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The IR Distance Adapter is designed to interface Sharp IR distance sensors to an Analog Input or VINT Hub Port. Any Sharp sensor with a supply voltage of 5V and an output voltage range falling within 0-5V is compatible with this adapter. The cable included with this adapter uses a JST S3B-PH connector, like the Sharp sensors sold by Phidgets Inc. If your Sharp sensor uses a different connector, you'll need to find a matching cable for it.
The 1101 is capable of adapting one Sharp distance sensor so that it can be used with Phidgets. Below is a list of Sharp sensors that we sell. This adapter can also be used for other Sharp sensors not sold here; see the technical section of the User Guide tab for a complete list.
|Image||Part Number||Price||Measurement Distance Min||Measurement Distance Max|
|3520_0||$14.00||40 mm||300 mm|
|3521_0||$12.00||100 mm||800 mm|
|3522_0||$16.00||200 mm||1.5 m|
This sensor can be read by any Phidget with an Analog Input or VINT Hub port. It will connect to either one using the included Phidget cable. VINT Hub ports can behave just like Analog Inputs, but have the added flexibility of being able to be used as digital inputs, digital outputs, or ports to communicate with VINT devices. For more information about VINT, see the VINT Primer.
|Image||Part Number||Price||Number of Voltage Inputs||Voltage Input Resolution|
|HUB0000_0||$30.00||6 (Shared)||* 16 bit|
|HUB5000_0||$60.00||6 (Shared)||* 16 bit|
|SBC3003_0||$120.00||6 (Shared)||* 16 bit|
This sensor comes with its own Phidget cable to connect it to an InterfaceKit or Hub, but if you need extras we have a full list down below. You can solder multiple cables together in order to make even longer Phidget cables, but you should be aware of the effects of having long wires in your system.
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:
Now that you have everything together, let's start using the 1101!
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.
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:
The Phidget Control Panel will list all connected Phidgets and associated objects, as well as the following information:
The Phidget Control Panel can also be used to test your device. Double-clicking on an object will open an example.
Double-click on a Voltage Ratio Input object in order to run the example:
General information about the selected object will be displayed at the top of the window. You can also experiment with the following functionality:
The function of the 1101 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 the HUB0000 (or compatible product), then it may potentially experience an overload.
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.
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:
The formula to translate voltage into Distance for Sharp 10-80cm analog sensors is:
The formula to translate voltage into Distance for Sharp 20-150cm analog sensors is:
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.
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.
|Sharp||GP2Y0A02YK||20-150cm Analog (non-RoHS)|
|Sharp||GP2Y0D21YK||24cm Digital (non-RoHS)|
|Sharp||GP2D15||24cm Digital (non-RoHS)|
|Sharp||GP2Y0D02YK||80cm Digital (non-RoHS)|
|Sharp||GP2D140A||15cm Digital (non-RoHS)|
|Sharp||GP2D12||10-80cm Analog (non-RoHS)|
|Sharp||GP2Y0A21YK||10-80cm Analog (non-RoHS)|
|Sharp||GP2D120||4-30cm Analog (non-RoHS)|
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.
|Sensor Output Type||Ratiometric|
|Controlled By||VoltageRatio Input|
|Supply Voltage Min||4.8 V DC|
|Supply Voltage Max||5.3 V DC|
|Current Consumption Max||3 mA|
|Output Impedance||1 kΩ|
|Operating Temperature Min||-25 °C|
|Operating Temperature Max||85 °C|
|Date||Board Revision||Device Version||Comment|
|October 2005||0||N/A||Product Release|
|May 2008||0A||N/A||Redesign due to component obsolescence|
This device doesn't have an API of its own. It is controlled by opening a VoltageRatioInput channel on the Phidget that it's connected to. For a list of compatible Phidgets with VoltageRatio Inputs, see the Connection & Compatibility tab.
You can find details for the VoltageRatioInput API on the API tab for the Phidget that this adapter connects to.