Датчики - Решения

Описание:

The ADIS16203/PCBZ is a breakout board that provides (1) ADIS16203CCCZ and (1) interface PCB to simplify the process of "prototyping" during the early stages of system design and evaluation. The ADIS16203CCCZ is a fully-calibrated, digital MEMS inclinometer, which provides a serial peripheral interface (SPI) for all digital communications. It is in a 16-lead, LGA package that minimizes board space but does not support typical prototype soldering processes. The interface PCB provides access to the ADIS16203CCCZ, using dual-row, 12-pin connectors, which supports standard ribbon cable systems and hand-soldering connection techniques.

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The ADIS16ACL1/PCBZ breakout board simplifies the process of connecting ADIS16210 and ADIS16228 products to an embedded processor board or to the EVAL-ADIS2 evaluation system. The ADIS16ACL1/PCBZ also serves as a partial replacement for two evaluation tools that will soon be obsolete. Please see the following list:
  • Replace the ADIS16210/PCBZ with (1) ADIS16210CMLZ and (1) ADIS16ACL1/PCBZ
  • Replace the ADIS16228/PCBZ with (1) ADIS16228CMLZ and (1) ADIS16ACL1/PCBZ
Возможности:

  • Mating connector for the ADIS16210 and ADIS16228
  • Standard (1mm, 16-pin) ribbon cable interface for simple connection to a separate embedded processor board
  • Compatible interface with EVAL-ADIS2 platform

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The ADIS16IMU1/PCBZ is a breakout board for many of the ADIS16xxx IMU and gyroscope products. It provides a series of tapped M2x0.4mm machine screw holes to support direct-mounting with several different package styles, along with a 16-pin, dual-row, 2mm connect interface that supports simple connection with remote processor boards, using up to 12 inches of a 1mm ribbon cable.

Возможности:

  • Simplify prototype connection of many ADIS16xxx devices to existing embedded processor systems.
  • Necessary to connect some ADIS16xxx devices to the EVAL-ADIS2 evaluation system.
  • Comes with a kit of M2x0.4 machine screws and hardware to simplify DUT attachment.

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The ADXL345 is a small, thin, low power, 3-axis accelerometer with high resolution (13-bit) measurement up to ±16 g. Digital output data is formatted as 16-bit twos complement and is accessible through either an SPI (3- or 4-wire) or I2C digital interface.

The ADXL345 is well suited for mobile device applications. It measures the static acceleration of gravity in tilt-sensing appli-cations, as well as dynamic acceleration resulting from motion or shock. Its high resolution (4 mg/LSB) enables measurement of inclination changes of about 0.25°. Using a digital output accelerometer such as the ADXL345 eliminates the need for analog-to-digital conversion, reducing system cost and real estate. Additionally, the ADXL345 includes a variety of built-in features. Activity/inactivity detection, tap/double-tap detection, and free-fall detection are all done internally with no need for the host processor to perform any calculations. A built-in 32-stage FIFO memory buffer reduces the burden on the host processor, allowing algorithm simplification and power savings. Additional system level power savings can be implemented using the built-in activity/inactivity detection and by using the ADXL345 as a “motion switch” to turn the whole system off when no activity is felt and on when activity is sensed again.

The ADXL345 communicates via I2C or SPI interface. The circuits described in this document demonstrate how to implement communication via these protocols.

Figure 1. ADXL345 and ADuC7024 in 4-Wire SPI Configuration (Simplified Schematic: Decoupling and All Connections Not Shown)

Figure 2. ADXL345 and ADuC7024 in I2C Configuration (Simplified Schematic: Decoupling and All Connections Not Shown)

Возможности:

  • Programmable accelerometer up to 16g
  • Digital output easily connects to the sensor
  • Built in FIFO reduces work for processor

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The circuit, shown in Figure 1, incorporates a dual axis ADXL203 accelerometer and the AD7887 12-bit successive approximation (SAR) ADC to create a dual axis tilt measurement system. The ADXL203 is a polysilicon surface micromachined sensor and signal conditioning circuit. Acceleration in the X or Y axis will produce a corresponding output voltage on the XOUT or YOUT output pins of the device. The X axis and Y axis are perpendicular to one another. The AD8608 quad op amp buffers, attenuates, and level shifts the ADXL203 outputs so they are at the proper levels to drive the inputs of the AD7887. The rail-to-rail input/output AD8608 is chosen for its low offset voltage (65 ?V maximum), low bias current (1 pA maximum), low noise (8 nV/?Hz), and small footprint (14-lead SOIC or TSSOP). The AD7887 is configurable for either dual or single channel operation via the on-chip control register. In this application it is configured for dual channel mode, allowing the user to monitor both outputs of the ADXL203, thereby providing a more accurate and complete solution. The system maintains an accuracy of 1° over 90° and over temperature. The circuit provides this precision, performance, and range in a low cost, low power, small footprint, calibration dependent solution. The ADXL203 is specified over a minimum temperature range of ?40°C to +105°C and is available in an 8-terminal ceramic leadless chip carrier package (LCC). Figure 1. Dual Axis Tilt Measurement System (Simplified Schematic: Decoupling and All Connection Not Shown)
Возможности:

  • 1 Degree Accuracy over 90 Degrees and Temperature
  • Dual axis to ensure precise accuracy
  • Filtered to reduce inband noise
  • Precision tilt applications

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  • Тестирование
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The circuit shown in Figure 1 provides a fully programmable universal analog front end (AFE) for process control applications. The following inputs are supported: 2-, 3-, and 4- wire RTD configurations, thermocouple inputs with cold junction compensation, unipolar and bipolar input voltages, and 4 mA-to-20 mA inputs.


Today, many analog input modules use wire links (jumpers) to configure the customer input requirements. This requires time, knowledge, and manual intervention to configure and reconfigure the input. This circuit provides a software controllable switch to configure the modes along with a constant current source to excite the RTD. The circuit is also reconfigurable to set common-mode voltages for the thermocouple configuration. A differential amplifier is used to condition the analog input voltage range to the Σ-Δ ADC. The circuit provides industry-leading performance and cost.


Because of the voltage gain provided by the AD8676 and AD8275, the design is particularly suitable for small signal inputs, all types of RTDs, or thermocouples.


The AD7193 is a 24-bit Σ-Δ ADC that can be configured to have four differential inputs or eight pseudo differential inputs. The ADuM1400 and ADuM1401provide all the necessary signal isolation between the microcontroller and the ADC. The circuit also includes standard external protection and is compliant with the IEC 61000 specifications.



Figure 1. Universal Programmable Analog Front End for Process Control Applications (Simplified Schematic: All Connections and Decoupling Not Shown)

Возможности:

  • Complete Analog front end for Process Control
  • Inputs include RTD, thermocouple, 4-20 mA, +/- 10V
  • Easily switch between the various input types

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The EV-COG-AD3029 is a development platform for Analog Devices Ultra Low Power technology across ADI's MCU and RF transceiver portfolio. The board uses CrossCore Embedded Studio, an open source Eclipse based Interactive Development Environment (IDE), which can be downloaded free of charge. The platform contains many hardware and software example projects to make it easier for customers to prototype and create solutions for Internet of Things (IoT) applications.


A Cog development system may consist of these


  • A MCU Cog that highlights the differentiating values of ADI ULP portfolio.
  • An optional add-on board (Gear) for application specific use case.
  • An optional wireless board (RF-Cog) for connectivity

The Cog development system objective is to rapidly create a development/prototyping capability focused on industrial, professional, pro-sumer customers, with a flexible radio, microprocessor, sensor and application development environment.

Возможности:

  • On-board ultra-low power ARM Cortex M3 MCU
  • No external Debugger/Emulator Tools required
  • Small form factor (75X35 mm )
  • Multiple power options – USB, Coincell, External, Li-Ion
  • Onboard peripherals – Accelerometer, Temperature sensor
  • Compatible with ADI RF daughter cards, and RF modules
  • Compatible with ADI application add-on boards (Gears)
  • Expansion Connectors and Jumpers for providing external access to all MCU signals

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The AD7416/7/8 evaluation board allows the AD7416 digital temperature sensor to be quickly and easily evaluated using a PC. Using the evaluation board and its accompanying software, the AD7416/AD7417/AD7418 evaluation board can be interfaced to a PC through its USB connection.


Please note: This Evaluation software does not run on Windows 8 or Windows 10 (USB driver is non-compliant with OS >Windows 7).

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The EVAL-ADIS2 system provides a Windows-compatible evaluation system for most iSensor (ADIS16xxx) products. It comes with several application packages that run on Windows XP, Vista and 7 systems, using either 32-bit or 64-bit USB drivers. The standard 16-pin interface provides the connection path to all iSensor breakout boards (ADIS16xxx/PCBZ). Device-under-test (DUT) power can come from the USB (+3.3V, +5V selectable options) or an external power supply. For those who are familiar with the predecessor system (EVAL-ADIS), the EVAL-ADIS2 provides a number of key advancements including support for longer cabling to the DUT and operation over a wider temperature range (-40°C to +85°C)
Возможности:

  • PC-USB Inertial MEMS Evaluation System
  • Windows XP, Vista and 7 with 32-bit and 64-bit driver support
  • IMU and Vibration Evaluation software packages
  • Compatible with most ADIS1613x, ADIS162xx, ADIS163xx, ADIS164xx devices
  • Synchronous Data Capture at maximum sample rates
  • Register access for device configuration and validation
  • Standard, 16-pin ribbon cable interface with all ADIS16xxx breakout boards.
  • Up to 2m of separation with DUT

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The ADT7X10 evaluation board allows designers to easily evaluate all features of the ADT7310 and ADT7410 high accuracy temperature sensor. There are two boards - the main evaluation board and the secondary evaluation board. The secondary board can be used to measure temperatures that are remote from the main board.


Please note: This Evaluation software does not run on Windows 8 or Windows 10 (USB driver is non-compliant with OS >Windows 7).

Возможности:

  • Easy access to the ADT7310/ADT7410
  • Connects to any PC USB port
  • Self-contained evaluation system
  • Test points for access to interface signals
  • Secondary evaluation board allows remote temperature testing

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The EVAL-ADXL335Z is a simple breakout board that allows quick evaluation of the performance of the ADXL335 accelerometer. The ADXL335 is a 3-axis analog-output accelerometer with ±3 g measurement range. The small size (1" x 1") of the breakout board makes it easy to mount the accelerometer to an existing system without the need for additional hardware and with minimal effect on performance of the system and of the accelerometer.

This page contains all the information related to the EVAL-ADXL335Z including documentation, pricing, and ordering information.

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Analog Devices provides a line of evaluation boards designed to help users evaluate our instrumentation amplifiers in 8 pin packages. Access the user guide UG-261.

This user guide describes three generic evaluation boards that can be used to evaluate many of Analog Devices instrumentation amplifiers. For information on the performance of a specific instrumentation amplifier, see the data sheet for that instrumentation amplifier.

  • 3 generic, easy-to-use evaluation boards
  • Shipped with an assortment of Analog Devices, Inc., in-amps
  • Solder in the in-amp to be tested
  • Test pins already populated
  • Decoupling capacitors already populated
  • EVAL-INAMP-62RZ board: Compatible with AD620, AD621, AD622, AD623, AD627, AD8223, and AD8225 in SOIC or PDIP
  • EVAL-INAMP-82RZ board: Compatible with AD8221, AD8226, AD8227, AD8228, AD8229, AD8421, AD8422, AD8428, and AD8429 in SOIC package
  • EVAL-INAMP-82RMZ board: Compatible with AD8220, AD8221, AD8226, AD8227, AD8228, AD8236, AD8421, and AD8422 in MSOP package

Analog Devices provides a line of evaluation boards designed to help users evaluate our instrumentation amplifiers in 8 pin packages. Access the user guide UG-261.

This user guide describesAnalog Devices provides a line of evaluation boards designed to help users evaluate our instrumentation amplifiers in 8 pin packages. Access the user guide UG-261.

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The MAX1617A evaluation kit (EV kit) is a demonstration platform for the MAX1617A temperature-sensor IC. It monitors both the junction temperature of the IC and the temperature of a remote (external) diode-connected transistor, and converts these temperatures to 8-bit, 2-wire serial data. A 2N3904 remote temperature-sensor transistor comes soldered to the board in a SOT23 package, but for more realistic experiments, it can easily be removed and connected through a twisted pair to the DXP and DXN terminals.

The EV kit is designed to be connected to a standard IBM®-compatible PC parallel printer port. Signals from the parallel port are converted to open-drain SMBus™ clock and data by a 74HC05 logic chip on the board. An on-board MAX1615 linear regulator steps down the unregulated DC input to 5V to power the glue logic, the MAX1617A, and the SMBus pullup resistors.

The software runs under Windows® 95, 98, or 2000. This user-friendly program is menu-driven and offers a graphic user interface with control buttons and numeric data displays. Note: Windows 2000 requires the installation of a driver; refer to Win2000.pdf or Win2000.txt located on the diskette.
Возможности:

  • Measures and Displays Sensor Temperature
  • Simultaneously Monitors Package and a Remote Sensor
  • Programs Alarms, Configuration, and Rate
  • Operating Temperature Ranges
    • -55°C to +125°C (remote sensor)
    • 0°C to +70°C (board)
  • Easy to Use
  • Includes: Windows 95/98/2000 Software, Demo PC Board, 3.5 in. Floppy Disk

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The MAX1617 evaluation kit (EV kit) is a demonstration platform for the MAX1617 temperature-sensor IC. It monitors both the junction temperature of the IC and the temperature of a remote (external) diode-connected transistor, and converts these temperatures to 8-bit, 2-wire serial data. A 2N3904 remote temperature-sensor transistor comes soldered to the board in a SOT23 package, but for more realistic experiments, it can easily be removed and connected via a twisted pair to the DXP and DXN terminals.

The EV kit is designed to be connected to a standard IBM®-compatible PC parallel printer port. Signals from the parallel port are converted to open-drain SMBus™ clock and data by a 74HC05 logic chip on the board. An on-board MAX883 linear regulator with reverse voltage protection steps down the unregulated DC input to 5V to power the glue logic, the MAX1617, and the SMBus pull-up resistors.

The software runs under Windows® 3.1 or 95. This user-friendly program is menu-driven and offers a graphic user interface with control buttons and numeric data displays.
Возможности:

  • Measures and Displays Sensor Temperature
  • Simultaneously Monitors Package and a Remote Sensor
  • Programs Alarms, Configuration, and Rate
  • Operating Temperature Ranges:
    • -55°C to +125°C (remote sensor)
    • 0°C to +70°C (board)
  • Easy to Use
  • Includes:
    • Windows 3.1/95 Software
    • Demo PC Board
    • 3.5 in. Floppy Disk

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The MAX1630/MAX1631/MAX1632 evaluation kits (EV kits) each consist of one of three preassembled and tested evaluation boards (EV boards) that embody the standard application circuits. The MAX1630 and MAX1632 EV boards provide the triple-output 3.3V/5V/12V circuit, and the MAX1631 EV board provides the dual-output 3.3V/5V circuit.

All three use the same PC board but have different components to accommodate different input voltage ranges. The main differences between the MAX1630 and MAX1632 EV boards are in the turns ratio (1:4 or 1:2.2) and in the location of the transformer connection (3.3V side or 5V side). Connecting the transformer to the 3.3V side allows lower input voltage. Connecting the transformer to the 5V side provides slightly better efficiency and lower stress voltages.

These circuits are configured to deliver up to 3A of output current on each of the main PWM outputs with greater than 90% efficiency. The MAX1630/MAX1631/MAX1632 EV kits can also be used to evaluate other output voltages.
Возможности:

  • Battery Range:
    • 5.2V to 20V (MAX1630)
    • 5.2V to 28V (MAX1631)
    • 6.5V to 28V (MAX1632)
  • Outputs:
    • 3.3V at 3A
    • 12V at 120mA
    • 5V at 3A
    • 5V at 30mA Keep-Alive
  • 1:4 Transformer (MAX1630)
    1:2.2 Transformer (MAX1632)
  • Adjustable 2.5V to 5.5V Outputs (optional resistor divider)
  • Precision 2.5V Reference Output
  • Oscillator Sync Input
  • Low-Noise Mode Control Input (active-low SKIP)
  • Power-Good Monitor (active-low RESET output)
  • Fully Assembled and Tested

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The MAX1668 evaluation system (EV system) consists of a MAX1668 evaluation kit (EV kit) and a companion Maxim system management bus (SMBus™) interface board.

The MAX1668 EV kit is an assembled and tested PC board that demonstrates the MAX1668 temperature sensor. It monitors the temperature of four external diode-connected transistors and one internal diode, and converts the temperatures to 8-bit, 2-wire serial data. Four 2N3906 temperature-sensor transistors come soldered to the board in SOT23 packages, but for more realistic experiments, any of the transistors can be removed and the board connected through a twisted pair to remote diodes closer to your system.

The Maxim SMBus Interface Board (MAXSMBus) allows an IBM®-compatible PC to use its parallel port to emulate an Intel® SMBus 2-wire interface. Windows® 95/98/2000 compatible software provides a user-friendly interface to exercise the MAX1668 features. The program is menu driven and offers a graphic interface with control buttons and status display.

Order the MAX1668EVSYS for complete PC-based evaluation of the MAX1668. Order the MAX1668EVKIT if you already have an SMBus interface.
Возможности:

  • Measures and Displays Remote and Internal Sensor Temperature
  • Programmable Alarms and Configuration
  • Operating Temperature Ranges
    • -55°C to +125°C (Remote Sensor)
    • 0°C to +70°C (Board)
  • I²C*/SMBus Compatible
  • Easy-to-Use Menu-Driven Software
  • Assembled and Tested
  • Includes Windows 95/98/2000 Compatible Software and Demo PC Board

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The MAX1978 evaluation kit (EV kit) is a fully assembled and tested PC board that implements a complete switch-mode temperature control system for a Peltier thermo-electric cooler (TEC) module. It operates from a single 3V to 5.5V supply and provides a bipolar ±2.2A (max) output to the module.

A potentiometer, DAC, or external source generates a DC temperature set-point voltage. Thermal feedback from the TEC module is compared to the set-point voltage to generate the TEC current control signal. The MAX1978 controls TEC current to accurately regulate temperature.

When using the DAC, the EV kit connects to the parallel port of a computer running Windows® 95, 98, or 2000.
Возможности:

  • Circuit Footprint Less than 0.93in²
  • Circuit Height Less than 3mm
  • Operates from a Single Supply (3V to 5.5V)
  • ±2.2A Output Current
  • High-Efficiency Switch-Mode Design
  • Programmable Heating/Cooling Current Limit
  • TEC Current Monitor Output
  • Overtemperature, Undertemperature, and Analog Temperature Monitor
  • 500kHz or 1MHz Switching Frequency
  • SPI™-Compatible Serial Interface
  • Easy-to-Use Menu-Driven Software
  • Includes Windows 95-/98-/2000-Compatible Software and Demo PC Board
  • Surface-Mount Construction
  • Fully Assembled and Tested

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The MAX197 evaluation system (EV system) is a complete, low-cost, 8-channel data-acquisition system consisting of a MAX197 evaluation kit (EV kit) and a Maxim 80C32 or 68HC16 microcontroller (µC) module. IBM® PC compatible software provides a handy user interface to demonstrate the MAX197's many features. Source code is provided.

The MAX197 EV kit requires a single +5V supply and includes optional input buffer amplifiers that operate with ±15V supplies.

The MAX197 EV kit and EV system evaluate both the MAX197 and the MAX199. To evaluate the MAX199, order a sample of the MAX199 along with the MAX197 EV kit.
Возможности:

  • Proven PC Board Layout
  • Complete Evaluation System
  • Convenient Test Points Provided On-Board
  • Data Logging Software
  • Source Code Provided
  • Fully Assembled and Tested
  • User-Selected Microcontroller Module 80C32 or 68HC16

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The MAX31850/MAX31851 evaluation kit (EV kit) provides the hardware and software graphical user interface (GUI) necessary to evaluate the MAX31850/MAX31851 cold-junction compensated, 1-Wire® thermocouple-to-digital converter.

The EV kit comes with a MAX31850KATB+ soldered to the PCB. This is the K-type thermocouple version of the device. Other thermocouple types can be evaluated by procuring the desired thermocouple, thermocouple socket, and corresponding MAX31850 or MAX31851. Contact the factory for free samples of the devices to match your desired thermocouple type. See the Evaluating Other Thermocouple Types section in the full data sheet for part numbers and additional information regarding other thermocouple types.

Возможности:

  • Includes Everything Needed to Evaluate a MAX31850K with a K-Type Thermocouple
  • EV Kit Hardware is USB Powered (USB Cable Included)
  • Windows XP®- and Windows® 7-Compatible Operating System Software
  • USB HID Interface
  • Second Channel Allows Easy Evaluation of Other Thermocouple Types
  • Fully Assembled and Tested on Proven PCB Layout
  • RoHS Compliant

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The MAX31855 evaluation kit (EV kit) provides the hardware and software (GUI) necessary to evaluate the MAX31855 cold-junction compensated thermocouple-to-digital converter.

The MAX31855 EV kit comes with a MAX31855KASA+ soldered to the PCB. This is the K-type thermocouple version of the MAX31855. Other thermocouple types can be evaluated by procuring the desired thermocouple, thermocouple socket, and corresponding MAX31855. Contact the factory for free samples of the MAX31855 to match your desired thermocouple type. See the Evaluating Other Thermocouple Types section in the full data sheet for part numbers and additional information regarding other thermocouple types.
Возможности:

  • Includes Everything Needed to Evaluate a K-Type Thermocouple
  • EV Kit Hardware is USB Powered (USB Cable Included)
  • Windows XP®, Windows Vista®, and Windows® 7 Operating Systems-Compatible Software
  • USB HID Interface
  • Graphical User Interface (GUI) Consists of a Single .EXE File
  • Second Channel Allows Easy Evaluation of Other Thermocouple Types
  • RoHS Compliant

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The MAX44005 evaluation system (EV system) includes one MAX44005 evaluation kit (EV kit) and one MAX44005 daughter board. The EV kit is a fully assembled and tested PCB that evaluates the MAX44005 digital RGB color sensor with proximity sensor and temp sensor. The EV system also includes Windows XP®-, Windows Vista®-, and Windows® 7-compatible software that provides a simple graphical user interface (GUI) for exercising the features of the IC. The EV kit comes installed with a MAX44005EDT+ in 6-pin OTDFN package.

The daughter board is an external device-under-test module that also comes with a MAX44005EDT+ installed. The daughter board can be connected to and controlled by the EV kit. The user can also evaluate the IC by connecting a user-supplied controller to the daughter board.

Возможности:

  • USB Powered
  • Daughter Board Powered by the EV Kit
  • On-Board Infrared (IR) LED on the EV Kit and Daughter Board
  • On-Board RGB LED on the EV Kit
  • Windows XP-, Windows Vista-, and Windows 7-Compatible Software
  • Block Sampling
  • Signal Plotting in the EV System Software
  • RoHS Compliant
  • Proven PCB Layout
  • Fully Assembled and Tested

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The MAX6675 evaluation kit (EV kit) is an assembled and tested printed circuit board (PCB) that demonstrates the MAX6675 thermocouple digital temperature sensor. It accepts the input from a type-K thermocouple and converts the temperature to 12-bit data.

The MAX6675 EV kit connects to a computer for acquiring the data from the MAX6675. Windows® 95/98/2000/XP compatible software provides a user-friendly interface to display the 12-bit data and convert it to a temperature.

The EV kit includes a type-K thermocouple for evaluation up to +80°C.

To evaluate the MAX6674, order a free sample of the MAX6674ISA.
Возможности:

  • Digitizes and Displays Temperature from a Type-K Thermocouple
  • SPI™-Compatible Serial Interface
  • Easy-to-Use Menu-Driven Software
  • Available in an 8-Pin SO Package
  • Fully Assembled and Tested
  • Includes Windows 95/98/2000/XP-Compatible Software, Demo PCB, and Type-K Thermocouple

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The MAX668 evaluation kit (EV kit) combines a constant-frequency, pulse-width-modulation (PWM) step-up controller with an external N-channel MOSFET and Schottky diode to provide a regulated output voltage. The EV kit accepts a +3V to VOUT input and converts it to a +12V output for currents up to 1A, with greater than 90% conversion efficiency. The EV kit operates at 500kHz, allowing the use of small external components.

The MAX668 EV kit is a fully assembled and tested surface-mount circuit board. This EV kit can also be configured for the application circuits listed in the EV Kit Application Circuit Capabilitiestable. For input voltages below 3V and down to 1.8V, replace the MAX668 with a MAX669. The MAX669 must always operate in bootstrapped mode (JU2 shunt across pins 1 and 2).
Возможности:

  • +3V to VOUT Input Range (as shipped)
  • +12V or Adjustable Output Voltage
  • Output Current Up to 1A
  • N-Channel External MOSFET
  • 4µA IC Shutdown Current
  • 500kHz Switching Frequency
  • Surface-Mount Components
  • Fully Assembled and Tested

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The MAX6692 evaluation system (EV system) consists of a MAX6692 evaluation kit (EV kit) and a companion Maxim SMBus™ interface board.

The MAX6692 EV kit is an assembled and tested PC board with a mounted MAX6692. The EV kit allows full evaluation of the MAX6692 temperature sensor. The MAX6692 monitors its own die temperature and the junction temperature of an external diode-connected transistor. It converts the temperature to 11-bit data that may be accessed over a 2-wire serial bus.

The MAX6692 EV kit includes the external diode-connected transistor (2N3906) soldered to the board, which can be removed. The board can then be connected through a twisted pair to a remote diode close to your system.

The Maxim SMBus interface board (MAXSMBus) allows an IBM®-compatible PC to use its parallel port to emulate an Intel® system management bus (SMBus) 2-wire interface. Windows® 95/98/2000-compatible software provides a user-friendly interface to exercise the features of the MAX6692. The program is menu driven and offers a graphic interface with control buttons and status display. (Note: Windows 2000 requires the installation of a driver; refer to Win2000.pdf or Win2000.txt located on the diskette.)

The MAX6692 EV kit can also evaluate the MAX6648 and MAX6649. Order free samples of either the MAX6648MUA or MAX6649MUA through Maxim's website. Order the MAX6692EVSYS for a complete IBM PC-based evaluation of the MAX6648/MAX6649/MAX6692. Order the MAX6692EVKIT if you already have an SMBus interface.
Возможности:

  • Measures and Displays Temperature of the MAX6648/MAX6649/MAX6692 and a Remote Diode
  • Programmable Under/Overtemperature Alarms
  • Programmable Conversion Rate
  • Programmable Number of Faults Required to Assert the Alarm
  • Programmable Overtemperature Hysteresis
  • SMBus Compatible
  • Easy-to-Use Menu-Driven Software
  • Fully Assembled and Tested
  • Includes Windows 95/98/2000-Compatible Software and Demo PC Board

Документация:
  • Даташит
Описание:

Temperature is one of the most widely measured parameters in industrial process control and automation. This reference design provides a complete signal-chain solution that works with any type of RTDs, from PT100 to PT1000. The Novato PT100 2-wire, loop-powered smart temperature transmitter guarantees a low-power, easy-to-use, reliable solution of temperature measurement from -200°C to +850°C with accuracy better than 0.1% or 1.0°C, whichever is more accurate, over the entire operating range.

The Novato MAXREFDES16 smart sensor transmitter reference design features:

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:

Go-IO is an Industrial-Internet-of-Things (IIoT) reference design designed for rapid prototyping and development of configurable industrial-control systems. Typical end applications include Industry 4.0 driven process automation for building automation for intelligent buildings, smart sensors, reconfigurable industrial control systems, and robotics. All these industrial applications require a high performance, robust, configurable solution, which Go-IO provides using a modular approach. These systems are enabled by highly integrated ICs from Maxim Integrated, delivering new levels of performance while delivering lower power dissipation in tiny footprints.

Go-IO has four different boards. The different configurations provide a varying mix of type of I/O channels and communication interfaces to target different end applications.

Design files, firmware, and software can be found on the Design Resources tab. The boards are also available for purchase.

Возможности:

  • 8 Channels Isolated Digital Input
  • 4 Channels Isolated 1.2A Digital Output with Safe/Fast Demag
  • 4-Port IO-Link® Master version 1.1 compliant with TMG IO-Link Master Stack
  • 1 Isolated Power and RS-485 COM port, full duplex to 25Mbps data rate

Документация:
  • Схемотехника
  • BOM
  • Топология платы
Описание:
The MCP9700 Temperature-to-Voltage Converter PICtail™ Demo Board demonstrates how to interface the MCP9700 to a microcontroller. This can be used by the system designer as an example of how to integrate an analog temperature sensor into systems.

Возможности:

    • Firmware that uses PIC16F676 to measure and display temperature in degree Fahrenheit or Celsius
    • Small PCB layout
    • Standard 100 mil 14-pin header (P1) for easy interface to PICkit™ 1 Flash Starter Kit or custom application

Документация:
  • Програмное обеспечение
  • Топология платы
Описание:

Типовое решение NFC-DATALOGGER-EVM представляет собой модуль даталоггера с временем автономной работы порядка 5-лет и простым интерфейсом NFC (Near Field Communication) для конфигурирования и чтения.

Для максимальной гибкости система предлагает на выбор несколько конфигураций датчиков для контроля температуры (TMP112), внешнего освещения (OPT3001) и/или влажности (HDC1000/HDC1010).

Интерфейс NFC обеспечивается контроллером RF430CL331H от TI, до 64 КБ энергонезависимой памяти FRAM доступно в микроконтроллере MSP430FR5969.

Возможности:

  • Срок службы батареи CR-2032 5 лет

  • Совместимость с RF430 NFC Dynamic Tag Type 4B

  • Конфигурирование и чтение данных через NFC

  • Несколько вариантов датчиков

    - Температура (TMP112)

    - Окружающий свет (OPT3001)

    - Влажность + Температура (HDC1000/HDC1010)

  • До 64 КБ энергонезависимой памяти FRAM

  • Метка даты/времени для данных

Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • BOM
  • Топология платы
  • Тестирование
Описание:

В мощном базовом проекте с высоким КПД для генерирования стабилизированного выхода 14,4 В / 60 А используется двухфазный синхронный понижающий контроллер LM5119. Данный проект может использоваться для генерирования мощности одной автомобильной батареи из входного напряжения от системы с двумя автомобильными батареями, которая обычно применяется в грузовых автомобилях. Среди особенностей данного проекта имеются фильтрование ЭМП, защита от замены «на горячую» на выходе, отслеживание входного и выходного токов и отслеживание температуры.

Данный базовый проект имеет характер аппаратного решения.

Возможности:

  • КПД 96% при входном напряжении 24 В и выходном токе 60 А
  • Крайне низкий уровень пульсаций выходного напряжения (межпиковая амплитуда 20 мВ)
  • Внутренний источник напряжения смещения 5 В генерирует ток до 0,5 А
  • Отслеживание входного и выходного токов
  • Защита от повышенного тока на выходе

Возможность заказа
  • Заказать BOM
Документация:
  • Схемотехника
  • BOM
  • Топология платы
  • Тестирование
Описание:
Данный проект представляет собой лёгкий резонансный преобразователь с высоким КПД и высокой удельной мощностью. Он преобразует входное напряжение 390 В в выходное напряжение 48 В при выходной мощности 1 кВт. Звено питания проекта PMP20637 характеризуется удельной мощностью 140 Вт / куб. дюйм. Масса всей печатной платы составляет менее 210 гр. При частоте переключения 950 кГц в рабочем режиме максимальное значение КПД данного проекта составляет 97,6%.

Базовый проект имеет характер аппаратного решения.
Возможности:

  • Резонансный преобразователь мощностью 1 кВт с входным напряжением 390 В, выходным напряжением 48 В и высокой частотой переключения
  • Частота переключения 950 кГц при общей массе менее 210 гр.
  • В качестве входных ключей используются высоковольтные полевые GaN-транзисторы от компании TI
  • Оптимизированный LLC-преобразователь с синхронным выпрямлением на базе UCD7138 / UCD3138A
  • Габариты звена питания: 2 дюйма x 2,1 дюйма x 1,7 дюйма
  • Максимальное значение КПД 97,6%

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

The STEVAL-MKI089V1 is an adapter board designed to facilitate the evaluation of MEMS devices in the LIS331DLH product family. The board offers an effective solution for fast system prototyping and device evaluation directly within the user’s own application.

The STEVAL-MKI089V1 can be plugged into a standard DIL 24 socket. The adapter provides the complete LIS331DLH pinout and comes ready-to-use with the required decoupling capacitors on the VDD power supply line.

This adapter is supported by the STEVAL-MKI109V2 motherboard which includes a high-performance 32-bit microcontroller functioning as a bridge between the sensor and a PC, on which it is possible to use the downloadable graphical user interface (Unico GUI), or dedicated software routines for customized applications.

Возможности:

  • Complete LIS331DLH pinout for a standard DIL 24 socket
  • Fully compatible with the STEVAL-MKI109V2 motherboard
  • RoHS compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

The STEVAL-MKI105V1 is an adapter board designed to facilitate the evaluation of MEMS devices in the LIS3DH product family. The board offers an effective solution for fast system prototyping and device evaluation directly within the user’s own application.

The STEVAL-MKI105V1 can be plugged into a standard DIL 24 socket. The adapter provides the complete LIS3DH pinout and comes ready-to-use with the required decoupling capacitors on the VDD power supply line.

This adapter is supported by the STEVAL-MKI109V2 and STEVAL-MKI109V3 motherboards which include a high-performance 32-bit microcontroller functioning as a bridge between the sensor and a PC, on which it is possible to use the downloadable graphical user interface (Unico GUI), or dedicated software routines for customized applications.

Возможности:

  • Complete LIS3DH pinout for a standard DIL 24 socket
  • Fully compatible with the STEVAL-MKI109V2 and STEVAL-MKI109V3 motherboards
  • RoHS compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

The Discovery-M1 helps to discover the INEMO-M1 performance features and to facilitate its evaluation. The INEMO-M1 is the smallest 9-axis system-on-board (SoB) of the iNEMO module family; it integrates multiple ST sensors with a powerful computational core: a 6-axis geomagnetic module, a 3-axis gyroscope and an ARM Cortexв„ў M3 32-bit MCU.

The Discovery-M1 based on the INEMO-M1, and including a pressure sensor LPS331AP, represents a complete 10-DoF open platform able to provide fast inertial application development using MEMS sensors and the STM32. The pinout of the two connectors gives a complete set of communication interfaces in a very small size, making the Discovery-M1 a flexible solution for effortless orientation estimation embedded applications.

To aid in user development and analysis, the Discovery-M1 demonstration kit includes a PC GUI for sensor output display and a firmware library to quickly support the use of the demonstration board features.

Возможности:

  • Two power supply options: through the USB bus or from one of two external supply voltages, VEXT (from 3.6 to 6 V) or D_VDD (from 2.4 V to 3.3 V)
  • INEMO-M1: 9-axis SoB, 13x13x2 mm size factor
  • LPS331AP: MEMS pressure sensor 260-1260 mbar absolute digital output barometer
  • INEMO-M1 pinout available on two double connectors
  • SWD connector for programming and debugging.
  • Two pushbuttons (reset and user)
  • Two LEDs: user LED, power-on LED
  • RoHS compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

The STEVAL-MKI153V1 is an adapter board designed to facilitate the evaluation of MEMS devices in the H3LIS331DL product family. The board offers an effective solution for fast system prototyping and device evaluation directly within the user’s own application.

The STEVAL-MKI153V1 can be plugged into a standard DIL 24 socket. The adapter provides the complete H3LIS331DL pinout and comes ready-to-use with the required decoupling capacitors on the VDD power supply line.

This adapter is supported by the STEVAL-MKI109V2, which is a motherboard including a high-performance 32-bit microcontroller which functions as a bridge between the sensor and a PC, on which it is possible to use the downloadable graphical user interface (Unico GUI), or dedicated software routines for customized applications.

Возможности:

  • Complete H3LIS331DL pinout for a standard DIL 24 socket
  • Fully compatible with STEVAL-MKI109V2 motherboard
  • RoHS compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

The STEVAL-MKI198V1K evaluation kit consists of a probe with the STTS751 temperature sensor connected via flat cable to the STEVAL-MKIGIBV1 adapter board, so it can interface with the STEVAL-MKI109V3 motherboard.

The device small package dimensions allow it to be mounted on top of a very thin probe, so it can take temperature readings not influenced by heat from other electronic components or boards.

The STEVAL-MKIGIBV1 can be plugged into a standard DIL24 socket. The kit provides the complete STTS751 pinout and comes ready-to-use with the required decoupling capacitors on the VDD power supply line.

The STEVAL-MKI109V3 motherboards feature a high performance 32-bit microcontroller functioning as a bridge between the sensor and a PC running the free Unico GUI graphical user interface or dedicated software routines for customized applications.

Возможности:

  • User friendly STTS751 board
  • Complete STTS751 pinout for a standard DIL24 socket
  • Fully compatible with STEVAL-MKI109V3 motherboards
  • RoHS compliant
  • WEEE compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

The STEVAL-MKI201V1K evaluation kit consists of a probe with the STTS75 temperature sensor connected via flat cable to the STEVAL-MKIGIBV1 adapter board, so it can interface with the STEVAL-MKI109V3 motherboard.

The device small package dimensions allow it to be mounted on top of a very thin probe, so it can take temperature readings not influenced by heat from other electronic components or boards.

The STEVAL-MKIGIBV1 can be plugged into a standard DIL24 socket.

The kit provides the complete STTS75 pinout and comes ready-to-use with the required decoupling capacitors on the VDD power supply line.

The STEVAL-MKI109V3 motherboards feature a high performance 32-bit microcontroller functioning as a bridge between the sensor and a PC running the free Unico GUI graphical user interface or dedicated software routines for customized applications.

Возможности:

  • User friendly STTS75 board
  • Complete STTS75 pinout for a standard DIL24 socket
  • Fully compatible with STEVAL-MKI109V3 motherboards
  • RoHS compliant
  • WEEE compliant

Документация:
  • Даташит
  • BOM
  • Топология платы
Описание:

Базовый проект TIDA-00156 представляет собой решение внутреннего освещения в автомобиле с емкостным управлением и тактильной обратной связью, оптимизированное для применений в автомобильных потолочных плафонах и плафонах с водительской стороны. Данное решение включает в себя тактильный драйвер с обширной встроенной библиотекой (более 100 эффектов) для приводов двигателей с эксцентричной вращающейся массой, LED-драйвер с постоянным током с интегрированным ШИМ-входом, позволяющим регулировать яркость светодиода, малопотребляющий МК, оптимизированный для емкостного управления, а также интерфейс связи LIN.

Возможности:

  • Широкий диапазон входного напряжения: типовое значение 12 В, 8-18 В непрерывного напряжения, 42 В в режиме сброса нагрузки
  • Малый ток потребления системы (менее 100 мкА) благодаря МК MSP430, вводящему ключевые компоненты системы в режим сна
  • Понижающий преобразователь с частотой переключения 400 кГц для выхода за пределы диапазона частот AM
  • В проект заложена возможность подавать как постоянный, так и управляемый с помощью ШИМ, ток светодиода
  • Интегрированная библиотека форм сигналов с лёгким доступом посредством I2C для различных эффектов тактильной обратной связи
  • Возможность реализации емкостного детектирования касания без использования внешних компонентов благодаря встроенному MSP430

Возможность заказа
  • Заказать BOM
  • Заказать PCB
Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • BOM
  • Топология платы
  • Тестирование
Описание:

В данном проекте TI использована технология ёмкостно-цифрового преобразования для реализации высокоточной методики пробуждения систем при взаимодействии с человеком. В TIDA-00220 продемонстрированы альтернативные пути проектирования датчиков, компенсации факторов окружающей среды и защиты от электромагнитных помех.

 

Возможности:

  • Обнаруживает приближение человека с помощью проводящего напечатанного датчика из никеля, что даёт возможность сделать промышленный дизайн более гибким
  • Сам датчик может быть выполнен из меди или другого проводящего материала
  • Уменьшает влияние факторов окружающей среды несколькими методами
  • Расстояние обнаружения зависит от геометрии датчика (20 см на испытанном оборудовании)
  • Низкое энергопотребление на уровне 6.2 мВт
  • Эта полностью испытанная и описанная подсистема включает в себя файлы аппаратной части проекта (схему электрическую принципиальную и трассировку платы), прошивку и подробное руководство пользователя с результатами испытаний

Возможность заказа
  • Заказать BOM
  • Заказать PCB
Документация:
  • Даташит
  • Схемотехника
  • Програмное обеспечение
  • BOM
  • Топология платы
  • Тестирование
Описание:

Базовый проект, в котором используется чипсет семейства DLP Pico™ для WXGA-дисплеев с диагональю матрицы микрозеркал 0,45 дюйма, позволяет применять разрешение высокой чёткости (HD) в таких проекционных дисплеях, как вспомогательные проекторы, интеллектуальные проекторы и мобильное Smart TV, а также таких встроенных проекторах, как проекторы в составе ноутбуков, портативных компьютеров и «горячих точках» (хот-спотах). Чипсет, использованный в данном проекте, состоит из цифрового устройства с микрозеркалами (Digital Micromirror Device, DMD) DLP4501 с матрицей зеркал с диагональю 0,45 дюйма и разрешением WXGA и контроллера дисплея DLPC6401. С базовым проектом внешнего LED-драйвера можно ознакомиться по следующей ссылке: PMP4356.

Данный базовый проект имеет характер аппаратного решения.

Возможности:

  • Базовый проект с использованием чипсета DLP4501 с разрешением HD, который состоит из DMD DLP4501 и контроллера DLPC6401
  • Данный базовый проект включает в себя детализированную схему электрическую принципиальную, Gerber-файлы и перечень элементов для быстрой и простой интеграции проекционного дисплея с технологией DLP в различные применения дисплеев

Документация:
  • Схемотехника
  • BOM
  • Топология платы
  • Тестирование
Описание:
Данный проект позволяет точно измерять интенсивность окружающего света, что может использоваться для детектирования вспышек дуги с временем отклика 1 мс для защиты или минимизации повреждений распределительных устройств электросетей. Данный проект также позволяет точно отслеживать температуру (с использованием ключа, аналоговой или цифровой схемы или удалённо), влажность, концентрацию пыли и давление для мониторинга состояния сборных шин, трансформаторов и конденсаторных батарей в реальном времени с целью определения неисправностей, повреждений изоляции или отказов из-за устаревания на раннем этапе, что в свою очередь увеличивает срок службы оборудования. В данном проекте представлен уникальный диагностический подход, при котором в течение 1 мс удаётся детектировать низкий ток нагрузки на датчике освещённости, что в свою очередь повышает надёжность системы. Датчики могут сопрягаться с микроконтроллером по интерфейсу I2C или по малопотребляющему беспроводному интерфейсу для выполнения функций передатчиков метеоданных с целью осуществления беспрерывного мониторинга в реальном времени, что позволяет упростить дизайн системы.

Базовый проект имеет характер аппаратно-программного решения.
Возможности:

  • Позволяет измерять интенсивность света, температуру, влажность, концентрацию пыли, интенсивность вибраций и давление; поддерживает несколько типов датчиков температуры и освещённости
  • Позволяет измерять интенсивность света от вспышек дуги с помощью датчика освещённости с аналоговым выходом для обеспечения быстрого отклика (время отклика менее 1 мс)
  • Для измерения параметров выхода с датчика освещённости используется 10-битный SAR-АЦП с интерфейсом I2C и выходным аварийным сигналом
  • В данном проекте используется аппаратный компаратор, обеспечивающий быстрый отклик на возникновение неисправности при изменении интенсивности окружающего света. Пороговое значение срабатывания компаратора может быть задано с использованием 10-битного АЦП или цифрового потенциометра
  • Позволяет измерять температуру дистанционно с использованием последовательного интерфейса UART, выходного аварийного сигнала и возможности работы с последовательным или мультиплексированным подключением датчиков
  • Поддерживает функции точной диагностики датчиков освещённости и температуры с длительностью диагностики около 1 мс, что позволяет осуществлять данный процесс в реальном времени

Документация:
  • Даташит
  • Схемотехника
  • BOM
  • Топология платы
*Информация о ценах и сроках поставки носит информационный характер. Офертой является только выставленный счет.

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