Applying Encoders

There are several variables to consider when choosing an encoder. The most common are:

• Style of encoder. What kind of encoder does the application call for? A shaft model, thru-bore, or blind hollow bore?
• Resolution. For incremental encoders, resolution is defined as cycles per revolution (CPR). For absolute encoders, resolution is the number of bits that define the position count for an absolute encoder turn; e.g., 12 bits or 212 is a resolution of 4096. Single-turn resolution refers to number of counts for positions in one 360-degree turn; multi-turn resolution is the total number of full revolutions possible (turns of 360 degrees) that may be measured before resetting to zero.
• Output type. Encoders offer a variety of different output types. Choosing the correct one means considering the number of output channels and the receiving device. See the white paper Selecting Digital Encoder Outputs for more information.
• Frequency response, or the maximum frequency of the output signal in Hertz.
• Accuracy, which is the difference between the theoretical position of one increment or bit edge and the actual position of the edge.
• Electrical connections.
• Environmental conditions. Specifically, encoders must withstand a range of conditions such as moisture and dust that can seep into internal optics and electronics. Sealed encoders are available to address this. For more information on sealing options on encoders, see technical bulletin TB-106: Sealing Options for EPC Encoders.

There are also encoders available that address other environmental conditions, including exposure to corrosive and caustic chemicals and ambient temperatures that reach up to 120° C. For more information, refer to the white paper, Encoders in Inhospitable Environments.

Examples of typical encoders. From left to right: Size 25 shaft encoder, 58 mm thru-bore encoder, 1.5 inch blind hollow-bore encoder.

Common Interfacing Issues

Designers must identify an encoder resolution that reflects the system’s true needs. Resolution that is too high can increase costs and raise frequencies above the encoder or receiver’s capabilities. Also, higher resolution doesn’t necessarily translate into higher system accuracy. On the other hand, resolution that’s too low may limit the system’s ability to control speed or position accurately. Additionally, incremental encoders with quadrature phasing not only provide directional information, but can increase resolution up to four times when combined with a compatible receiving device.

A system’s receiving device (controller) generally dictates encoder output. Thus, designers should first determine the controller’s input requirements, and then select a compatible encoder output driver. For more information, refer to our white paper Selecting Digital Encoder Outputs.

Three basic types of controllers exist:

• Drivers that supply current to external devices (sourcing)
• Drivers that provide a current path to the circuit ground or common (sink)
• Drivers that do both (line drivers)

Many controllers accept differential line-driver signals, canceling common-mode noise while accommodating long encoder cable runs.