Difference between revisions of "Encoders"

(Sensor Overview)
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We have a few preferred methods for tracking and reading encoder values.
 
We have a few preferred methods for tracking and reading encoder values.
 
===Roboteq Motor Controller===
 
===Roboteq Motor Controller===
Roboteq motor controllers include built-in functionality to connect directly with the encoder A and B quadrature signals, detect pulses, and maintain a count of the number of pulses observed. Roboteqs can use the measured encoder data to perform [[Speed Control|Closed Loop Speed Control]].
+
Roboteq motor controllers include built-in functionality to connect directly with the encoder A and B quadrature signals, detect pulses, and maintain a count of the number of pulses observed. Roboteqs can use the measured encoder data to perform [[Speed Control#Closed Loop|Closed Loop Speed Control]].
  
 
===Roboclaw Motor Controller===
 
===Roboclaw Motor Controller===
Roboclaw motor controllers are able to connect directly to the encoder quadrature signals and keep track of the number of pulses observed. Roboclaws can use the measured encoder data to perform [[Speed Control|Closed Loop Speed Control]].
+
Roboclaw motor controllers are able to connect directly to the encoder quadrature signals and keep track of the number of pulses observed. Roboclaws can use the measured encoder data to perform [[Speed Control#Closed Loop|Closed Loop Speed Control]].
  
 
===Quadrature Encoder Buffer Board===
 
===Quadrature Encoder Buffer Board===
 
This board is always an option when the robot's motor controller does not support encoder reading. This device uses the LS3766R chip and connects directly to the encoders, maintains a count of the encoder pulses, and provides a SPI interface to read the counts from a microcontroller. We sell this board in 1-, 2-, 3-, and 4-channel variants. The board provides optional pullup resistors for the encoder A and B signals so no additional circuitry is required.
 
This board is always an option when the robot's motor controller does not support encoder reading. This device uses the LS3766R chip and connects directly to the encoders, maintains a count of the encoder pulses, and provides a SPI interface to read the counts from a microcontroller. We sell this board in 1-, 2-, 3-, and 4-channel variants. The board provides optional pullup resistors for the encoder A and B signals so no additional circuitry is required.
  
[##ITEM2397## Single LS7366R Quadrature Encoder Buffer (TE-183-001)]
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<sdr item id=2397>Single LS7366R Encoder Buffer Board (TE-183-001)</sdr item>
  
[##ITEM1523## Dual LS7366R Quadrature Encoder Buffer (TE-183-002)]
+
<sdr item id=1523>Dual LS7366R Encoder Buffer Board (TE-083-002)</sdr item>
  
[##ITEM1523## Triple LS7366R Quadrature Encoder Buffer (TE-183-003)]
+
<sdr item id=2398>Triple LS7366R Encoder Buffer Board (TE-183-003)</sdr item>
 +
 
 +
<sdr item id=2418>Quadruple LS7366R Encoder Buffer Board (TE-183-004)</sdr item>
  
[##ITEM1523## Quadruple LS7366R Quadrature Encoder Buffer (TE-183-004)]
 
<br />
 
 
==Quick Links to our Encoders and Accessories:==
 
==Quick Links to our Encoders and Accessories:==
 
'''Encoder Buffer and Pull-up Boards:'''
 
'''Encoder Buffer and Pull-up Boards:'''

Revision as of 14:29, 8 January 2021

Rotary encoders are devices that generate electrical pulses as they rotate. The angle or rate of rotation that the encoder is experiencing can be measured by monitoring the number or frequency of the pulses. In robotics, encoders are most commonly attached to the robot's drive motors and used to measure the robot's linear speed, angular speed, and distance traveled. More generally, encoders can be attached to any of the robot's joints to track its speed and/or angle, such as a rotating joint in a robotic arm.

Sensor Overview

Measurement: Motor rotation distance. When attached to the drive motors, can be used to generate position and heading estimates. In most practical applications encoders are best used to track linear and angular velocities instead.

Ideal operating conditions: Robot operating on smooth/even ground where wheels maintain constant rolling contact with no slip.

Sensor Pros:

  • Quite accurate over short time periods/distances
  • Works indoors and outdoors, day or night
  • Good for mitigating discrete jumps in position and orientation estimates when fused with other sensors
  • Great fallback sensor when things go wrong
  • Can be used for Closed Loop Speed Control of the wheels

Sensor Cons:

  • Requires initial calibration between encoder counts and amount of robot movement
  • Assumes no slip between robot wheel and ground. An unstable or inconsistent surface beneath the robot can lead to wheel slippage. Skid-steer robots also experience wheel slippage while turning. This causes error in the estimated robot speed and position because the wheel moves but the robot doesn’t.
  • Position errors from wheel slippage and imperfect calibration accumulate over time/distance to give a progressively worse position estimate. *When used to measure speed instead of position this is less of an issue.
  • Additional hardware is often needed to keep track of the encoder counts. However, some motor controllers (such as Roboteq models) have this functionality built-in.

Encoder Output

Encoders typically output what is known as a quadrature signal. A quadrature signal is comprised of two channels (Channel A and Channel B). Channel B is 90 degrees out of phase from channel A. This allows the circuitry watching the output signal to know what direction you are traveling. If B trails A then your motor is moving clockwise, if A trails B then your motor is moving counter clockwise.

Picture

Reading Encoders

We have a few preferred methods for tracking and reading encoder values.

Roboteq Motor Controller

Roboteq motor controllers include built-in functionality to connect directly with the encoder A and B quadrature signals, detect pulses, and maintain a count of the number of pulses observed. Roboteqs can use the measured encoder data to perform Closed Loop Speed Control.

Roboclaw Motor Controller

Roboclaw motor controllers are able to connect directly to the encoder quadrature signals and keep track of the number of pulses observed. Roboclaws can use the measured encoder data to perform Closed Loop Speed Control.

Quadrature Encoder Buffer Board

This board is always an option when the robot's motor controller does not support encoder reading. This device uses the LS3766R chip and connects directly to the encoders, maintains a count of the encoder pulses, and provides a SPI interface to read the counts from a microcontroller. We sell this board in 1-, 2-, 3-, and 4-channel variants. The board provides optional pullup resistors for the encoder A and B signals so no additional circuitry is required.

Single LS7366R Encoder Buffer Board (TE-183-001)

Dual LS7366R Encoder Buffer Board (TE-083-002)

Triple LS7366R Encoder Buffer Board (TE-183-003)

Quadruple LS7366R Encoder Buffer Board (TE-183-004)

Quick Links to our Encoders and Accessories:

Encoder Buffer and Pull-up Boards:

  • [##ITEM1523## Dual LS7366R Quadrature Encoder Buffer Breakout Board (TE-183-002)]
  • [##ITEM1514## Kangaroo x2 motion controller (TE-180-000)]
  • [##ITEM1512## IG32, IG42, and IG52 Gear Motor Encoder Pull-up Board (TE-179-000)]

Motors with Encoders:

  • [##ITEM1238## IG42 24VDC 013 RPM Gear Motor with Encoder (TD-044-013)]
  • [##ITEM1181## IG52-04 24VDC 082 RPM Gear Motor with Encoder (TD-045-082)]
  • [##ITEM1134## IG32P 24VDC 075 RPM Gear Motor with Encoder (TD-055-075)]
  • [##ITEM1099## IG32 24VDC 074 RPM Gear Motor with Encoder (TD-054-074)]
  • [##ITEM1036## IG42 24VDC 078 RPM Gear Motor with Encoder (TD-044-078)]
  • [##ITEM998## IG32P 24VDC 265 RPM Gear Motor with Encoder (TD-055-265)]
  • [##ITEM997## IG32P 24VDC 190 RPM Gear Motor with Encoder (TD-055-190)]
  • [##ITEM996## IG32 24VDC 191 RPM Gear Motor with Encoder (TD-054-191)]
  • [##ITEM937## IG52-04 24VDC 010 RPM Gear Motor with Encoder (TD-045-010)]
  • [##ITEM873## IG52-04 24VDC 136 RPM Gear Motor with Encoder (TD-045-136)]
  • [##ITEM849## IG42 24VDC 122 RPM Gear Motor with Encoder (TD-044-122)]
  • [##ITEM843## IG52-04 24VDC 285 RPM Gear Motor with Encoder (TD-045-285)]
  • [##ITEM840## IG42 24VDC 240 RPM Gear Motor with Encoder (TD-044-240)]

Motor Controllers with direct encoder feedback:

  • [##ITEM1197## SyRen 50A Regenerative Motor Driver (TE-098-150)] with [##ITEM1514## Kangaroo Option]
  • [##ITEM1169## RoboteQ SDC2150 - 2x20A 50V Motor Controller with Encoder Input (TE-144-050)]
  • [##ITEM1168## RoboteQ SDC2130 - 2x20A 30V Motor Controller with Encoder Input (TE-144-030)]
  • [##ITEM2233## RoboteQ XDC2460 - 2x150A 60V Motor Controller with Encoder Input (TE-286-150)]
  • [##ITEM1834## RoboteQ MDC2460 - 2x60A 60V Motor Controller with Encoder Input (TE-240-060)]
  • [##ITEM1833## RoboteQ MDC2230 - 2x60A 30V Motor Controller with Encoder Input (TE-240-030)]
  • [##ITEM848## SyRen 25A Regenerative Motor Driver (TE-098-125)] with [##ITEM1514## Kangaroo Option]
  • [##ITEM847## SyRen 10A Regenerative Motor Driver (TE-098-110)] with [##ITEM1514## Kangaroo Option]
  • [##ITEM822## Sabertooth Dual 25A Motor Driver (TE-091-225)] with [##ITEM1514## Kangaroo Option]
  • [##ITEM1225## Sabertooth Dual 60A motor driver (TE-091-260)] with [##ITEM1514## Kangaroo Option]

Encoder support: