Vex Robotics Victor SPX User manual
217-9191-751
Victor SPX User Guide
vexpro.com ctr-electronics.com
Copyright 2018, VEX Robotics Inc., Cross the Road Electronics
Updated: 2021-11-29
1
Victor SPX
User Guide
217-9191-751
Victor SPX User Guide
vexpro.com ctr-electronics.com
Copyright 2018, VEX Robotics Inc., Cross the Road Electronics
Updated: 2021-11-29
2
Table of Contents
The Victor SPX at a Glance…………………………………………………………………………………………………………………………………………………..3
Installing the Victor SPX........................................................................................................................................................................... 4
Wiring the Output ........................................................................................................................................................................ 4
Wiring the Input ............................................................................................................................................................................ 4
Controlling the Victor SPX........................................................................................................................................................ 5
CAN bus ........................................................................................................................................................................................... 5
PWM ................................................................................................................................................................................................. 6
Mounting the Victor SPX .......................................................................................................................................................... 7
Strain Relief .................................................................................................................................................................................... 8
Applying Power for the First Time......................................................................................................................................... 8
Additional Information ............................................................................................................................................................................... 9
Brake & Coast Modes................................................................................................................................................................ 9
Calibration .................................................................................................................................................................................... 10
Blink Codes................................................................................................................................................................................... 11
Thermal Performance............................................................................................................................................................. 12
Frequently Asked Questions: ................................................................................................................................................ 13
Troubleshooting ......................................................................................................................................................................... 16
FCC Compliance Statement (United States) ................................................................................................................................ 19
ICES-003 Compliance Statement (Canada).................................................................................................................................. 19
Revision History......................................................................................................................................................................................... 19
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Victor SPX User Guide
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Updated: 2021-11-29
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Getting Started – Victor SPX
The Victor SPX is a speed controller designed through collaboration between VEX Robotics
(vexrobotics.com) & Cross the Road Electronics (ctr-electronics.com) that allows for fine control and high
performance of brushed DC motors in competition robotics applications. The Victor SPX handles high
current loads with minimal voltage drop and heat generation. Its linear output and Brake/Coast options allow
for precise motor control, making it well suited for all FRC motor applications from drivetrains to shooter
wheels. The plastic housing and aluminum heatsink create a lightweight motor controller – while maintaining
the full sealed, fan-less design that FRC teams expect. This, combined with a 3 sq-in. footprint, a variety of
built-in mounting options and super flexible, high strand count leads make installation a breeze.
The Victor SPX at a Glance:
Victor SPX Specs
Outside Dimensions
2.50” x 1.16” x 0.77”
[63.5mm x 29.5mm x 19.5mm]
Weight (Without Wire) 0.20 lbf [0.09 kgf]
Nominal Voltage 12 VDC
Min/Max Voltage 6-16 VDC
Continuous Current 60A
Surge Current (2 sec) 100A
PWM Input Pulse (High Time) 1 – 2 ms Nominal
PWM Input Rate (Period) 2.9 - 100ms
PWM Output Chop Rate (Switching Frequency) 15.625 kHz
PWM Logic High Min. Voltage Threshold 1 VDC
PWM Logic Low Max. Voltage Threshold 0.4 VDC
PWM Input Min. Current <1mA
Minimum Throttle (Deadband) Adjustable [0.1% - 25% (4% Default)]
Motor - (M-)
Motor + (M+)
Signal LEDs
Ground (GND)
Input Voltage (V+)
CAN wires
(Green/Yellow)
Brake / Coast / Calibration Button
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The power input & outputs of the Victor SPX are indicated by markings on the housing as well as wire color
as shown in the table below. All power input/output wires on the Victor SPX are 600 strand minimum,
12AWG copper wire.
Wire Case Marking Wire Color Wire Length
Positive Input
V+
Red
5.5in [139.7mm] ± 0.25in [6.35mm]
Input Ground
GND Black
5.5in [139.7mm] ± 0.25in [6.35mm]
Motor Positive
M+ White
5.5in [139.7mm] ± 0.25in [6.35mm]
Motor Negative
M- Green
5.5in [139.7mm] ± 0.25in [6.35mm]
CAN-High / PWM Signal None Yellow 12.0in[304.8mm] ± 0.25in [6.35mm]
CAN-Low / PWM Ground None Green 12.0in[304.8mm] ± 0.25in [6.35mm]
Installing the Victor SPX
Wiring a speed controller has never been easier than with the Victor SPX. By following a few quick steps,
your robot will be up and running in no time.
Wiring the Output
Connect the white wire to the M+ side of the motor and the green wire to the M- side of the motor using
tightly crimped connectors. If the motor’s inputs are not marked, the polarity of the input may be chosen by
the user. Be sure to connect the output wires to motors with consistent polarity so each motor will rotate
the same direction when given the same CAN bus command or PWM signal. Reversing the output wire
connections will result in the motor rotating the opposite direction when given the same CAN bus command
or PWM signal.
In many cases, the output leads of the Victor SPX will not be long enough to reach the motor it is controlling,
so an extension cable will be required. Extension cables should be made using appropriately sized wire and
connected using properly crimped connectors.
Note: For the most robust connection, it is highly recommended that all connectors are crimped and
soldered.
Wiring the Input
To power the Victor SPX, connect the positive input (red) wire to the selected
positive terminal of the Power Distribution Panel (PDP), and the input ground
(black) wire to the corresponding ground terminal. In many cases, the Victor
SPX may be wired directly to the robot’s PDP without extension cables – this
is preferable since it reduces the number of electrical connections. If the
Bat +
Bat GND
Input
GND
Input +
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robot’s design does not allow for a direct connection to the PDP, extension cables may be used.
Always keep good electrical practices in mind when designing a robot's electrical system. The Victor SPX's
source voltage should never exceed 28V. In addition, a 40A or smaller breaker should be used in series with
the Victor SPX's positive input.
WARNING:TO MAXIMIZE PERFORMANCE, THE VICTOR SPX DOES NOT INCLUDE REVERSE
POLARITY PROTECTION. IF POWER IS APPLIED BACKWARDS, THE VICTOR SPX MAY BE
PERMANENTLY DAMAGED.
Controlling the Victor SPX
The Victor SPX was intended to be a drop-in replacement for the Victor SP, allowing teams to use either
basic control over PWM – or make the jump to more advanced control over CAN bus. To make this easier
for teams, we’ve included a standard 3 pin (0.1” pitch) connector on each of the Green/Yellow twisted pairs.
One set of wires has a female connector and the other has a male connector.
CAN bus
Using the CAN bus to control the Victor SPX allows users to take full advantage of all its features. To wire the
CAN bus, connect a yellow signal wire to the CAN terminal marked “H” on the NI roboRIO and connect a
green signal wire to the CAN terminal marked “L” on the NI roboRIO.
To connect additional Victor SPXs, use tightly crimped connectors to connect the signal wires green-to-green
& yellow-to-yellow as shown below. For the best connection, it is highly recommended that each connector is
crimped and soldered. The yellow and green wires should also be wrapped in a twisted pair fashion (not
illustrated) to maximize tolerance to electrical noise.
Note: Signal wires of the same color are electrically identical – it does not matter which wire is used as long
as the color is correct.
120 Ω
Resistor
or PDP
To CAN “H”
Terminal
To CAN “L”
Terminal
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After your Victor SPXs have been wired, there will be 2 remaining signal wires – connect these two wires
using a 120 Ω resistor or to the CAN interface on the Power Distribution Panel (PDP) to properly terminate
the cable end.
PWM
Either of the Victor SPX’s built-in CAN bus wires can be used to control the device using PWM. In addition,
one set of twisted pair wires have a male PWM connector while the other has a female PWM connector.
This makes it easy to connect the Victor SPX with many PWM controllers, such as the roboRIO and several
VEX microcontrollers. The PWM signal used to control the Victor SP should be between 1-2ms in duration
with a center (neutral) pulse of 1.5ms and a period between 2.9-100ms. The PWM period is how fast the
robot controller can send a new PWM pulse. The amount of time between the rising edge of one PWM pulse
to the next PWM pulse should not be less than 2.9ms or greater than 100ms.
The pinout for the Victor SPX’s PWM cable is shown in the table below:
Wire Color
Description
Traditional PWM Wire
Color
Yellow
PWM Signal
White
Green
PWM Ground
Black
Controlling a Victor SPX with a NI roboRIO Controller:
To connect a Victor SPX to the NI roboRIO controller, simply plug the Victor SPX’s attached female PWM
connector into the desired PWM header in the roboRIO’s PWM output with the yellow (signal) wire on the
“inside” of the controller. If an extension cable is needed for the Victor SPX to reach the roboRIO, a standard
male-female 3-wire extension cable should be used – these extension cables are available from VEX Robotics
as well as many other online retailers.
Female 3-pin plug
required for NI roboRIO
Standard Male 3-pin
Extension Cable
Standard female 3-pin
Extension Cable
Male 3-pin plug required
for some control systems
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Controlling a Victor SPX with a VEX Microcontroller:
The Victor SPX is compatible with the following VEX microcontrollers:
VEX
V5 Robot Brain
VEX
ARM®
Cortex®
-
based Microcontroller
VEX PIC Microcontroller V0.5
VEXpro ARM9 Microcontroller
To connect a Victor SPX with any of the above VEX microcontrollers, simply plug the Victor SPX’s male PWM
connector into the desired motor port on the microcontroller with the white (signal) wire on the “inside” of
the microcontroller.
If an extension cable is needed for the Victor SPX to reach one of these microcontrollers, a standard male-
female 3-wire extension cable should be used – these extension cables are available from VEX Robotics as
well as many other online retailers.
Note: The Victor SPX’s default calibration profile is configured for use with the roboRIO. To reconfigure it for
use with a VEX microcontroller, follow the directions in the Calibration section.
Mounting the Victor SPX
The Victor SPX can be mounted using either (2X) #8-32 screws or zip-ties. The Victor SPX’s aluminum and
plastic case is electrically isolated from the electronics, meaning it is safe to mount directly to a robot’s
frame!
The Victor SPX’s mounting location should be chosen to allow for adequate air flow around the housing and
sides of the case. Any Victor SPXs that are used for low-current applications may be stacked as shown
below, but Victor SPXs used for high current applications, such as drivetrains, should be mounted individually.
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For maximum heat dissipation, it is recommended that the Victor SPX be securely mounted to a robot’s
metal frame – this allows the robot to be used as a giant heatsink to aid in cooling.
CAUTION:IN RARE CIRCUMSTANCES, THE VICTOR SPX MAY BECOME HOT DURING
USE. USE CAUTION AROUND ANY VICTOR SPX THAT HAS RECENTLY BEEN USED,
ESPECIALLY ONES USED FOR HIGH CURRENT APPLICATIONS. IF PROTECTED BY A
40A BREAKER, THE VICTOR SPX MAY BECOME HOT BUT WILL NOT BECOME HOT
ENOUGH TO DAMAGE ITSELF.
Strain Relief
An important yet frequently forgotten aspect of wiring is strain relief. All electrical connections should be
isolated from any pulling or tugging that may result in a poor connection. Once the Victor SPX is fully wired,
zip ties should be used to ensure that all electrical connections are protected.
Note: When zip-tying wires down, it is crucial to avoid sharp edges on the robot. Wires that are anchored to
sharp edges can become worn over time and cause a short.
Applying Power for the First Time
Before applying power for the first time, it is a good idea to double check the following:
The red wire is connected to the positive source
The black wire is connected to the source ground
All electrical connections are secure and electrically isolated
A 40A or smaller breaker is in series with the Victor SPX’s positive power input
There are no short circuits on the Victor SPX’s output
The CAN cable is correctly oriented (i.e. yellow to yellow for CAN bus & yellow to white for PWM)
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Additional Information
Brake & Coast Modes
The Victor SPX has two modes: Brake and Coast. When a neutral signal is applied to the Victor SPX in Brake
mode, the motor will resist rotation, especially high-speed rotation. This is accomplished by essentially
shorting the motor leads, which causes a Back Electromotive Force (Back-EMF) to resist the rotation of the
motor. Brake mode does not have any effect when the motor is not rotating, but can make a large difference
in robot behavior when used on a motor attached to a high reduction gearbox. Brake mode does not impact
performance when a non-neutral signal is applied.
When a neutral signal is applied to the Victor SPX in Coast mode, Back-EMF will not be generated, so the
motor’s rotation will not be affected by the Victor SPX.
Switching between Brake & Coast:
To switch between Brake and Coast mode, simply push the B/C CAL button at any time. The Victor SPX is in
Brake mode when the button is illuminated red and Coast when the red light is turned off. Brake/Coast
settings are saved even if power is removed from the Victor SPX.
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Calibration
The calibration of a Victor SPX is essentially the scale of input signal to output voltage. Different controllers
may have different “max” and “min” signals that may not correspond to the same Victor SPX outputs.
Calibrating the Victor SPX allows it to adjust for these differences so that a “max” signal results in a “max”
output. Calibrating can also correct issues caused by joysticks or gamepads with off-center neutral outputs.
The Victor SPX’s default calibration is compatible with the roboRIO control system.
To Calibrate the Victor SPX:
1) Press and hold the B/C CAL button until the Status LEDs begin to rapidly blink red & green.
2) While holding the button, move the joystick (or other input signal) to full forward then to full
reverse. This can be done multiple times. The Victor SPX is looking for max & min PWM values
during this step, so ensure that the joystick reaches its full max and full min.
3) Release the joystick and allow it to return to neutral. After the joystick is in the neutral position,
release the B/C CAL button.
4) If the Victor SPX was calibrated properly, the status LEDs will blink green several times.
If the calibration failed, the status LEDs will blink red and the previous calibration will be kept.
Note: Calibration profiles are saved even if power is removed from the Victor SPX.
To Restore Default Calibration:
1) Remove power from the Victor SPX
2) Hold down the B/C CAL button
3) While holding down the button, restore power to the Victor SPX
4) Continue holding the button until the status LEDs blink green, then release the button
Status LEDs
B/C CAL Button
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Blink Codes
Blink Codes During Calibration
Status LEDs Blink Code
Victor SPX State
Flashing Red/Green
Calibration Mode
Blinking Green
Successful Calibration
Blinking Red
Failed Calibration
Blink Codes During Normal Operation
LEDs
Colors
Victor SPX State
Both Blinking Green
Forward throttle is applied. Blink rate is
proportional to Duty Cycle
Both Blinking Red
Reverse throttle is applied. Blink rate is
proportional to Duty Cycle
None
None
No Power is being applied to Talon SRX
LEDs Alternate1
Off/Orange
CAN Bus detected, robot disabled
LEDs Alternate1
Off/Slow Red
CAN/PWM is not detected
LEDs Alternate1
Off/Fast Red
Fault Detected
LEDs Alternate1
Red / Orange
Damaged Hardware
LEDs Strobe “towards” (M+)2Off/ Red
Forward Limit Switch or Forward Soft
Limit
LEDs Strobe “towards” (M-)
2
Off/ Red
Reverse Limit Switch or Reverse Soft Limit
LED1 Only
Green / Orange
In Bootloader
B/C CAL Button Blink Codes
B/C CAL Button Color
Victor SPX State
Solid Red
Brake Mode
Off
Coast Mode
1) LEDs alternate – Status LEDs are different colors at all times. The (2X) LEDs will swap colors when
blinking.
2) (1X) Status LED will blink followed shortly by the other with a long pause before repeating. The
“direction” of the blink indicates the Talon SRX’s current state.
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Thermal Performance
To evaluate the Victor SPX’s thermal performance, a 40A load was applied using CIM motors and a
dynamometer. Before the test, a thermocouple was attached to the top of the Victor SPX PCBA. The test
was run for 15 minutes at 50% duty cycle. After the motor controller returned to room temperature, the
test was re-run at 100% duty cycle. During both tests, temperature data was recorded at regular intervals.
The results are plotted below.
Note: Running a motor controller at 50% duty cycle causes the transistors to switch at a higher frequency.
This switching is what produces the most heat.
0
20
40
60
80
100
120
140
160
180
200
220
0 1.5 3 4.5 6 7.5 9 10.5 12 13.5 15
Temperature (F)
Time (Minutes)
Max Temp vs. Time
(40A Continuous Load)
Victor SPX @ 50% Duty Cycle
VIctor SP @ 50% Duty Cycle
Victor SPX @ 100% Duty Cycle
Victor SP @ 100% Duty Cycle
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Frequently Asked Questions:
Q: Is it possible to use more than one type of speed controller?
A: Yes, it is completely safe and acceptable to use multiple types of speed controllers on a single
robot.
Q: Is it safe to mount a Victor SPX directly to a robot’s metal frame?
A: It is not only safe, it’s recommended. The electronics inside the Victor SPX are in a plastic housing,
with a layer of insulation between the electronics and the aluminum heatsink. Mounting a Victor SPX
to a robot’s frame allows the robot to be used as a giant heatsink that will help keep the Victor SPX
cool.
Q: Does the Victor SPX require a fan?
A: The Victor SPX does not require a fan for typical FRC use, but if the robot is being used for practice
or many back to back matches it is a good idea to use a fan to cool the Victor SPX.
Q: What kind of electrical connectors should I use to connect wires to the Victor SPX?
A: The choice of electrical connectors is left to the user. Electrical connectors used with the Victor
SPX should be designed for use with 12AWG wire and tightly crimped. For the best electrical
connection, it is highly recommended that wire connectors are soldered to the wire they are crimped
on.
Q: Can the Victor SPX be used with control systems other than the NI roboRIO?
A: Yes, the Victor SPX may be used with any control system that is capable of PWM output or CAN
bus.
Q: There isn’t a wire connected to the center (red) PWM wire on the .1” servo connector, is this a
problem?
A: No. The center (red) PWM wire is typically +5V that can be used to power PWM devices. The
Victor SPX is powered by the 12V input and does not require PWM power.
Q: What CAN bus topologies are recommended?
A: The Victor SPX is intended to be used in the daisy chain fashion. Additionally, FRC Teams should
always confirm what is considered “legal” per latest FRC competition rules.
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Alternatively, the CAN bus may be wired in the fashion commonly
seen in the automotive industry, where a single harness is made
(with proper termination resistor at each of the two ends). Each
module can “tap” into the primary bus harness (crimp, connector,
soldered, etc.) with a cable stub (maximum length of one foot).
In the automotive industry, this is accomplished
with a cable design that has the cable stubs
designed in with end-connectors at various places
in the cable.
As documented in the DW CAN bus specification, both daisy chain or a designed master cable
harness meets the specification’s documented topology (diagram below).
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Star topology is not recommended. This use case is not common, nor is it suggested in the DW
CAN bus specification. This nonstandard implementation requires careful study and analysis of
the candidate bus cable, which is typically beyond the capabilities of a typical FRC team.
This topology may be used when performing basic testing on a bench-setup with a small network
(few modules and short cable travel). However, this use case should not be construed as
evidence guaranteeing that star topology is a robust solution. Star topology is not a robust
general solution to be relied on for critical applications.
Ring topology is not recommended. This use case is not common, nor is it suggested in the DW
CAN bus specification. This nonstandard implementation requires careful study and analysis of
the candidate bus cable, which is typically beyond the capabilities of a typical FRC team.
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Troubleshooting
Indication: No ORANGE Status LEDs on power up.
Problem: Input power issue or joystick trim tab off center.
Possible Solutions:
1. Disconnect CAN cable(s).
2. If Status LEDs remains off, check +V or GND connections for voltage and proper polarity.
3. If Status LEDs blink ORANGE, the speed controller is probably damaged. The final test to
determine if the Victor SPX is damaged to to replace it with another Victor SPX that is known
to function properly.
CAUTION:PRIOR TO REPLACING A POTENTIALLY DAMAGED SPEED
CONTROLLER, ENSURE THAT THE WIRES CONNECTED TO THE OUTPUT
ARE NOT SHORTED AND THE INPUT IS NOT REVERSED. ALSO, VERIFY
THAT NEITHER OF THE VICTOR SPX’S MOTOR OUTPUT LEADS ARE
SHORTED TO THE CHASSIS OF THE MOTOR OR THE ROBOT.
Indication: Flashing ORANGE Status LEDs on power up.
Problem: No CAN/PWM signal.
Possible Solutions:
1. Ensure the transmitter and receiver are powered ON.
2. The CAN/PWM cable may be improperly connected. Check wire color-coding at each end. Check
that the connector is not offset by a pin at the receiver end.
3. If using PWM, check for a good PWM signal by connecting a known good servo to the PWM
cable. If the servo does not move, this can indicate either:
a. A faulty microcontroller
b. An improperly connected cable
c. A bad PWM cable
Note: The servo requires that voltage be present on the center pin of the PWM cable. This
connection is not required for the Victor SPX.
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Indication: Flashing RED Status LEDs after calibration.
Problem: Calibration Failed.
Possible Solutions:
1. Inadequate travel in either the forward or reverse direction. Repeat the calibration procedure
and move the joystick further forward and/or further reverse.
2. The joystick trim is not centered. Neutral cannot be extremely far from center.
Indication: No power output from the speed controller although the Status LEDs work.
Problem: Possible internal damage.
Possible Solutions:
If the Status LEDs on the Victor SPX are operating properly and there is no output, the Victor SPX
may be internally damaged. This condition is typically caused by a short circuit on the output or there
has been an over-current condition that caused a failure.
Check the following:
1. Ensure the Status LEDs are changing between ORANGE, RED, and GREEN with joystick
movement.
2. Disconnect the motor and check the output (M+ to M-) with a voltmeter. The meter should
read between +/- battery voltage with corresponding full range joystick movement. If the
Status LEDs are working properly and the outputs are not working properly, the speed
controller is probably damaged. The final test to determine if the Victor SPX is damaged is to
replace it with another Victor SPX that is known to function properly.
CAUTION:PRIOR TO REPLACING A POTENTIALLY DAMAGED SPEED
CONTROLLER, ENSURE THAT THE WIRES CONNECTED TO THE OUTPUT
ARE NOT SHORTED AND THE INPUT IS NOT REVERSED. ALSO, VERIFY
THAT NEITHER OF THE VICTOR SPX’S MOTOR OUTPUT LEADS ARE
SHORTED TO THE CHASSIS OF THE MOTOR OR THE ROBOT.
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Indication: No power output from the speed controller and the Status LEDs do NOT work.
Problem: No input power or possible internal damage.
Possible Solutions:
If the Status LEDs on the Victor SPX are not operating properly and there is no output, the Victor SPX
may be internally damaged. This condition is typically caused by no input power or a reversed polarity
on the input.
Check the following:
1. Disconnect the output wires.
2. Ensure the Status LEDs on the Victor SPX do not illuminate at any joystick position.
3. Check the input at the Victor SPX (+BATTERY to GND) with a voltmeter. If the Status LEDs
are not working properly and the input is good, the speed controller is probably damaged.
The final test to determine if the Victor SPX is damaged is to replace it with another Victor
SPX that is known to function properly.
CAUTION: PRIOR TO REPLACING A POTENTIALLY DAMAGED SPEED
CONTROLLER, ENSURE THAT THE WIRES CONNECTED TO THE OUTPUT
ARE NOT SHORTED AND THE INPUT IS NOT REVERSED. ALSO, VERIFY
THAT NEITHER OF THE VICTOR SPX’S MOTOR OUTPUT LEADS ARE
SHORTED TO THE CHASSIS OF THE MOTOR OR THE ROBOT.
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FCC Compliance Statement (United States):
This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions:
(1) This device may not cause harmful interference, and
(2) this device must accept any interference received, including interference that may cause
undesired operation.
Changes or modifications not expressly approved by the party responsible for compliance could void the
user’s authority to operate the equipment.
Note: This equipment has been tested and found to comply with the limits for a Class B digital device,
pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against
harmful interference in a residential installation. This equipment generates, uses and can radiate radio
frequency energy and, if not installed and used in accordance with the instructions, may cause harmful
interference to radio communications. However, there is no guarantee that interference will not occur in a
particular installation. If this equipment does cause harmful interference to radio or television reception,
which can be determined by turning the equipment off and on, the user is encouraged to try to correct the
interference by one or more of the following measures:
– Reorient or relocate the receiving antenna.
– Increase the separation between the equipment and receiver.
– Connect the equipment into an outlet on a circuit different from that to which the receiver is
connected.
– Consult the dealer or an experienced radio/TV technician for help.
ICES-003 Compliance Statement (Canada):
This Class B digital apparatus complies with Canadian ICES-003.
Cet appareil numérique de la classe B est conforme à la norme NMB-003 du Canada.
Revision History:
2018/05/31 – Initial Public Release
2021/11/29 – Added PWM voltage and current info
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