecommunication receivers that require high dynamic range.

Возможности:

Digital down converter with decimation solution Interference avoidance configuration Low noise, high dynamic range RF sampling receiver solution Low-phase noise clocking solution for RF sampling ADC

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The TIDA-01346 design uses two LMX2594 synthesizers in combination to produce lower noise than is possible with just one. By combining the output of two synthesizers that are in phase, a theoretical 3 dB phase noise benefit is possible due to the output power being 6 dB higher while the noise power is only 3 dB higher. The LMX2594 is an ideal synthesizer for this application as it has a SYNC feature that allows it to have deterministic and repeatable phase as well as a programmable phase that can be used to correct for any phase error due to trace mismatches or any other factors.
Возможности:

3 to 12.5 GHz Output Frequency 40-fs rms Jitter at 9GHz (100 Hz to 100 MHz)

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

SimpleLink™ Bluetooth®Smart CC2650 uTag (или microtag) – это ультракомпактное решение для семейства устройств SimpleLink CC26xx. Решение подходит для приложений Интернета Вещей (IoT), требует минимум места на плате и может использоваться в модулях Bluetooth® Smart, в медицинском оборудовании и беспроводных датчиках окружающей среды для домашней автоматизации.

 

Возможности:

  • Ультракомпактные размеры платы;
  • Встроенный акселерометр и температурный датчик;
  • Миниатюрный антенный чип;
  • Создан для разработки устройств Bluetooth Smart.

Возможность заказа
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Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Емкостные сенсорные дисплеи, как правило, представляют более высокое качество и большие возможности для пользователей, чем традиционные дисплеи с резистивной сенсорной панелью. Этот референс дизайн показывает, как подключить емкостной сенсорный дисплей к процессору Sitara AM437x. Дисплей имеет встроенный контроллер сенсорной панели, который подключается к AM437x по интерфейсу I2C.

 

Возможности:

  • Цветной 7-дюймовый TFT LCD дисплей с емкостной сенсорной панелью;
  • WVGA 800x480 разрешение пикселей с 24-битным RGB интерфейсом;
  • LCD интерфейс, подключенный к встроенному DSS (Display Sub-System) Sitara AM437x процессора;
  • Емкостная сенсорная панель подключена к процессору Sitara AM437x по интерфейсу I2C;
  • 27 белых светодиодов для подсветки, управляются ШИМ контроллером TPS61081;
  • Необходимое питание для ЖК-дисплея обеспечивается линейным стабилизатором  TPS65105;
  • Полная опорная подсистема с принципиальной схемой, BOM, проектные файлы и руководство пользователя.

Возможность заказа
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Документация:
  • Схемотехника
  • BOM
Описание:
The Sitara AM437x simplified power sequence feature provides flexibility to power designers. This reference design implementation is a BOM-optimized discrete power solution for the AM437x processor with a minimal number of discrete ICs and basic feature set. The solution represents a baseline of a discrete power solution that can be extended for additional features and capabilities of the AM437x processor.

Возможности:

Simplified, BOM-optimized discrete power solution for the Sitara AM437x processor. AM437x includes an integrated LDO that simplifies processor power sequencing requirements. Systems without controlled power down can greatly benefit from this feature since the integrated LDO always ensures power up/down sequencing is met for VDDS and VDDSHVx supplies The TLV62565 step down converter provides the 3.3 volt supply and the TLV62080 provides the 1.1 volt supply. Two TLV702xx low drop out regulators (LDOs) provide the 1.5-V and 1.8-V supplies. TLV803M voltage supervisor keeps the processor in reset until all rails are operational and to reset the processor when input power is lost. This design is tested and includes schematics, BOM, design guide, and test data.

Документация:
  • Схемотехника
  • BOM
Описание:
The K2E devices require power supplies to be sequenced in a proper order. This design demonstrates power sequencing for the 66AK2Ex and AM5K2Ex families of KeyStone II ARM+DSP and ARM-only multicore processors by use of the UCD9090. The UCD9090 is a 10-rail PMBus/I2C addressable power-supply sequencer and monitor. The UCD9090 provides both sequence and timing of the power supply enables. This design shows a power sequencing implementation specific to the K2E EVM platform.

Возможности:

Power supply sequencing reference implementation for the 66AK2Ex and AM5K2Ex SoCs. Uses UCD9090 for power supply sequencing and monitoring for nine voltage rails. Uses the Fusion Digital Power Designer Software to configure and program the UCD9090. Complete system reference with schematics, BOM, design files, and HW Design Guide, implemented on the K2E EVM platform for testing and evaluation.

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Данное типовое решение - первый широкодоступный процессор со встроенным интерфейсом JESD204B и цифровым Front End’ом для разработчиков, использующих FPGA или ASIC для подключения к высокоскоростным преобразователям данных, с целью сокращения времени выхода на рынок, увеличения производительности, а так же значительного уменьшения стоимости, потребляемой мощности и размера конечного продукта. Подключение ADC12J4000 и DAC38J84 позволяет реализовать эффективные решения в приложениях тестирования, измерения и защиты.

 

Возможности:

  • Простая интеграция сигнального процессора и преобразователя данных через интерфейс JESD204B
  • Многоканальное решение с частотой дискретизации до 368Msps и полосой пропускания 150 МГц
  • Цифровой Front End для фильтрации и повышения или понижения частоты дискретизации
  • FFT/ iFFT преобразования с применением ускорителя FFTC
  • Решение оптимизировано для применения в приложениях тестирования, измерения и защиты
  • Широкополосное решение с интерфейсом JESD, включающее в себя DSP, платы АЦП и ЦАП, демонстрационное программное обеспечение, графический интерфейс пользователя для конфигурации и руководство по быстрому старту
  • Надежная платформа для демонстрации и разработки, включающая в себя три отладочные платы, схему, перечень компонентов, руководство пользователя, тесты производительности, программное обеспечение и примеры

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
For modern radar system developers currently using an FPGA or ASIC to connect to high speed data converters, who need faster time to market with increased performance and significant reduction in cost, power, and size, this reference design includes the first widely available processor integrating a JESD204B interface and Digital Front End (DFE) processing. Connecting to the ADC14X250 and DAC38J84 provides an efficient solution for avionics and defense applications such radar, electronic warfare, compute platforms and transponders.
Возможности:

Easy integration of signal processor to data converters over JESD204B Sampling of a single 100MHz channel, when connected to ADC14X250 DFE processing for filtering, down-sampling or up-sampling; FFTC hardware accelerator to offload compute-intensive 2D FFT operations, achieving low latency and high accuracy Wideband sampling with JESD attached signal processing solution including Digital Signal Processor (DSP), ADC and DAC boards, demo software, configuration GUIs and Getting Started Guide A robust demonstration and development platform including three EVMs, a deterministic latency card, schematic, BOM, user guide, benchmarks, software and demos

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
For wideband receiver system developers currently using FPGA or ASIC to connect High Speed data converters to a baseband processor, who need faster time to market with increased performance and significant reduction in cost, power, and size. This reference design includes the first widely available processor integrating a JESD204B interface and Digital Front End Processing (DFE). Connecting ADC32RF80 to DAC38J84 provides an efficient solution for avionics and defense, test and measurements and industrial applications.
Возможности:

Easy integration of signal processor to data converters over JESD204B Usable bandwidth of two 75MHz channels or a single 100MHz channel when connected to ADC32RF80 DFE processing for filtering, down-sampling or up-sampling: FFTC hardware accelerator to offload comput-intensive 2D FFT operation, achieving low latency and high accuracy Wideband sampling with JESD attached signal processing solution including Digital Signal Processor (DSP), ADC and DAC boards, demo software, configuration GUIs and getting started guide A robust demonstration and development platform including three EVMs, a deterministic latency card, schematic, BOM, user guide, benchmarks, software and demos

Документация:
  • Схемотехника
  • BOM
Описание:

Этот проверенный дизайн от TI представляет собой высокопроизводительную систему сбора данных (DAQ), использующую 18-битный АЦП SARADS8881 с частотой дискретизации 1 МГц. Конструкция оптимизирована для обеспечения низкого уровня шума и искажений для диапазона входного синусоидного сигнала 10 кГц. Это приводит к максимально возможному значению эффективного числа битов (ENOB) при общей потребляемой мощности менее 50 мВт.

В качестве драйвера входного сигнала для АЦП используется полностью дифференциальный THS4521, что обеспечивает чрезвычайно низкий уровень искажений, шума во всей полосе сигнала. Драйвер буфера использует комбинированный буфер, образованный THS4281 и OPA333, что позволяет получить требуемую производительность при низкой потребляемой мощности.

 

Возможности:

  • 18 бит, частота дискретизации 1 МГц;
  • Постоянное напряжение, переменное напряжение 10 кГц;
  • Оптимизация: ENOB;
  • Мощность: 50 мВт @ AVDD= 5 В;
  • Используется ADS8881 (18 бит, 1 МГц SARЦАП), THS4521 (Вход), OPA333 + THS4281 + REF5045 (Reference);
  • Это решение содержит: теорию, подбор компонентов, симуляцию TINA-TI, схему и макет печатной платы, проверку и измерение производительности, варианты модификации.

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Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Архитектура R-2R ЦАП имеет хорошие характеристики в части шумов и точности, но за счёт больших всплесков напряжения при смене кода. Данный проект преследует цель уменьшения всплесков напряжений, возникающих при особых изменениях кода в архитектуре R-2RЦАП. В данном проекте эти всплески уменьшаются, что делает возможным его применение в системах, чувствительных к всплескам напряжений (например, в генераторах формы сигналов).

Возможности:

  • 18-битный выход 0-5 В
  • Схема с R-2R ЦАП с уменьшением всплесков напряжений с помощью устройства хранения и выборки
  • Общая нескорректированная ошибка менее 0,15 % во всём диапазоне измерений
  • Интегральная нелинейность (INL) менее 2 наименьших значащих битов (LSB)

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Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:

В некоторых случаях осциллограф или логический анализатор не позволяют измерить очень низкий уровень шума. Данное решение позволяет усилить уровень шума на выходе тестируемого устройства до уровня, достаточного для измерения стандартными измерительными приборами. Основной особенностью данного решения является низкий собственный уровень шума и достаточная пропускная способность для измерения характеристик большинства устройств.

 

Возможности:

  • Тестовая схема для усиления шума выше порога чувствительности измерительного прибора
  • Полоса пропускания от 0.016 Гц до 443 кГц

Возможность заказа
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Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
This TI Verified Design implements a 16-bit, differential 4-channel multiplexed data acquisition system at 400KSPS throughput for high voltage differential input of ±20 V (40 Vpk-pk) industrial applications. The circuit is realized with a 16-bit successive-approximation-resistor (SAR) analog-to-digital converter (ADC), a precision high voltage signal conditioning front end, and a 4-channel differential multiplexer (MUX). The design details the process for optimizing the precision high voltage front end drive circuit using the OPA192 and OPA140 to achieve excellent dynamic performance with the ADS8864.

Возможности:

4-Channel, High-Voltage (±20 V), Multiplexed, Data Acquisition System 400 KSPS (100KSPS/Channel) Sampling Rate ±1LSB INL 16 Bit, Full Scale, Channel-to-Channel Settling 14.2 Bits ENOB

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  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Данный прецизионный испытанный проект TI представляет собой аппаратно компенсированную систему сбора данных с 3-Wire терморезистора, которая точно измеряет температуру от 0 до 100 °C. Входное и опорное напряжения находятся в ратиометрической конфигурации для уменьшения ошибок от шума и дрейфа и улучшения общей точности системы. Аппаратная реализация упрощается благодаря использованию ADS1247, в который интегрированы необходимые источники тока, программируемый усилитель и дискретно управляемый мультиплексор. Источники тока работают независимо друг от друга для минимизации несоответствия между двумя источниками. Для дальнейшего увеличения точности системы рекомендуется LDO с регулируемым выходом и высоким коэффициентом подавления пульсаций напряжения питания TPS7A4901 как замена установленному USB-источнику.

 

Возможности:

  • Измеряет температуру от 0 до 100 °C с помощью 3-Wire терморезистор
  • Решение с одним напряжением питания
  • Ратиометрическая конфигурация
  • Используется ADS1247 – 24-битный дельта-сигма АЦП

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  • Топология платы
Описание:

В данном испытанном базовом проекте подробно описываются процесс разработки, результаты симуляций и практические примеры функционирования блока сбора 12-битных дискретных данных на базе ADS7042, оптимизированные для сверхмалопотребляющих и малогабаритных применений следующих 3 групп:

  • Группа применений № 1: 12 бит и 500 kSPS для мониторинга тока, мониторинга состояния батарей, электромиографии (ЭМГ), измерения импеданса кожи и носимых фитнес-устройств.
  • Группа применений № 2: 12 бит и 1 MSPSдля жёстких дисков, управления двигателями, датчиков угла поворота двигателя, оптических датчиков угла поворота и оптических модулей.
  • Группа применений № 3: 12 бит и менее 1 kSPS для датчиков крена, гироскопов, датчиков давления, температуры, газов, химических датчиков, измерений уровня глюкозы в крови, измерений низких напряжений (1,8-3,3 В, JESD8-7A) и измерений постоянного тока.
Возможности:

  • Представляет три реализации, оптимизированные для скоростных/ силовых/ высокоточных применений
  • Включает в себя теоретический материал, анализ подбора компонентов, симуляцию, схему электрическую принципиальную, трассировку печатной платы и результаты измерений для всех трёх реализаций
  • Включает в себя подробный теоретический материал, вычисления и симуляции схемы драйвера АЦП
  • Протестированный сверхмалопотребляющий (1 мВт) SAR-сбор 12-битных данных
  • Использован ADS7042 – самый маленький в мире 12-битный SAR-АЦП
 

Возможность заказа
  • Заказать PCB
Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The environmental changes of today are no exception. Professional weather stations are rightfully used, but cannot be placed in every corner of the world. What if it was possible to make a low cost weather station, which almost everyone could afford? What if we together could help out with a piece of the puzzle, trying to solve problems ahead?

We have created a portable weather station that will measure and display weather parameters such as
• Temperature
• Humidity
• Environment Air Quality
• Light Brightness
and can be used in office environment and outdoor as well. The design uses Microchip eXtreme Low Power MCU PIC24FJ128GC010 which drives the measurement for all of the sensors. The sensor values undergo signal conditioning using microcontrollers integrated Op-Amps and analog to digital converters making the sensor reading suitable for digital processing. To allow user to control the board and select different operating modes capacitive buttons are implemented using CTMU peripheral. A segmented LCD display and USB are both output for the board. The board is powered bytwo AA batteriesand also a coin cell connected to Vbat pin of the microcontroller for maintaining real time clock information even if the main battery is removed.

Besides displaying weather data on board, we can do meaningful use of data by sending data to cloud using computers. This demo also includes connectivity to computers using USB communications device class (or USB CDC), providing an interface for transmitting and receiving to other USB based systems. The demo is supported by Schematic, User guide and MCU firmware.

This level of integration is available on Microchip’s PIC24F ‘GC’ family, we call it intelligent analog and it improves system throughput, reduces noise, and reduces system cost by integrating several analog blocks. We also integrated user interface peripherals like USB, LCD to create a product that is perfect for portable medical and industrial sensors applications.


Возможности:

Документация:
  • Даташит
  • Програмное обеспечение
  • Тестирование