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1121 User Guide: Difference between revisions

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Why is adjusting the resistance important? The Analog Input can measure a voltage between 0V and 5V. The analog measurement is represented in the software as a value between 0 and 1000,so a sensor value of 1 unit represents a voltage of approximately 5 millivolts. When using variable resistance devices a voltage divider is commonly used to measure the changing resistance. The two resistors in the divider form a voltage, based on the ratio between them.  This voltage is then measured by the Analog Input. To optimize the voltage divider to meet your need you have to adjust the fixed resistance to match the characteristics of your chosen sensor. To adjust the resistance on the Voltage Divider, simply turn the screw on the potentiometer clockwise to decrease the resistance and counterclockwise to increase it. You get between 900 ohm to 1000 ohm change in resistance per revolution. First, adjust the resistance for no stimuli on your sensor and then apply maximum stimuli and make sure that Sensor Value stays within a range that gives you expectable resolution.  At the extremes (<50, >950), a very large change in stimuli (and therefore change in the resistance) produces only a small change in Sensor Value. Keep adjusting until you get a range you are happy with.
Why is adjusting the resistance important? The Analog Input can measure a voltage between 0V and 5V. The analog measurement is represented in the software as a value between 0 and 1000,so a sensor value of 1 unit represents a voltage of approximately 5 millivolts. When using variable resistance devices a voltage divider is commonly used to measure the changing resistance. The two resistors in the divider form a voltage, based on the ratio between them.  This voltage is then measured by the Analog Input. To optimize the voltage divider to meet your need you have to adjust the fixed resistance to match the characteristics of your chosen sensor. To adjust the resistance on the Voltage Divider, simply turn the screw on the potentiometer clockwise to decrease the resistance and counterclockwise to increase it. You get between 900 ohm to 1000 ohm change in resistance per revolution. First, adjust the resistance for no stimuli on your sensor and then apply maximum stimuli and make sure that Sensor Value stays within a range that gives you expectable resolution.  At the extremes (<50, >950), a very large change in stimuli (and therefore change in the resistance) produces only a small change in Sensor Value. Keep adjusting until you get a range you are happy with.
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Revision as of 16:20, 26 July 2012


Getting Started

Checking the Contents

You should have received:

  • A voltage divider
  • A sensor cable

In order to test your new Phidget you will also need:

  • A PhidgetInterfaceKit 8/8/8 or PhidgetTextLCD
  • A USB cable
  • A variable resistance sensor

Connecting the Pieces

  1. Connect the Voltage Divider to the Analog Input 6 on the PhidgetInterfaceKit 8/8/8 using the sensor cable.
  2. Connect the variable resistance sensor to the terminal block on the Voltage Divider.
  3. Connect the PhidgetInterfaceKit to your PC using the USB cable.

1121 0 Connecting The Hardware.jpg

Testing Using Windows 2000 / XP / Vista / 7

Make sure you have the current version of the Phidget library installed on your PC. If you don't, follow these steps:

  1. Go to the Quick Downloads section on the Windows page
  2. Download and run the Phidget21 Installer (32-bit, or 64-bit, depending on your system)
  3. You should see the Ph.jpg icon on the right hand corner of the Task Bar.

Running Phidgets Sample Program

Double clicking on the Ph.jpg icon loads the Phidget Control Panel; we will use this program to ensure that your new Phidget works properly.

The source code for the InterfaceKit-full sample program can be found in the quick downloads section on the C# Language Page. If you'd like to see examples in other languages, you can visit our Languages page.

Updating Device Firmware

If an entry in this list is red, it means the firmware for that device is out of date. Double click on the entry to be given the option of updating the firmware. If you choose not to update the firmware, you can still run the example for that device after refusing.

Double Click on the Ph.jpg icon to activate the Phidget Control Panel and make sure that the Phidget InterfaceKit 8/8/8 is properly attached to your PC.

1018 2 Control Panel Screen.jpg
  1. Double Click on Phidget InterfaceKit 8/8/8 in the Phidget Control Panel to bring up InterfaceKit-full and check that the box labelled Attached contains the word True.
  2. Make sure that the Ratiometric boxis Ticked.
  3. As you apply a stimuli (in ourexample, pushing on the variableforce sensor) you should see thevalue change in the Analog In box.
  4. You can adjust the input sensitivityby moving the slider pointer.
  5. Click on the Sensors button to bring up the Advanced Sensor Form.

1121 0 InterfaceKit Screen.jpg

  1. In the Sensor 6 box, select the 1121 - Voltage Divider from the drop down menu.
  2. The voltage measured across the sensor isshown here.
  3. Formula used to convert the analog input SensorValue into voltage.

1121 0 Advanced Sensor Form Screen.jpg

Testing Using Mac OS X

  1. Go to the Quick Downloads section on the Mac OS X page
  2. Download and run the Phidget OS X Installer
  3. Click on System Preferences >> Phidgets (under Other) to activate the Preference Pane
  4. Make sure that the is properly attached.
  5. Double Click on in the Phidget Preference Pane to bring up the Sample program. This program will function in a similar way as the Windows version.

Using Linux

For a step-by-step guide on getting Phidgets running on Linux, check the Linux page.

Using Windows Mobile / CE 5.0 / CE 6.0

For a step-by-step guide on getting Phidgets running on Windows CE, check the Windows CE page.

Technical Details

Configuring the Voltage Divider

Why is adjusting the resistance important? The Analog Input can measure a voltage between 0V and 5V. The analog measurement is represented in the software as a value between 0 and 1000,so a sensor value of 1 unit represents a voltage of approximately 5 millivolts. When using variable resistance devices a voltage divider is commonly used to measure the changing resistance. The two resistors in the divider form a voltage, based on the ratio between them. This voltage is then measured by the Analog Input. To optimize the voltage divider to meet your need you have to adjust the fixed resistance to match the characteristics of your chosen sensor. To adjust the resistance on the Voltage Divider, simply turn the screw on the potentiometer clockwise to decrease the resistance and counterclockwise to increase it. You get between 900 ohm to 1000 ohm change in resistance per revolution. First, adjust the resistance for no stimuli on your sensor and then apply maximum stimuli and make sure that Sensor Value stays within a range that gives you expectable resolution. At the extremes (<50, >950), a very large change in stimuli (and therefore change in the resistance) produces only a small change in Sensor Value. Keep adjusting until you get a range you are happy with.

1121 0 Schematic.jpg

Non-Phidgets Sensors

Here is a list of interesting variable resistance sensors that could be used with the Voltage Divider.

Light Sensors:

http://www.digikey.com

Light Sensors - CDS Photocells (Advanced Photonics)

Search for “photocell”

Examples - “PDV-P9003-1”

Force Sensors

http://www.digikey.com

Force Sensors (CUI Inc.)

Search for “force sensor”

Examples - “IESP-12”

http://www.trossenrobotics.com

Force Sensing FSRs

Thermistors

http://www.digikey.com

Search Digikey for ‘Thermistor Radial’

Choose a thermistor with a resistance in the range 10K ohms.

Bend sensor

http://www.imagesco.com

Other Interfacing Alternatives

If you want maximum accuracy, you can use the RawSensorValue property from the PhidgetInterfaceKit. To adjust a formula, substitute (SensorValue) with (RawSensorValue / 4.095) If the sensor is being interfaced to your own Analog to Digital Converter and not a Phidget device, our formulas can be modified by replacing (SensorValue) with (Vin * 200). It is important to consider the voltage reference and input voltage range of your ADC for full accuracy and range.


Each Analog Input uses a 3-pin, 0.100 inch pitch locking connector. Pictured here is a plug with the connections labelled. The connectors are commonly available - refer to the Analog Input Primer for manufacturer part numbers.

Analoginput.jpg

Product History

Date Board Revision Device Version Comment
August 2007 0 N/A Product Release