1101 User Guide: Difference between revisions

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__NOINDEX__
<metadesc>The Phidget IR Distance Adapter lets you read Sharp distance sensors with a Phidgets Analog Input or VINT Hub port.</metadesc>
[[Category:UserGuide]]
[[Category:UserGuide]]
==Getting Started==
{{UgSensorIntro|1101|IR Distance Adapter|Voltage Ratio Input port}}
*{{CT|SharpSensor|Sharp distance sensor}}


===Required Hardware===


* A 1101 IR Distance Adapter
Next, you will need to connect the pieces:
* An InterfaceKit or Hub to read the sensor
[[Image:1101_0_Connecting_The_Hardware.jpg|500px|right|link=]]
* A Phidget cable
# Connect the Sharp distance sensor to the 1101.
* A USB cable
# Connect the 1101 to the HUB0000 using the Phidget cable.
* A computer
# Connect the HUB0000 to your computer using the USB cable.
* A compatible Sharp IR distance sensor


===Connecting the Pieces===
<br clear="all">
[[Image:1101_0_Connecting_The_Hardware.jpg|400px|right|link=]]
{{UGIntroDone|1101}}
# Connect the Sharp IR distance sensor to the 1101 adapter.
# Connect the adapter to the InterfaceKit or Hub using the Phidget cable.
# Connect the InterfaceKit or Hub to your computer using the USB cable.


<br clear="all">
==Using the 1101==
==Testing Using Windows==
{{UGcontrolpanelSensor|1101|HUB0000}}


{{UgSensor}}
{{UGSensorVoltageRatioInput|1101|distance (cm)}}


==Technical Details==
==Technical Details==
===General===
The function of the 1101 is to regulate the power requirement of the connected Sharp distance sensor, smoothing out current spikes that could otherwise overwhelm the device measuring them.


The function of the IR Distance Adapter Board is to regulate the power requirement of the connected sensor. Although the specified current consumption may be low for these types of sensors, they may draw much more current for short periods of time during measurements. If two or more of these sensors are directly connected to the analog inputs of a PhidgetInterfaceKit, (which can source a maximum of 500mA current total) then the InterfaceKit may potentially experience an overload.  Up to eight Sharp IR Distance sensors can safely be connected to the PhidgetInterfaceKit 8/8/8 at the same time through IR Distance Adapter Boards, which prevents the possibility of overcurrent.
Make sure that the distance of the object being measured is within the distance range of the sensor. When the object is outside the valid sensor's distance range, the returned value should be discarded. You must be especially careful when the object is closer than it should be, as the returned value might be within the expected voltage range but is not meaningful. If the sensor is being used outdoors, be mindful that sunlight can cause interference, especially when the sunlight is entering at such an angle that it is within the sensor's cone of detection. The IR light from these sensors can pass through glass, but only if the glass is completely clear and the sensor is perpendicular and very close to the surface of the glass. Otherwise, too much IR light will be reflected for the sensor to work properly.
 
Sharp IR distance sensors are recommended for use with the IR Distance Adapter board. The sensor values given will be outside the specified range when no object is present, and fall between a specific range when an object isdetected. For analog type sensors, the output is roughly inversely proportional to the distance between the specific range. For digital type sensors, output below a certain value can be treated as a detection.
 
Make sure that the distance of the object being measured is within the distance range of the sensor. When the object is outside the valid sensor’s distance range, the returned value should be discarded. You must be especially careful when the object is closer than it should be, as the returned value might be within the expected voltage range but is not meaningful. If the sensor is being used outdoors, be mindful that sunlight can cause interference, especially when the sunlight is entering at such an angle that it is within the sensor's cone of detection. The IR light from these sensors can pass through glass, but only if the glass is completely clear and the sensor is perpendicular and very close to the surface of the glass. Otherwise, too much IR light will be reflected for the sensor to work properly.


===Formulas===
===Formulas===
These formulas are derived from the Sharp datasheets to compute distance and are only valid for the Sharp Distance Sensors that we stock and sell on [http://www.phidgets.com Phidgets.com].
{{UGSensorFormula|distance (cm)}} These formulas are derived from the Sharp datasheets to compute distance and are only valid for the {{CT|SharpSensor|Sharp distance sensors}} we sell.  
* 3520 - Sharp Distance Sensor 2D120X (4-30cm)
* 3521 - Sharp Distance Sensor 2Y0A21 (10-80cm)
* 3522 - Sharp Distance Sensor 2Y0A02 (20-150cm)




The formula to translate voltage into Distance for Sharp 4-30cm analog sensor is:
The formula to translate voltage ratio into Distance for Sharp 4-30cm analog sensor is:


::<math>
::<math>
\text{Distance (cm)} = \frac{519}{(\text{Voltage} \times 50) + \frac{11}{4}}
\text{Distance (cm)} = \frac{2.076}{\text{VoltageRatio} - \text{0.011}}
</math>
</math>


:This formula is only valid over the voltage range 0.4V to 2.65V.
:This formula is only valid for VoltageRatio between 0.08 and 0.53.




Line 48: Line 43:


::<math>
::<math>
\text{Distance (cm)} = \frac{24}{\text{Voltage}  - 0.01}
\text{Distance (cm)} = \frac{4.8}{\text{VoltageRatio}  - 0.02}
</math>
</math>


:This formula is only valid over the voltage range 0.4V to 2.5V.
:This formula is only valid for VoltageRatio between 0.08 and 0.53.




Line 57: Line 52:


::<math>
::<math>
\text{Distance (cm)} = \frac{47.31}{\text{Voltage}  - 0.085}
\text{Distance (cm)} = \frac{9.462}{\text{VoltageRatio}  - 0.01692}
</math>
</math>


:This formula is only valid over the voltage range 0.4V to 2.45V.
:This formula is only valid for VoltageRatio between 0.08 and 0.49.
 
 
For digital distance sensors, the sensor voltage will be greater than 1V if the distance of the object being measured is less that the detection distance of the sensor. Otherwise the voltage will be less than 1V.  


'''Note:''' The output of this sensor will vary from unit to unit, and based on the characteristics of the target (reflectance, size, direction of motion, object alignment, etc). Our formula is based on the data provided by Sharp. If you find that you are not getting good results with the standard formulas, you may want to derive your own formula to better characterize your situation.
'''Note:''' The output of this sensor will vary from unit to unit, and based on the characteristics of the target (reflectance, size, direction of motion, object alignment, etc). Our formula is based on the data provided by Sharp. If you find that you are not getting good results with the standard formulas, you may want to derive your own formula to better characterize your situation.
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{| style="border:1px solid darkgray;" cellpadding="7px;" width="40%"
{|class = "wikitable"
|-style="background: #e9e9e9" align=center
| align="center" style="background:#f0f0f0;"|'''Manufacturer '''
! Manufacturer || Part Number || Description
| align="center" style="background:#f0f0f0;"|''' Part Number'''
| align="center" style="background:#f0f0f0;"|'''Description'''
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0A02YK0F
|style="width: 10%;align=left| GP2Y0A02YK0F
|style="width: 10%; background: #f0f0f0" align=left| 20-150cm Analog
|style="width: 10%;align=left| 20-150cm Analog
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0A02YK
|style="width: 10%;align=left| GP2Y0A02YK
|style="width: 10%; background: #f0f0f0" align=left| 20-150cm Analog (non-RoHS)
|style="width: 10%;align=left| 20-150cm Analog (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0D21YK0F
|style="width: 10%;align=left| GP2Y0D21YK0F
|style="width: 10%; background: #f0f0f0" align=left| 24cm Digital
|style="width: 10%;align=left| 24cm Digital
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0D21YK
|style="width: 10%;align=left| GP2Y0D21YK
|style="width: 10%; background: #f0f0f0" align=left| 24cm Digital (non-RoHS)
|style="width: 10%;align=left| 24cm Digital (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D14J0000F
|style="width: 10%;align=left| GP2D14J0000F
|style="width: 10%; background: #f0f0f0" align=left| 24cm Digital
|style="width: 10%;align=left| 24cm Digital
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D15
|style="width: 10%;align=left| GP2D15
|style="width: 10%; background: #f0f0f0" align=left| 24cm Digital (non-RoHS)
|style="width: 10%;align=left| 24cm Digital (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0D02YK0F
|style="width: 10%;align=left| GP2Y0D02YK0F
|style="width: 10%; background: #f0f0f0" align=left| 80cm Digital
|style="width: 10%;align=left| 80cm Digital
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0D02YK
|style="width: 10%;align=left| GP2Y0D02YK
|style="width: 10%; background: #f0f0f0" align=left| 80cm Digital (non-RoHS)
|style="width: 10%;align=left| 80cm Digital (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D150AJ00F
|style="width: 10%;align=left| GP2D150AJ00F
|style="width: 10%; background: #f0f0f0" align=left| 15cm Digital
|style="width: 10%;align=left| 15cm Digital
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D140A
|style="width: 10%;align=left| GP2D140A
|style="width: 10%; background: #f0f0f0" align=left| 15cm Digital (non-RoHS)
|style="width: 10%;align=left| 15cm Digital (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0A21YK0F
|style="width: 10%;align=left| GP2Y0A21YK0F
|style="width: 10%; background: #f0f0f0" align=left| 10-80cm Analog
|style="width: 10%;align=left| 10-80cm Analog
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D12
|style="width: 10%;align=left| GP2D12
|style="width: 10%; background: #f0f0f0" align=left| 10-80cm Analog (non-RoHS)
|style="width: 10%;align=left| 10-80cm Analog (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2Y0A21YK
|style="width: 10%;align=left| GP2Y0A21YK
|style="width: 10%; background: #f0f0f0" align=left| 10-80cm Analog (non-RoHS)
|style="width: 10%;align=left| 10-80cm Analog (non-RoHS)
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%;align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D120XJ00F
|style="width: 10%;align=left| GP2D120XJ00F
|style="width: 10%; background: #f0f0f0" align=left| 4-30cm Analog
|style="width: 10%;align=left| 4-30cm Analog
|-
|-
|style="width: 5%; background: #f0f0f0" align=left| Sharp
|style="width: 5%; align=left| Sharp
|style="width: 10%; background: #f0f0f0" align=left| GP2D120
|style="width: 10%;align=left| GP2D120
|style="width: 10%; background: #f0f0f0" align=left| 4-30cm Analog (non-RoHS)
|style="width: 10%;align=left| 4-30cm Analog (non-RoHS)
|-
|-
|}
|}

Latest revision as of 21:45, 11 July 2022


Getting Started

Welcome to the 1101 user guide! In order to get started, make sure you have the following hardware on hand:


Next, you will need to connect the pieces:

1101 0 Connecting The Hardware.jpg
  1. Connect the Sharp distance sensor to the 1101.
  2. Connect the 1101 to the HUB0000 using the Phidget cable.
  3. Connect the HUB0000 to your computer using the USB cable.


Now that you have everything together, let's start using the 1101!

Using the 1101

Phidget Control Panel

In order to demonstrate the functionality of the 1101, we will connect it to the HUB0000, and then run an example using the Phidget Control Panel on a Windows machine.


The Phidget Control Panel is available for use on both macOS and Windows machines. If you would like to follow along, first take a look at the getting started guide for your operating system:


Linux users can follow the getting started with Linux guide and continue reading here for more information about the 1101.

First Look

After plugging in the 1101 into the HUB0000, and the HUB0000 into your computer, open the Phidget Control Panel. You will see something like this:

HUB0000 Panel.jpg


The Phidget Control Panel will list all connected Phidgets and associated objects, as well as the following information:

  • Serial number: allows you to differentiate between similar Phidgets.
  • Channel: allows you to differentiate between similar objects on a Phidget.
  • Version number: corresponds to the firmware version your Phidget is running. If your Phidget is listed in red, your firmware is out of date. Update the firmware by double-clicking the entry.


The Phidget Control Panel can also be used to test your device. Double-clicking on an object will open an example.

Voltage Ratio Input

Double-click on a Voltage Ratio Input object in order to run the example:

1018 Sensors VoltageRatioInput.png


General information about the selected object will be displayed at the top of the window. You can also experiment with the following functionality:

  • Modify the change trigger and/or data interval value by dragging the sliders. For more information on these settings, see the data interval/change trigger page.
  • Select the 1101 from the Sensor Type drop-down menu. The example will now convert the voltage into distance (cm) automatically. Converting the voltage to distance (cm) is not specific to this example, it is handled by the Phidget libraries, with functions you have access to when you begin developing!


Technical Details

General

The function of the 1101 is to regulate the power requirement of the connected Sharp distance sensor, smoothing out current spikes that could otherwise overwhelm the device measuring them.

Make sure that the distance of the object being measured is within the distance range of the sensor. When the object is outside the valid sensor's distance range, the returned value should be discarded. You must be especially careful when the object is closer than it should be, as the returned value might be within the expected voltage range but is not meaningful. If the sensor is being used outdoors, be mindful that sunlight can cause interference, especially when the sunlight is entering at such an angle that it is within the sensor's cone of detection. The IR light from these sensors can pass through glass, but only if the glass is completely clear and the sensor is perpendicular and very close to the surface of the glass. Otherwise, too much IR light will be reflected for the sensor to work properly.

Formulas

The Phidget libraries can automatically convert sensor voltage into distance (cm) by selecting the appropriate SensorType. See the Phidget22 API for more details. These formulas are derived from the Sharp datasheets to compute distance and are only valid for the Sharp distance sensors we sell.


The formula to translate voltage ratio into Distance for Sharp 4-30cm analog sensor is:

This formula is only valid for VoltageRatio between 0.08 and 0.53.


The formula to translate voltage into Distance for Sharp 10-80cm analog sensors is:

This formula is only valid for VoltageRatio between 0.08 and 0.53.


The formula to translate voltage into Distance for Sharp 20-150cm analog sensors is:

This formula is only valid for VoltageRatio between 0.08 and 0.49.

Note: The output of this sensor will vary from unit to unit, and based on the characteristics of the target (reflectance, size, direction of motion, object alignment, etc). Our formula is based on the data provided by Sharp. If you find that you are not getting good results with the standard formulas, you may want to derive your own formula to better characterize your situation.

Compatible Infrared Sensors

The following is a list of distance sensors that are known to work with the IR Distance Adapter Board. If the product is not listed here, it can be assumed to be incompatible.


Manufacturer Part Number Description
Sharp GP2Y0A02YK0F 20-150cm Analog
Sharp GP2Y0A02YK 20-150cm Analog (non-RoHS)
Sharp GP2Y0D21YK0F 24cm Digital
Sharp GP2Y0D21YK 24cm Digital (non-RoHS)
Sharp GP2D14J0000F 24cm Digital
Sharp GP2D15 24cm Digital (non-RoHS)
Sharp GP2Y0D02YK0F 80cm Digital
Sharp GP2Y0D02YK 80cm Digital (non-RoHS)
Sharp GP2D150AJ00F 15cm Digital
Sharp GP2D140A 15cm Digital (non-RoHS)
Sharp GP2Y0A21YK0F 10-80cm Analog
Sharp GP2D12 10-80cm Analog (non-RoHS)
Sharp GP2Y0A21YK 10-80cm Analog (non-RoHS)
Sharp GP2D120XJ00F 4-30cm Analog
Sharp GP2D120 4-30cm Analog (non-RoHS)

Phidget Cable

Analoginput.jpg

The Phidget Cable is 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.

What to do Next

  • Programming Languages - Find your preferred programming language here and learn how to write your own code with Phidgets!
  • Phidget Programming Basics - Once you have set up Phidgets to work with your programming environment, we recommend you read our page on to learn the fundamentals of programming with Phidgets.