Now that we have an estimate for our target position let's see if we can refine it to be more precise using similar methods to what we covered during the Drivetrain Encoders section.
Recall, that ticks per revolution of the encoder shaft is different than the ticks per revolution of the shaft that is controlling a mechanism, such as what we determined on our Drivetrain.
For more information on the effect of motion transmission across a mechanism check out the Compound Gearing section.
The amount of ticks per revolution of the encoder shaft is dependent on the motor and encoder. Manufacturers of motors with built-in encoders will have information on the amount of ticks per revolution.
Visit the manufacturers website for your motor or encoders for more information on encoder counts. For HD Hex Motors or Core Hex Motors visit the Motor documentation.
In the Core Hex Motor specifications there are two different Encoder Counts per Revolution numbers:
At the motor - 4 counts/revolution
At the output - 288 counts/revolution
At the motor is the number of encoder counts on the shaft that encoder is on. This number is equivalent to the 28 counts per revolution we used for the HD Hex Motor.
The 288 counts "at the output" accounts for the change in resolution after the motion is transmitted from the motor to the built in 72:1 gearbox.
Lets use the 288 as ticks per revolution so that we do not have to account for the gearbox in our total gear reduction variable.
Since we built the the gear reduction from the motor gearbox into the ticks per revolution the main focus of this section is calculating the gear reduction of the arm joint.
The motor shaft drives a 45 tooth gear that transmits motion to a 125 tooth gear. The total gear ratio is 125T:45T. To calculate the gear reduction for this gear train, we can simply divide 125 by 45.
To summarize, for the Class Bot V2 the following information is true:
Ticks per revolution
288 ticks
Total gear reduction
2.777778
Now that we have this information lets create two constant variables:
COUNTS_PER_MOTOR_REV
GEAR_REDUCTION
Add the variables COUNTS_PER_MOTOR_REV
and GEAR_REDUCTION
variables to the initialization section of the program.
Our COUNTS_PER_MOTOR_REV
and GEAR_REDUCTION
variables will be set to a value that will then be used to calculate our other two variables COUNTS_PER_DEGREE
and COUNTS_PER_GEAR_REV
.
Let's go ahead and add these variables to our OpMode.
Now that these two variables have been defined, we can use them to calculate two other variables: the amount of encoder counts per rotation of the 125T driven gear and the number of counts per degree moved.
Calculating counts per revolution of the 125T gear (or COUNTS_PER_GEAR_REV
) is the same formula we used for COUNTS_PER_WHEEL_REV
variable on our drivetrain, so to get this variable we can multiple COUNTS_PER_MOTOR_REV
by GEAR_REDUCTION
.
To calculate the number of COUNTS_PER_DEGREE
divide the COUNTS_PER_GEAR_REV
variable by 360.
All together our variables will look like below:
We need to create one more non-constant variable that will act as our position. This will be called armPosition
.
To get to the 90 degree position, the arm needs to move roughly 45 degrees therefore set arm position equal to COUNTS_PER_DEGREE
times 45.
Save your OpMode and give it a test!
Once the variables are created and in place, use the blocks to set the first variables to the respective values
Add this variable to the section of the statement, as this section dictates the 90 degree position. Add the block to the block.