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7 Commits
b9e91a14ab ... main

Author SHA1 Message Date
Alvie Rahman
f580f77cf2 add zip recipe to makefile 2023-12-06 15:38:26 +00:00
Alvie Rahman
6d16857453 copy lab_2 code to src folders 2023-12-06 15:38:01 +00:00
Alvie Rahman
7799bbf6ea add screenshots of program output 2023-12-06 15:33:09 +00:00
Alvie Rahman
1059a7f791 expand q2, fix formatting 2023-12-06 15:20:58 +00:00
Alvie Rahman
d18f125995 first draft of submission 2023-12-04 17:56:13 +00:00
Alvie Rahman
d68eb0fa95 update gitignore 2023-12-04 17:55:41 +00:00
Alvie Rahman
e188f0f2f4 update c mac steppers to take args and remove windows.h 2023-12-04 17:54:36 +00:00
19 changed files with 2397 additions and 59 deletions
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1
.gitignore vendored
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@@ -1 +1,2 @@
out
plots

5
Makefile
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@@ -20,6 +20,11 @@ $(SUBMISSION_FILENAME): .PHONY $(OUT_DIR)
$(TEX) $(SRC_DIR)/submission.md -o $(OUT_DIR)/$@ $(TEX_FLAGS)
mv mermaid-filter.err $(OUT_DIR)
zip: .PHONY $(OUT_DIR)
rm -rf $(OUT_DIR)/lab_2_submission_akbar_alvi_rahman_20386125.zip
zip -j $(OUT_DIR)/lab_2_submission_akbar_alvi_rahman_20386125 $(OUT_DIR)/*.pdf
zip -r $(OUT_DIR)/lab_2_submission_akbar_alvi_rahman_20386125 images csv src/lab_2
$(OUT_DIR):
mkdir -p $(OUT_DIR)

51
csv/LeibRampStepper_out_50.csv Normal file
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@@ -0,0 +1,51 @@
Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)
0.000, 4.583, 21.000, 1, 218.218
0.189, 5.304, 3.828, 2, 188.528
0.347, 6.359, 6.711, 3, 157.245
0.480, 7.531, 8.822, 4, 132.785
0.596, 8.653, 9.711, 5, 115.565
0.700, 9.688, 10.023, 6, 103.223
0.794, 10.640, 10.135, 7, 93.982
0.881, 11.523, 10.175, 8, 86.781
0.962, 12.348, 10.186, 9, 80.984
1.039, 13.124, 10.185, 10, 76.195
1.112, 13.859, 10.180, 11, 72.157
1.181, 14.558, 10.172, 12, 68.693
1.247, 15.225, 10.164, 13, 65.681
1.311, 15.865, 10.156, 14, 63.031
1.372, 16.481, 10.148, 15, 60.676
1.431, 17.075, 10.141, 16, 58.566
1.488, 17.649, 10.134, 17, 56.660
1.543, 18.205, 10.128, 18, 54.929
1.597, 18.745, 10.122, 19, 53.346
1.649, 19.270, 10.117, 20, 51.893
1.700, 19.782, 10.112, 21, 50.552
1.751, 19.782, 0.000, 22, 50.552
1.802, 19.782, 0.000, 23, 50.552
1.853, 19.782, 0.000, 24, 50.552
1.904, 19.782, 0.000, 25, 50.552
1.955, 19.782, 0.000, 26, 50.552
2.006, 19.782, 0.000, 27, 50.552
2.057, 19.782, 0.000, 28, 50.552
2.108, 19.782, 0.000, 29, 50.552
2.159, 19.782, 0.000, 30, 50.552
2.210, 19.782, 0.000, 31, 50.552
2.262, 19.270, -9.853, 32, 51.894
2.316, 18.745, -9.845, 33, 53.347
2.371, 18.205, -9.835, 34, 54.930
2.428, 17.648, -9.823, 35, 56.663
2.487, 17.074, -9.810, 36, 58.570
2.548, 16.479, -9.795, 37, 60.682
2.612, 15.863, -9.778, 38, 63.040
2.678, 15.222, -9.757, 39, 65.695
2.747, 14.553, -9.732, 40, 68.714
2.820, 13.853, -9.702, 41, 72.188
2.897, 13.116, -9.665, 42, 76.244
2.979, 12.336, -9.618, 43, 81.062
3.066, 11.506, -9.556, 44, 86.914
3.161, 10.613, -9.473, 45, 94.224
3.265, 9.643, -9.355, 46, 103.703
3.382, 8.572, -9.178, 47, 116.655
3.518, 7.365, -8.889, 48, 135.770
3.686, 5.962, -8.365, 49, 167.717
3.905, 4.583, -6.323, 50, 218.218
1 Time (s) Speed (steps/s) Accel (steps/s^2) Posit'n (steps) Step time (ticks)
2 0.000 4.583 21.000 1 218.218
3 0.189 5.304 3.828 2 188.528
4 0.347 6.359 6.711 3 157.245
5 0.480 7.531 8.822 4 132.785
6 0.596 8.653 9.711 5 115.565
7 0.700 9.688 10.023 6 103.223
8 0.794 10.640 10.135 7 93.982
9 0.881 11.523 10.175 8 86.781
10 0.962 12.348 10.186 9 80.984
11 1.039 13.124 10.185 10 76.195
12 1.112 13.859 10.180 11 72.157
13 1.181 14.558 10.172 12 68.693
14 1.247 15.225 10.164 13 65.681
15 1.311 15.865 10.156 14 63.031
16 1.372 16.481 10.148 15 60.676
17 1.431 17.075 10.141 16 58.566
18 1.488 17.649 10.134 17 56.660
19 1.543 18.205 10.128 18 54.929
20 1.597 18.745 10.122 19 53.346
21 1.649 19.270 10.117 20 51.893
22 1.700 19.782 10.112 21 50.552
23 1.751 19.782 0.000 22 50.552
24 1.802 19.782 0.000 23 50.552
25 1.853 19.782 0.000 24 50.552
26 1.904 19.782 0.000 25 50.552
27 1.955 19.782 0.000 26 50.552
28 2.006 19.782 0.000 27 50.552
29 2.057 19.782 0.000 28 50.552
30 2.108 19.782 0.000 29 50.552
31 2.159 19.782 0.000 30 50.552
32 2.210 19.782 0.000 31 50.552
33 2.262 19.270 -9.853 32 51.894
34 2.316 18.745 -9.845 33 53.347
35 2.371 18.205 -9.835 34 54.930
36 2.428 17.648 -9.823 35 56.663
37 2.487 17.074 -9.810 36 58.570
38 2.548 16.479 -9.795 37 60.682
39 2.612 15.863 -9.778 38 63.040
40 2.678 15.222 -9.757 39 65.695
41 2.747 14.553 -9.732 40 68.714
42 2.820 13.853 -9.702 41 72.188
43 2.897 13.116 -9.665 42 76.244
44 2.979 12.336 -9.618 43 81.062
45 3.066 11.506 -9.556 44 86.914
46 3.161 10.613 -9.473 45 94.224
47 3.265 9.643 -9.355 46 103.703
48 3.382 8.572 -9.178 47 116.655
49 3.518 7.365 -8.889 48 135.770
50 3.686 5.962 -8.365 49 167.717
51 3.905 4.583 -6.323 50 218.218

51
csv/SimplisticRampStepper_out_50.csv Normal file
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Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)
0.000, 1.000, 1.000, 1, 1000.000
0.953, 1.050, 0.052, 2, 952.500
1.858, 1.105, 0.061, 3, 905.000
2.716, 1.166, 0.071, 4, 857.500
3.526, 1.235, 0.084, 5, 810.000
4.289, 1.311, 0.101, 6, 762.500
5.004, 1.399, 0.122, 7, 715.000
5.672, 1.498, 0.149, 8, 667.500
6.292, 1.613, 0.185, 9, 620.000
6.865, 1.747, 0.234, 10, 572.500
7.390, 1.905, 0.301, 11, 525.000
7.868, 2.094, 0.397, 12, 477.500
8.298, 2.326, 0.538, 13, 430.000
8.681, 2.614, 0.755, 14, 382.500
9.016, 2.985, 1.107, 15, 335.000
9.304, 3.478, 1.715, 16, 287.500
9.544, 4.167, 2.868, 17, 240.000
9.737, 5.195, 5.341, 18, 192.500
9.882, 6.897, 11.736, 19, 145.000
9.980, 10.256, 34.460, 20, 97.500
10.030, 20.000, 194.872, 21, 50.000
10.080, 20.000, 0.000, 22, 50.000
10.130, 20.000, 0.000, 23, 50.000
10.180, 20.000, 0.000, 24, 50.000
10.230, 20.000, 0.000, 25, 50.000
10.280, 20.000, 0.000, 26, 50.000
10.330, 20.000, 0.000, 27, 50.000
10.380, 20.000, 0.000, 28, 50.000
10.430, 20.000, 0.000, 29, 50.000
10.480, 20.000, 0.000, 30, 50.000
10.578, 10.256, -99.934, 31, 97.500
10.723, 6.897, -23.171, 32, 145.000
10.916, 5.195, -8.840, 33, 192.500
11.156, 4.167, -4.284, 34, 240.000
11.444, 3.478, -2.394, 35, 287.500
11.779, 2.985, -1.472, 36, 335.000
12.162, 2.614, -0.969, 37, 382.500
12.592, 2.326, -0.672, 38, 430.000
13.070, 2.094, -0.484, 39, 477.500
13.595, 1.905, -0.361, 40, 525.000
14.168, 1.747, -0.276, 41, 572.500
14.788, 1.613, -0.216, 42, 620.000
15.456, 1.498, -0.172, 43, 667.500
16.171, 1.399, -0.139, 44, 715.000
16.934, 1.311, -0.114, 45, 762.500
17.744, 1.235, -0.095, 46, 810.000
18.602, 1.166, -0.080, 47, 857.500
19.507, 1.105, -0.068, 48, 905.000
20.460, 1.050, -0.058, 49, 952.500
21.460, 1.000, -0.050, 50, 1000.000
1 Time (s) Speed (steps/s) Accel (steps/s^2) Posit'n (steps) Step time (ticks)
2 0.000 1.000 1.000 1 1000.000
3 0.953 1.050 0.052 2 952.500
4 1.858 1.105 0.061 3 905.000
5 2.716 1.166 0.071 4 857.500
6 3.526 1.235 0.084 5 810.000
7 4.289 1.311 0.101 6 762.500
8 5.004 1.399 0.122 7 715.000
9 5.672 1.498 0.149 8 667.500
10 6.292 1.613 0.185 9 620.000
11 6.865 1.747 0.234 10 572.500
12 7.390 1.905 0.301 11 525.000
13 7.868 2.094 0.397 12 477.500
14 8.298 2.326 0.538 13 430.000
15 8.681 2.614 0.755 14 382.500
16 9.016 2.985 1.107 15 335.000
17 9.304 3.478 1.715 16 287.500
18 9.544 4.167 2.868 17 240.000
19 9.737 5.195 5.341 18 192.500
20 9.882 6.897 11.736 19 145.000
21 9.980 10.256 34.460 20 97.500
22 10.030 20.000 194.872 21 50.000
23 10.080 20.000 0.000 22 50.000
24 10.130 20.000 0.000 23 50.000
25 10.180 20.000 0.000 24 50.000
26 10.230 20.000 0.000 25 50.000
27 10.280 20.000 0.000 26 50.000
28 10.330 20.000 0.000 27 50.000
29 10.380 20.000 0.000 28 50.000
30 10.430 20.000 0.000 29 50.000
31 10.480 20.000 0.000 30 50.000
32 10.578 10.256 -99.934 31 97.500
33 10.723 6.897 -23.171 32 145.000
34 10.916 5.195 -8.840 33 192.500
35 11.156 4.167 -4.284 34 240.000
36 11.444 3.478 -2.394 35 287.500
37 11.779 2.985 -1.472 36 335.000
38 12.162 2.614 -0.969 37 382.500
39 12.592 2.326 -0.672 38 430.000
40 13.070 2.094 -0.484 39 477.500
41 13.595 1.905 -0.361 40 525.000
42 14.168 1.747 -0.276 41 572.500
43 14.788 1.613 -0.216 42 620.000
44 15.456 1.498 -0.172 43 667.500
45 16.171 1.399 -0.139 44 715.000
46 16.934 1.311 -0.114 45 762.500
47 17.744 1.235 -0.095 46 810.000
48 18.602 1.166 -0.080 47 857.500
49 19.507 1.105 -0.068 48 905.000
50 20.460 1.050 -0.058 49 952.500
51 21.460 1.000 -0.050 50 1000.000

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82
res/lab_2/LeibRampStepperMac.c
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@@ -1,7 +1,6 @@
// Leib Ramp Stepper program with millis function adapted for MacOS
#include <stdio.h>
#include <stdlib.h>
#include <windows.h>
#include <math.h>
#include <time.h>
@@ -52,57 +51,52 @@ const float minSpeed = 1.0;
const float maxPermissSpeed = 20.0;
const float maxAccel = 10.0;
int main()
int main(int argc, char *argv[1])
{
unsigned long currentMillis = millis();
prevStepTime = 0;
long positionToMoveTo;
while(true)
sscanf(argv[1], "%ld", &positionToMoveTo);
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
goToPosition(positionToMoveTo);
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
// STEP 1
// Define number of steps in acceleration phase using Equation (3)
accelSteps = (long)(( maxPermissSpeed * maxPermissSpeed - minSpeed * minSpeed) / ( 2.0 * (float)maxAccel)); // Equation 4 but need to consider initial speed
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
printf("Enter position to move to in profile (or 999 to terminate)\n");
scanf("%ld", &positionToMoveTo);
if (positionToMoveTo==999) break;
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
// STEP 2
// Define maximum speed in profile and number of steps in acceleration phase
// Use Equations (4) and (5)
maxSpeed = sqrt(minSpeed * minSpeed + stepsToGo * maxAccel); // Modified version of eq. 5
accelSteps = (long)(stepsToGo / 2);
}
goToPosition(positionToMoveTo);
// STEPS 3 and 5
// Calculate initial value of and p1 and R Set p = p1
p1 = (float)ticksPerSec / sqrt( minSpeed * minSpeed + 2 * maxAccel); // Eq 17 incorporating initial velocity
p = p1;
R = (float) maxAccel / ((float)ticksPerSec * (float)ticksPerSec); // Eq 19
ps = ((float)ticksPerSec) / maxSpeed; // STEP 4 Eq 7 in paper
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
// STEP 1
// Define number of steps in acceleration phase using Equation (3)
accelSteps = (long)(( maxPermissSpeed * maxPermissSpeed - minSpeed * minSpeed) / ( 2.0 * (float)maxAccel)); // Equation 4 but need to consider initial speed
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping, and associated coding */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
// STEP 2
// Define maximum speed in profile and number of steps in acceleration phase
// Use Equations (4) and (5)
maxSpeed = sqrt(minSpeed * minSpeed + stepsToGo * maxAccel); // Modified version of eq. 5
accelSteps = (long)(stepsToGo / 2);
}
// STEPS 3 and 5
// Calculate initial value of and p1 and R Set p = p1
p1 = (float)ticksPerSec / sqrt( minSpeed * minSpeed + 2 * maxAccel); // Eq 17 incorporating initial velocity
p = p1;
R = (float) maxAccel / ((float)ticksPerSec * (float)ticksPerSec); // Eq 19
ps = ((float)ticksPerSec) / maxSpeed; // STEP 4 Eq 7 in paper
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping, and associated coding */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
}
return 0;

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res/lab_2/SimplisticRampStepperMac.c Normal file
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// Simplistic Ramp Stepper program with millis function adapted for MacOS
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
/* Only needed in Windows program to maintain compatibility with Arduino version of C/C++ */
typedef enum { false, true } bool;
#define true 1
#define false 0
const bool FWDS = true;
const bool BWDS = false;
const long ticksPerSec = 1000; // ms on PC
// on Arduino it is 1E6 for micros (for s/w) or 1.6E7 for 62.5 ns ticks (for h/w)
void moveOneStep();
void computeNewSpeed();
long computeStepsToGo();
void goToPosition(long newPosition);
long millis(void);
/* Note: we are using global variables ONLY to preserve compatibility with the Arduino program structure.
They should not normally be used in C or C++ programs as they make for a poor software design. */
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
float maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
/* Global variables used in simplistic and Leib Ramp algorithms */
volatile float p; /* Step interval in clock ticks or microseconds */
float ps; /* Maximum step periods */
float deltaP; /* You'll be able to get rid of this later */
/* Global variable used for noting previous time of a step in timed loop and for calculating speed and accel */
long prevStepTime=0;
long millisAtStart;
float prevSpeed=0.0;
/* Define permissible parameters for motor */
// For testing on PC only, not for use in Arduino program: try movements in order of 50-100 steps
float accelSteps=20; /* leave this as a variable as we may over-write it */
const float minSpeed = 1.0; // in steps/s
const float maxPermissSpeed = 20.0; // in steps/s
const float maxAccel = 10.0; // in steps/s^2
int main(int argc, char *argv[])
{
unsigned long currentMillis = millis();
prevStepTime = 0;
long positionToMoveTo;
sscanf(argv[1], "%ld", &positionToMoveTo);
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
goToPosition(positionToMoveTo);
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
float maxInterval = ((float)ticksPerSec) / minSpeed;
ps = ((float)ticksPerSec) / maxPermissSpeed;
deltaP = (maxInterval - ps) / accelSteps;
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
accelSteps = (long)(stepsToGo / 2);
}
p = maxInterval;
ps = ((float)ticksPerSec) / maxSpeed;
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
}
return 0;
}
/* Only needed for compatibility with Arduino program because millis() is not a native MacOS function */
long millis(void)
{
struct timespec _t;
clock_gettime(CLOCK_REALTIME, &_t);
return _t.tv_sec*1000 + lround(_t.tv_nsec/1e6);
}
/* Move a single step. If this were running on the Arduino we would holding pulse high for delayMicroSeconds */
void moveOneStep()
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
// Print to screen instead of making a step
if (direction == FWDS)
{
currentPosition++;
}
else
{
currentPosition--;
}
/* Instead of actually making step, print out parameters for current step */
float speed = (float)(ticksPerSec)/p;
float accel = (float)(ticksPerSec)*(speed-prevSpeed)/p;
printf("%16.3f, %16.3f, %16.3f, %16ld, %16.3f\n", 0.001*(millis()-millisAtStart), speed, accel, currentPosition, p);
prevSpeed = speed;
}
}
/* Calcuate new value of step interval p based on constants defined in timed loop */
void computeNewSpeed()
{
stepsToGo = computeStepsToGo();
/* Start of on-the-fly step calculation code, executed once per step */
if (stepsToGo == 0)
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo >= accelSteps && (long)p > (long)ps) // Changed to make ramps even length
/* Speeding up */
{
p -= deltaP;
}
else if (stepsToGo <= accelSteps)
/* Slowing down */
{
p += deltaP;
}
/* else p is unchanged: running at constant speed */
/* End of on-the-fly step calculation code */
}
/* Work out how far the stepper motor still needs to move */
long computeStepsToGo()
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
/* Set the target position and determine direction of intended movement */
void goToPosition(long newPosition)
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}

204
src/lab_2/LeibRampStepper.c Normal file
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@@ -0,0 +1,204 @@
#include <stdio.h>
#include <stdlib.h>
#include <windows.h>
#include <math.h>
/* Only needed in Windows program to maintain compatibility with Arduino version of C/C++ */
#define bool BOOL
#define true 1
#define false 0
const bool FWDS = true;
const bool BWDS = false;
const long ticksPerSec = 1000; // ms on PC
// on Arduino it is 1E6 for micros (for s/w) or 1.6E7 for 62.5 ns ticks (for h/w)
/* Function prototypes: */
/* PC only, don't need function prototypes on Arduino as they get added within compilation process */
void moveOneStep();
void computeNewSpeed();
long computeStepsToGo();
void goToPosition(long newPosition);
void printLoop();
long millis(void);
/* Note: we are using global variables ONLY to preserve compatibility with the Arduino program structure.
They should not normally be used in C or C++ programs as they make for a poor software design. */
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
float maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
/* Global variables used in simplistic and Leib Ramp algorithms */
volatile float p; /* Step interval in clock ticks or microseconds */
float p1, ps; /* Minimum and maximum step periods */
float deltaP; /* You'll be able to get rid of this later */
float R; /* Multiplying constant used in Eiderman's algorithm */
/* Global variable used for noting previous time of a step in timed loop and for calculating speed and accel */
long prevStepTime=0;
long millisAtStart;
float prevSpeed=0.0;
/* Define permissible parameters for motor */
// For testing on PC only, not for use in Arduino program: try movements in order of 50-100 steps
float accelSteps=20; /* leave this as a variable as we may over-write it */
const float minSpeed = 1.0;
const float maxPermissSpeed = 20.0;
const float maxAccel = 10.0;
int main()
{
unsigned long currentMillis = millis();
prevStepTime = 0;
long positionToMoveTo;
while(true)
{
printf("Enter position to move to in profile (or 999 to terminate)\n");
scanf("%ld", &positionToMoveTo);
if (positionToMoveTo==999) break;
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
goToPosition(positionToMoveTo);
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
// STEP 1
// Define number of steps in acceleration phase using Equation (3)
accelSteps = (long)(( maxPermissSpeed * maxPermissSpeed - minSpeed * minSpeed) / ( 2.0 * (float)maxAccel)); // Equation 4 but need to consider initial speed
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
// STEP 2
// Define maximum speed in profile and number of steps in acceleration phase
// Use Equations (4) and (5)
maxSpeed = sqrt(minSpeed * minSpeed + stepsToGo * maxAccel); // Modified version of eq. 5
accelSteps = (long)(stepsToGo / 2);
}
// STEPS 3 and 5
// Calculate initial value of and p1 and R Set p = p1
p1 = (float)ticksPerSec / sqrt( minSpeed * minSpeed + 2 * maxAccel); // Eq 17 incorporating initial velocity
p = p1;
R = (float) maxAccel / ((float)ticksPerSec * (float)ticksPerSec); // Eq 19
ps = ((float)ticksPerSec) / maxSpeed; // STEP 4 Eq 7 in paper
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping, and associated coding */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
}
}
return 0;
}
/* Only needed for compatibility with Arduino program because millis() is not a native Windows API function */
long millis(void)
{
return GetTickCount();
}
/* Move a single step. */
void moveOneStep()
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
// Print to screen instead of making a step
if (direction == FWDS)
{
currentPosition++;
}
else
{
currentPosition--;
}
/* Instead of actually making step, print out parameters for current step */
float speed = (float)(ticksPerSec)/p;
float accel = (float)(ticksPerSec)*(speed-prevSpeed)/p;
printf("%16.3f, %16.3f, %16.3f, %16ld, %16.3f\n", 0.001*(millis()-millisAtStart), speed, accel, currentPosition, p);
prevSpeed = speed;
}
}
/* Calcuate new value of step interval p based on constants defined in loop() */
void computeNewSpeed()
{
float q;
float m;
stepsToGo = computeStepsToGo();
/* ----------------------------------------------------------------- */
/* Start of on-the-fly step calculation code, executed once per step */
if (stepsToGo == 0) // STEP 6a
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo >= accelSteps && (long)p > (long)ps) // Speeding up
{
m = -R; // Equation (9)
}
else if (stepsToGo <= accelSteps) // Slowing down
{
m = R; // Equation 10
}
else // Running at constant speed
{
m = 0; // Equation (11)
}
/* else p is unchanged: running at constant speed */
/* Update to step interval based on Eiderman's algorithm, using temporary variables */
// STEP 6b, c and d using Equations (12) and (13)
q = m * p * p; // this is a part of optional enhancement
p = p * ( 1 + q + 1.5 * q * q); // this is an enhanced approximation -equation [22]
/* Need to ensure rounding error does not cause drift outside acceptable interval range:
replace p with relevant bound if it strays outside */
if (p > p1)
{
p = p1;
}
/* End of on-the-fly step calculation code */
/* ----------------------------------------------------------------- */
}
/* Work out how far the stepper motor still needs to move */
long computeStepsToGo()
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
/* Set the target position and determine direction of intended movement */
void goToPosition(long newPosition)
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}

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src/lab_2/LeibRampStepper/LeibRampStepper.ino Normal file
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/* Stepper motor demonstration program written by Arthur Jones,
4 November 2018. Implements a simplistic and ineffective ramping
algorithm but provides framework for implementation of LeibRamp
algorithm described by Aryeh Eiderman, http://hwml.com/LeibRamp.pdf
Makes use of background work and some aspects of code developed
by Choaran Wang, 2017-18. This in turn incorporates some ideas
used in the AccelStepper library:
https://www.airspayce.com/mikem/arduino/AccelStepper/
Serial input aspects are based closely upon:
http://forum.arduino.cc/index.php?topic=396450
Example 4 - Receive a number as text and convert it to an int
Modified to read a long */
const int stepPin = 13;
const int dirPin = 9;
const bool FWDS = true;
const bool BWDS = false;
const long ticksPerSec = 1000000; // microseconds in this case
/* Define permissible parameters for motor */
// For testing by watching LED: try movements in order of 100 steps
//float accelSteps=20; /* leave this as a variable as we may over-write it */
//const float minSpeed = 2.0;
//const float maxPermissSpeed = 20.0;
//const float maxAccel = 10.0;
//const long stepLengthMus = 10000;
// For lab testing with real motor: try movements in the order of 3000 steps
float accelSteps=1000; /* leave this as a variable as we may over-write it */
const float minSpeed=10.0;
const float maxPermissSpeed=100000000.0;
const float maxAccel=500.0;
const long stepLengthMus=100;
/* Intervals in milliseconds for user-defined timed loops */
const long printInterval = 1000;
/* Global variables used for loop timing */
unsigned long prevMillisPrint = 0; /* stores last time values were printed */
/* Global variables used in serial input */
enum {numChars = 32};
char receivedChars[numChars]; /* an array to store the received data */
long dataNumber = 0; /* Value read from serial monitor input */
boolean newData = false;
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
double maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
volatile float p; /* Step interval in clock ticks or microseconds */
float p1, ps; /* Minimum and maximum step periods */
double deltaP; /* You'll be able to get rid of this later */
double R; /* Multiplying constant used in Eiderman's algorithm */
/* Global variable used for noting previous time of a step in timed loop */
long prevStepTime;
void setup()
{
long stepsToGo = 0;
currentPosition = 0;
goToPosition(dataNumber);
pinMode(stepPin, OUTPUT);
pinMode(dirPin, OUTPUT);
Serial.begin(9600);
Serial.println("Enter target position in number of steps and hit return");
prevStepTime = micros();
}
void loop()
{
unsigned long currentMillis = millis();
unsigned long currentMicros;
recvWithEndMarker();
stepsToGo = computeStepsToGo();
if (convertNewNumber())
{
Serial.print("Converted number: datanumber is: ");
Serial.println(dataNumber);
// Only get to this stage if there was new data to convert
if (stepsToGo <= 0)
{
// Only get to this stage if not busy, otherwise will have thrown away input
goToPosition(dataNumber);
Serial.print("Got target position: ");
Serial.println(targetPosition);
/* Define number of steps in acceleration phase using Equation (3) */
accelSteps = long(( maxPermissSpeed * maxPermissSpeed) / ( 2.0 * (double)maxAccel)); // Equation 4 but need to consider initial speed
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
// Define maximum speed in profile and number of steps in acceleration phase
maxSpeed = sqrt(minSpeed * minSpeed + stepsToGo * maxAccel); // Modified version of eq. 5
accelSteps = (long)(stepsToGo / 2);
}
ps = ((double)ticksPerSec) / maxSpeed; // Eq 7
p1 = (double)ticksPerSec / sqrt( minSpeed * minSpeed + 2 * maxAccel); // Eq 17 but need initial velocity
p = p1;
R = (double) maxAccel / ((double)ticksPerSec * (double)ticksPerSec); // Eq 19
}
}
/* Timed loop for stepping */
currentMicros = micros();
if (currentMicros - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMicros;
computeNewSpeed();
}
/* Timed loop for printing */
if (currentMillis - prevMillisPrint >= printInterval)
{
// save the last time you printed output
prevMillisPrint = currentMillis;
printLoop();
}
}
/* Move a single step, holding pulse high for delayMicroSeconds */
void moveOneStep()
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
digitalWrite(stepPin, HIGH);
if (direction == FWDS)
{
/* Is something missing here? */
digitalWrite(dirPin, HIGH);
currentPosition++;
}
else
{
/* Is something missing here? */
digitalWrite(dirPin, LOW);
currentPosition--;
}
delayMicroseconds(stepLengthMus);
digitalWrite(stepPin, LOW);
}
}
/* Calcuate new value of step interval p based on constants defined in loop() */
void computeNewSpeed()
{
double q;
double m;
stepsToGo = computeStepsToGo();
/* ----------------------------------------------------------------- */
/* Start of on-the-fly step calculation code, executed once per step */
if (stepsToGo == 0)
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo > accelSteps && (long)p > long(ps)) //Speeding up
{
m = -R; // definition following equation 20
}
else if (stepsToGo <= accelSteps) // Slowing down
{
m = R;
}
else // Running at constant speed
{
m = 0;
}
/* Update to step interval based on Eiderman's algorithm, using temporary variables */
q = m * p * p; // this is a part of optional enhancement
p = p * ( 1 + q + 1.5 * q * q); // this is an enhanced approximation -equation [22]
/* Need to ensure rounding error does not cause drift outside acceptable interval range:
replace p with relevant bound if it strays outside */
if (p < ps)
{
p = ps;
}
if (p > p1)
{
p = p1;
}
/* End of on-the-fly step calculation code */
/* ----------------------------------------------------------------- */
}
/* Work out how far the stepper motor still needs to move */
long computeStepsToGo()
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
/* Set the target position and determine direction of intended movement */
void goToPosition(long newPosition)
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}
/* Receive data from serial port finishing with "newline" character.
Based on http://forum.arduino.cc/index.php?topic=396450 Example 4 */
void recvWithEndMarker()
{
static byte ndx = 0;
char endMarker = '\n';
char rc;
if (Serial.available() > 0)
{
rc = Serial.read();
if (rc != endMarker)
{
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars)
{
ndx = numChars - 1;
}
}
else
{
receivedChars[ndx] = '\0'; // terminate the string
ndx = 0;
newData = true;
}
}
}
bool convertNewNumber()
/* Converts character string to long integer only if there are new
data to convert, otherwise returns false */
{
if (newData)
{
dataNumber = 0.0;
dataNumber = atol(receivedChars);
newData = false;
Serial.println(dataNumber);
return true;
}
else
{
return false;
}
}
/* Print current position of stepper using timed loop */
void printLoop()
{
/* Sample all counters one after the other to avoid delay-related offsets */
Serial.print("Current position = ");
Serial.print(currentPosition);
Serial.print("\r\n");
Serial.print("p = ");
Serial.print(p);
Serial.print("\r\n");
}

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// Leib Ramp Stepper program with millis function adapted for MacOS
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
/* Only needed in Windows program to maintain compatibility with Arduino version of C/C++ */
typedef enum { false, true } bool;
#define true 1
#define false 0
const bool FWDS = true;
const bool BWDS = false;
const long ticksPerSec = 1000; // ms on PC
// on Arduino it is 1E6 for micros (for s/w) or 1.6E7 for 62.5 ns ticks (for h/w)
/* Function prototypes: */
/* PC only, don't need function prototypes on Arduino as they get added within compilation process */
void moveOneStep();
void computeNewSpeed();
long computeStepsToGo();
void goToPosition(long newPosition);
void printLoop();
long millis(void);
/* Note: we are using global variables ONLY to preserve compatibility with the Arduino program structure.
They should not normally be used in C or C++ programs as they make for a poor software design. */
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
float maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
/* Global variables used in simplistic and Leib Ramp algorithms */
volatile float p; /* Step interval in clock ticks or microseconds */
float p1, ps; /* Minimum and maximum step periods */
float deltaP; /* You'll be able to get rid of this later */
float R; /* Multiplying constant used in Eiderman's algorithm */
/* Global variable used for noting previous time of a step in timed loop and for calculating speed and accel */
long prevStepTime=0;
long millisAtStart;
float prevSpeed=0.0;
/* Define permissible parameters for motor */
// For testing on PC only, not for use in Arduino program: try movements in order of 50-100 steps
float accelSteps=20; /* leave this as a variable as we may over-write it */
const float minSpeed = 1.0;
const float maxPermissSpeed = 20.0;
const float maxAccel = 10.0;
int main(int argc, char *argv[1])
{
unsigned long currentMillis = millis();
prevStepTime = 0;
long positionToMoveTo;
sscanf(argv[1], "%ld", &positionToMoveTo);
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
goToPosition(positionToMoveTo);
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
// STEP 1
// Define number of steps in acceleration phase using Equation (3)
accelSteps = (long)(( maxPermissSpeed * maxPermissSpeed - minSpeed * minSpeed) / ( 2.0 * (float)maxAccel)); // Equation 4 but need to consider initial speed
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
// STEP 2
// Define maximum speed in profile and number of steps in acceleration phase
// Use Equations (4) and (5)
maxSpeed = sqrt(minSpeed * minSpeed + stepsToGo * maxAccel); // Modified version of eq. 5
accelSteps = (long)(stepsToGo / 2);
}
// STEPS 3 and 5
// Calculate initial value of and p1 and R Set p = p1
p1 = (float)ticksPerSec / sqrt( minSpeed * minSpeed + 2 * maxAccel); // Eq 17 incorporating initial velocity
p = p1;
R = (float) maxAccel / ((float)ticksPerSec * (float)ticksPerSec); // Eq 19
ps = ((float)ticksPerSec) / maxSpeed; // STEP 4 Eq 7 in paper
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping, and associated coding */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
}
return 0;
}
/* Only needed for compatibility with Arduino program because millis() is not a native MacOS function */
long millis(void)
{
struct timespec _t;
clock_gettime(CLOCK_REALTIME, &_t);
return _t.tv_sec*1000 + lround(_t.tv_nsec/1e6);
}
/* Move a single step. */
void moveOneStep()
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
// Print to screen instead of making a step
if (direction == FWDS)
{
currentPosition++;
}
else
{
currentPosition--;
}
/* Instead of actually making step, print out parameters for current step */
float speed = (float)(ticksPerSec)/p;
float accel = (float)(ticksPerSec)*(speed-prevSpeed)/p;
printf("%16.3f, %16.3f, %16.3f, %16ld, %16.3f\n", 0.001*(millis()-millisAtStart), speed, accel, currentPosition, p);
prevSpeed = speed;
}
}
/* Calcuate new value of step interval p based on constants defined in loop() */
void computeNewSpeed()
{
float q;
float m;
stepsToGo = computeStepsToGo();
/* ----------------------------------------------------------------- */
/* Start of on-the-fly step calculation code, executed once per step */
if (stepsToGo == 0) // STEP 6a
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo >= accelSteps && (long)p > (long)ps) // Speeding up
{
m = -R; // Equation (9)
}
else if (stepsToGo <= accelSteps) // Slowing down
{
m = R; // Equation 10
}
else // Running at constant speed
{
m = 0; // Equation (11)
}
/* else p is unchanged: running at constant speed */
/* Update to step interval based on Eiderman's algorithm, using temporary variables */
// STEP 6b, c and d using Equations (12) and (13)
q = m * p * p; // this is a part of optional enhancement
p = p * ( 1 + q + 1.5 * q * q); // this is an enhanced approximation -equation [22]
/* Need to ensure rounding error does not cause drift outside acceptable interval range:
replace p with relevant bound if it strays outside */
if (p > p1)
{
p = p1;
}
/* End of on-the-fly step calculation code */
/* ----------------------------------------------------------------- */
}
/* Work out how far the stepper motor still needs to move */
long computeStepsToGo()
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
/* Set the target position and determine direction of intended movement */
void goToPosition(long newPosition)
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}

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/* Example of driving servomotor using PID closed loop control */
#include <SPI.h> /* Needed to communicate with LS7366R (Counter Click) */
#include <PID_v1.h>
/* Serial input aspects are based closely upon:
http://forum.arduino.cc/index.php?topic=396450
Example 4 - Receive a number as text and convert it to an int
Modified to read a float */
/* LS7366R aspects very loosely based on concepts used in controlling
the Robogaia 3-axis encoder shield though implementation is very different
https://www.robogaia.com/3-axis-encoder-conter-arduino-shield.html */
/* Pins used for L298 driver */
const int enA = 13; /* PWM output, also visible as LED */
const int in1 = 8; /* H bridge selection input 1 */
const int in2 = 9; /* H bridge selection input 2 */
const float minPercent = -100.0;
const float maxPercent = 100.0;
/* Used to to initiate SPI communication to LS7366R chip (Counter click) */
const int chipSelectPin = 10;
/* Size of buffer used to store received characters */
enum {numChars = 32};
/* Intervals in milliseconds for user-defined timed loops */
const int printInterval = 1000;
const int controlInterval = 20;
/* Global variables used in serial input */
char receivedChars[numChars]; // an array to store the received data
float dataNumber = 0;
boolean newData = false;
/* Global variables used for motor control and encoder reading */
double percentSpeed = 0;
double encoderPosnMeasured = 0;
double positionSetPoint = 0;
/* PID */
double Kp = 0.1;
double Ki = 0.1;
double Kd = 0.05;
PID myPID(&encoderPosnMeasured, &percentSpeed, &positionSetPoint, Kp, Ki, Kd, DIRECT);
/* Global variables used for loop timing */
unsigned long prevMillisPrint = 0; /* stores last time values were printed */
unsigned long prevMillisControl = 0;
/* Overlapping regions of memory used to convert four bytes to a long integer */
union fourBytesToLong
{
long result;
unsigned char bytes [4];
};
void setup()
{
Serial.begin(9600);
Serial.print("Kp"); Serial.print(Kp);
Serial.print("Ki"); Serial.print(Ki);
Serial.print("Kd"); Serial.println(Kd);
Serial.println("Enter desired motor position: ");
/* Set up and initialise pin used for selecting LS7366R counter: hi=inactive */
pinMode(chipSelectPin, OUTPUT);
digitalWrite(chipSelectPin, HIGH);
SetUpLS7366RCounter();
delay(100);
/* Configure control pins for L298 H bridge */
pinMode(enA, OUTPUT);
pinMode(in1, OUTPUT);
pinMode(in2, OUTPUT);
/* Set initial rotation direction */
digitalWrite(in1, LOW);
digitalWrite(in2, HIGH);
delay(100);
positionSetPoint = 0;
encoderPosnMeasured=readEncoderCountFromLS7366R();
myPID.SetOutputLimits(-100,100);
myPID.SetMode(AUTOMATIC);
}
void loop()
{
unsigned long currentMillis = millis();
// Call control loop at frequency controInterval
if (currentMillis - prevMillisControl >= controlInterval) {
// save the last time the control loop was called
prevMillisControl = currentMillis;
controlLoop();
}
// Call print loop at frequency of printInterval
if (currentMillis - prevMillisPrint >= printInterval) {
// save the last time you printed output
prevMillisPrint = currentMillis;
printLoop();
}
recvWithEndMarker();// Update value read from serial line
// If a valid number has been read this is set to the current required position
if(convertNewNumber()){
positionSetPoint=dataNumber;
}
}
void controlLoop()
{
// Get the current position from the encoder
encoderPosnMeasured=readEncoderCountFromLS7366R(); // Get current motor position
myPID.Compute(); // Use the PID library to compute new value for motor input
driveMotorPercent(percentSpeed); // Send value to motor
}
void driveMotorPercent(double percentSpeed)
/* Output PWM and H bridge signals based on positive or negative duty cycle % */
{
percentSpeed = constrain(percentSpeed, -100, 100);
int regVal = map(percentSpeed, -100, 100, -255, 255);
analogWrite(enA, (int)abs(regVal)); // Write value to speed control pin
digitalWrite(in1, regVal>0); // Set the value of direction control pins to true or false
digitalWrite(in2, !(regVal>0));
}
void printLoop()
/* Print count and control information */
{
double error;
Serial.print("Actual position: ");
Serial.print(encoderPosnMeasured);
Serial.print("\t");
Serial.print("Desired position: ");
Serial.print(positionSetPoint);
Serial.print("\t");
error = positionSetPoint - encoderPosnMeasured;
Serial.print("Error: ");
Serial.print(error);
Serial.print("\t");
// Serial.print(percentSpeed);
Serial.print("\r\n");
}
long readEncoderCountFromLS7366R()
/* Reads the LS7366R chip to obtain up/down count from encoder. Reads four
bytes separately then concverts them to a long integer using a union */
{
fourBytesToLong converter; /* Union of four bytes and a long integer */
digitalWrite(chipSelectPin,LOW); /* Make LS7366R active */
SPI.transfer(0x60); // Request count
converter.bytes[3] = SPI.transfer(0x00); /* Read highest order byte */
converter.bytes[2] = SPI.transfer(0x00);
converter.bytes[1] = SPI.transfer(0x00);
converter.bytes[0] = SPI.transfer(0x00); /* Read lowest order byte */
digitalWrite(chipSelectPin,HIGH); /* Make LS7366R inactive */
return converter.result;
}
void SetUpLS7366RCounter(void)
/* Initialises LS7366R hardware counter on Counter Click board to read quadrature signals */
{
/* Control registers in LS7366R - see LS7366R datasheet for this and subsequent control words */
unsigned char IR = 0x00, MRD0=0x00;
// SPI initialization
SPI.begin();
//SPI.setClockDivider(SPI_CLOCK_DIV16); // SPI at 1Mhz (on 16Mhz clock)
delay(10);
/* Configure as free-running 4x quadrature counter */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
/* Instruction register IR */
IR |= 0x80; /* Write to register (B7=1, B6=0) */
IR |= 0x08; /* Select register MDR0: B5=0, B4=0, B3=1 */
SPI.transfer(IR); /* Write to instruction register */
/* Mode register 0 */
MRD0 |= 0x03; /* 4x quadrature count: B0=1, B1=1 */
/* B2=B3=0: free running. B4=B5=0: disable index. */
/* B6=0: asynchronous index. B7: Filter division factor = 1. */
SPI.transfer(MRD0);
digitalWrite(chipSelectPin,HIGH);
/* Clear the counter i.e. set it to zero */
IR = 0x00; /* Clear the instructino register IR */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
IR |= 0x20; /* Select CNTR: B5=1,B4=0,B3=0; CLR register: B7=0,B6=0 */
SPI.transfer(IR); /* Write to instruction register */
digitalWrite(chipSelectPin,HIGH);
}
void recvWithEndMarker()
/* Receive data from serial port finishing with "newline" character.
Based on http://forum.arduino.cc/index.php?topic=396450 Example 4 */
{
static byte ndx = 0;
char endMarker = '\n';
char rc;
if (Serial.available() > 0) { // If data is available read value from serial monitor
rc = Serial.read();
if (rc != endMarker) { // Store character in buffer if not end marker
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars) {
ndx = numChars - 1;
}
}
else { // Add end of string character and change flag to indicate new data is available
receivedChars[ndx] = '\0'; // terminate the string
ndx = 0;
newData = true;
}
}
}
bool convertNewNumber()
/* Converts character string to floating point number only if there are new
data to convert, otherwise returns false */
{
if (newData) {
dataNumber = 0.0;
dataNumber = atof(receivedChars);
newData = false;
return true;
}
else
{
return false;
}
}

235
src/lab_2/ProportionalClosedLoop/ProportionalClosedLoop.ino Normal file
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@@ -0,0 +1,235 @@
/* Example of driving servomotor using simple proportional closed loop control */
#include <SPI.h> /* Needed to communicate with LS7366R (Counter Click) */
/* Serial input aspects are based closely upon:
http://forum.arduino.cc/index.php?topic=396450
Example 4 - Receive a number as text and convert it to an int
Modified to read a float */
/* LS7366R aspects very loosely based on concepts used in controlling
the Robogaia 3-axis encoder shield though implementation is very different
https://www.robogaia.com/3-axis-encoder-conter-arduino-shield.html */
/* Pins used for L298 driver */
const int enA = 13; /* PWM output, also visible as LED */
const int in1 = 8; /* H bridge selection input 1 */
const int in2 = 9; /* H bridge selection input 2 */
const float minPercent = -100.0;
const float maxPercent = 100.0;
/* Used to to initiate SPI communication to LS7366R chip (Counter click) */
const int chipSelectPin = 10;
/* Size of buffer used to store received characters */
enum {numChars = 32};
/* Intervals in milliseconds for user-defined timed loops */
const int printInterval = 1000;
const int controlInterval = 20;
/* Global variables used in serial input */
char receivedChars[numChars]; // an array to store the received data
float dataNumber = 0; // new for this version
boolean newData = false;
/* Global variable used for motor control */
double percentDutyCycle;
long encoderPosnMeasured = 0;
double positionSetPoint = 0;
/* Proportional gain constant */
double Kp = 0.1;
/* Global variables used for loop timing */
unsigned long prevMillisPrint = 0; /* stores last time values were printed */
unsigned long prevMillisControl = 0; /* Stores last time control loop executed */
/* Overlapping regions of memory used to convert four bytes to a long integer */
union fourBytesToLong
{
long result;
unsigned char bytes [4];
};
void setup()
{
Serial.begin(9600);
Serial.println("Enter desired motor position: ");
/* Set up and initialise pin used for selecting LS7366R counter: hi=inactive */
pinMode(chipSelectPin, OUTPUT);
digitalWrite(chipSelectPin, HIGH);
SetUpLS7366RCounter();
delay(100);
/* Configure control pins for L298 H bridge */
pinMode(enA, OUTPUT);
pinMode(in1, OUTPUT);
pinMode(in2, OUTPUT);
/* Set initial rotation direction */
digitalWrite(in1, LOW);
digitalWrite(in2, HIGH);
}
void loop()
{
unsigned long currentMillis = millis();
// Call control loop at frequency controInterval
if (currentMillis - prevMillisControl >= controlInterval)
{
// Save the current time for comparison the next time the loop is called
prevMillisControl = currentMillis;
controlLoop();
}
// Call print loop at frequency of printInterval
if (currentMillis - prevMillisPrint >= printInterval)
{
// Save the current time for comparison the next time the loop is called
prevMillisPrint = currentMillis;
printLoop();
}
recvWithEndMarker(); // Update value read from serial line
// If a valid number has been read this is set to the current required position
if(convertNewNumber())
{
positionSetPoint = dataNumber;
}
}
void controlLoop()
{
double error;
// Get the current position from the encoder
encoderPosnMeasured = readEncoderCountFromLS7366R();
// Calculate the difference in position from the required position
error = positionSetPoint - (double)encoderPosnMeasured;
// Multiply by the gain
percentDutyCycle = error * Kp;
driveMotorPercent(percentDutyCycle);
}
/* Output PWM and H bridge signals based on positive or negative duty cycle % */
void driveMotorPercent(double percentDutyCycle)
{
// constrain the duty cycle to a value between -100 and 100 then map to +-255
percentDutyCycle = constrain(percentDutyCycle, -100, 100);
int regVal = map(percentDutyCycle, -100, 100, -255, 255);
analogWrite(enA, (int)abs(regVal)); // Write value to speed control pin
digitalWrite(in1, regVal>0); // Set the value of direction control pins to true or false
digitalWrite(in2, !(regVal>0));
}
/* Print count and control information */
void printLoop()
{ Serial.print("Actual position: ");
Serial.print(encoderPosnMeasured);
Serial.print("\t");
Serial.print("Desired position: ");
Serial.print(positionSetPoint);
Serial.print("\t");
Serial.print("Error: ");
Serial.print(positionSetPoint - (double)encoderPosnMeasured);
Serial.print("\r\n");
}
/* Reads the LS7366R chip to obtain up/down count from encoder. Reads four
bytes separately then concverts them to a long integer using a union */
long readEncoderCountFromLS7366R()
{
fourBytesToLong converter; /* Union of four bytes and a long integer */
digitalWrite(chipSelectPin,LOW); /* Make LS7366R active */
SPI.transfer(0x60); // Request count
converter.bytes[3] = SPI.transfer(0x00); /* Read highest order byte */
converter.bytes[2] = SPI.transfer(0x00);
converter.bytes[1] = SPI.transfer(0x00);
converter.bytes[0] = SPI.transfer(0x00); /* Read lowest order byte */
digitalWrite(chipSelectPin,HIGH); /* Make LS7366R inactive */
return converter.result;
}
/* Initialises LS7366R hardware counter on Counter Click board to read quadrature signals */
void SetUpLS7366RCounter(void)
{
/* Control registers in LS7366R - see LS7366R datasheet for this and subsequent control words */
unsigned char IR = 0x00, MRD0=0x00;
// SPI initialization
SPI.begin();
//SPI.setClockDivider(SPI_CLOCK_DIV16); // SPI at 1Mhz (on 16Mhz clock)
delay(10);
/* Configure as free-running 4x quadrature counter */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
/* Instruction register IR */
IR |= 0x80; /* Write to register (B7=1, B6=0) */
IR |= 0x08; /* Select register MDR0: B5=0, B4=0, B3=1 */
SPI.transfer(IR); /* Write to instruction register */
/* Mode register 0 */
MRD0 |= 0x03; /* 4x quadrature count: B0=1, B1=1 */
/* B2=B3=0: free running. B4=B5=0: disable index. */
/* B6=0: asynchronous index. B7: Filter division factor = 1. */
SPI.transfer(MRD0);
digitalWrite(chipSelectPin,HIGH);
/* Clear the counter i.e. set it to zero */
IR = 0x00; /* Clear the instructino register IR */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
IR |= 0x20; /* Select CNTR: B5=1,B4=0,B3=0; CLR register: B7=0,B6=0 */
SPI.transfer(IR); /* Write to instruction register */
digitalWrite(chipSelectPin,HIGH);
}
/* Receive data from serial port finishing with "newline" character.
Based on http://forum.arduino.cc/index.php?topic=396450 Example 4 */
void recvWithEndMarker()
{
static byte ndx = 0;
char endMarker = '\n';
char rc;
if (Serial.available() > 0) { // If data is available read value from serial monitor
rc = Serial.read();
if (rc != endMarker) { // Store character in buffer if not end marker
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars) {
ndx = numChars - 1;
}
}
else { // Add end of string character and change flag to indicate new data is available
receivedChars[ndx] = '\0'; // terminate the string
ndx = 0;
newData = true;
}
}
}
bool convertNewNumber()
/* Converts character string to floating point number only if there are new
data to convert, otherwise returns false */
{
if (newData) {
dataNumber = 0.0;
dataNumber = atof(receivedChars);
newData = false;
return true;
}
else
{
return false;
}
}

208
src/lab_2/SimpleControlNoFeedback/SimpleControlNoFeedback.ino Normal file
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@@ -0,0 +1,208 @@
/* Example of driving servomotor and reading encoder signals */
#include <SPI.h> /* Needed to communicate with LS7366R (Counter Click) */
/* Serial input aspects are based closely upon:
http://forum.arduino.cc/index.php?topic=396450
Example 4 - Receive a number as text and convert it to an int
Modified to read a float */
/* LS7366R aspects very loosely based on concepts used in controlling
the Robogaia 3-axis encoder shield though implementation is very different
https://www.robogaia.com/3-axis-encoder-conter-arduino-shield.html */
/* Pins used for L298 DC Motor driver */
#define enA 13 /* PWM output, also visible as LED */
#define in1 8 /* H bridge selection input 1 */
#define in2 9 /* H bridge selection input 2 */
#define minPercent -100.0
#define maxPercent 100.0
/* Used to to initiate SPI communication to LS7366R chip (Counter click) */
#define chipSelectPin 10
/* Size of buffer used to store received characters */
#define numChars 32
/* Intervals in milliseconds for user-defined timed loops */
#define printInterval 1000
/* Global variables used in serial input */
char receivedChars[numChars]; // an array to store the received data
float dataNumber = 0;
boolean newData = false;
/* Global variable used for motor control */
double percentSpeed;
/* Global variables used for loop timing */
unsigned long prevMillisPrint = 0; /* stores last time values were printed */
/* Overlapping regions of memory used to convert four bytes to a long integer */
union fourBytesToLong
{
long result;
unsigned char bytes [4];
};
void setup()
{
Serial.begin(9600);
Serial.println("Enter PWM duty cycle as a percentage (positive for forward, negative for reverse");
/* Set up and initialise pin used for selecting LS7366R counter: hi=inactive */
pinMode(chipSelectPin, OUTPUT);
digitalWrite(chipSelectPin, HIGH);
SetUpLS7366RCounter();
delay(100);
/* Configure control pins for L298 H bridge */
pinMode(enA, OUTPUT);
pinMode(in1, OUTPUT);
pinMode(in2, OUTPUT);
/* Set initial rotation direction */
digitalWrite(in1, LOW);
digitalWrite(in2, HIGH);
}
void loop()
{
unsigned long currentMillis = millis();
// Print out value to serial monitor at interval specified by printInterval variable
if (currentMillis - prevMillisPrint >= printInterval) {
// save the last time you printed output
prevMillisPrint = currentMillis;
printLoop();
}
// Check if new data has been input via serial monitor
recvWithEndMarker();
if(convertNewNumber()) // Update value read from serial line
{
percentSpeed=dataNumber;
driveMotorPercent(percentSpeed); // Send new speed value to motor driver
}
}
void driveMotorPercent(double percentSpeed)
/* Output PWM and H bridge signals based on positive or negative duty cycle % */
{
percentSpeed = constrain(percentSpeed, -100, 100); // Value must be in range -100 to +100
int regVal = map(percentSpeed, -100, 100, -255, 255); // Scale value to range -255 to +255
analogWrite(enA, (int)abs(regVal)); // Write value to speed control pin
digitalWrite(in1, regVal>0); // Set the value of direction control pins to true or false
digitalWrite(in2, !(regVal>0)); // depending on whether speed is positive or negative
}
void printLoop()
/* Print count and control information */
{
/* Sample counter chip and output position and requested speed */
long encoderCountFromLS7366R = readEncoderCountFromLS7366R();
Serial.print("Count from LS7366R = ");
Serial.print(encoderCountFromLS7366R);
Serial.print(" Percent speed = ");
Serial.print(percentSpeed);
Serial.print("\r\n");
}
long readEncoderCountFromLS7366R()
/* Reads the LS7366R chip to obtain up/down count from encoder. Reads four
bytes separately then concverts them to a long integer using a union */
{
fourBytesToLong converter; /* Union of four bytes and a long integer */
digitalWrite(chipSelectPin,LOW); /* Make LS7366R active */
SPI.transfer(0x60); // Request count
converter.bytes[3] = SPI.transfer(0x00); /* Read highest order byte */
converter.bytes[2] = SPI.transfer(0x00);
converter.bytes[1] = SPI.transfer(0x00);
converter.bytes[0] = SPI.transfer(0x00); /* Read lowest order byte */
digitalWrite(chipSelectPin,HIGH); /* Make LS7366R inactive */
return converter.result;
}
void SetUpLS7366RCounter(void)
/* Initialiseds LS7366R hardware counter on Counter Click board to read quadrature signals */
{
/* Control registers in LS7366R - see LS7366R datasheet for this and subsequent control words */
unsigned char IR = 0x00, MRD0=0x00;
// SPI initialization
SPI.begin();
//SPI.setClockDivider(SPI_CLOCK_DIV16); // SPI at 1Mhz (on 16Mhz clock)
delay(10);
/* Configure as free-running 4x quadrature counter */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
/* Instruction register IR */
IR |= 0x80; /* Write to register (B7=1, B6=0) */
IR |= 0x08; /* Select register MDR0: B5=0, B4=0, B3=1 */
SPI.transfer(IR); /* Write to instruction register */
/* Mode register 0 */
MRD0 |= 0x03; /* 4x quadrature count: B0=1, B1=1 */
/* B2=B3=0: free running. B4=B5=0: disable index. */
/* B6=0: asynchronous index. B7: Filter division factor = 1. */
SPI.transfer(MRD0);
digitalWrite(chipSelectPin,HIGH);
/* Clear the counter i.e. set it to zero */
IR = 0x00; /* Clear the instructino register IR */
digitalWrite(chipSelectPin,LOW); /* Select chip and initialise transfer */
IR |= 0x20; /* Select CNTR: B5=1,B4=0,B3=0; CLR register: B7=0,B6=0 */
SPI.transfer(IR); /* Write to instruction register */
digitalWrite(chipSelectPin,HIGH);
}
void recvWithEndMarker()
/* Receive data from serial port finishing with "newline" character.
Based on http://forum.arduino.cc/index.php?topic=396450 Example 4 */
{
static byte ndx = 0;
char endMarker = '\n';
char rc;
if (Serial.available() > 0) { // If data is available read value from serial monitor
rc = Serial.read();
if (rc != endMarker) { // Store character in buffer if not end marker
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars) {
ndx = numChars - 1;
}
}
else { // Add end of string character and change flag to indicate new data is available
receivedChars[ndx] = '\0'; // terminate the string
ndx = 0;
newData = true;
}
}
}
bool convertNewNumber()
/* Converts character string to floating point number only if there are new
data to convert, otherwise returns false */
{
if (newData) {
dataNumber = 0.0;
dataNumber = atof(receivedChars);
newData = false;
return true;
}
else
{
return false;
}
}

13
res/lab_2/SimplisticRampStepper Mac.c → src/lab_2/SimplisticRampStepper.c
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@@ -1,13 +1,10 @@
// Simplistic Ramp Stepper program with millis function adapted for MacOS
#include <stdio.h>
#include <stdlib.h>
#include <windows.h>
#include <math.h>
#include <time.h>
/* Only needed in Windows program to maintain compatibility with Arduino version of C/C++ */
typedef enum { false, true } bool;
#define bool BOOL
#define true 1
#define false 0
const bool FWDS = true;
@@ -97,16 +94,14 @@ int main()
return 0;
}
/* Only needed for compatibility with Arduino program because millis() is not a native MacOS function */
long millis(void)
/* Only needed for compatibility with Arduino program because millis() is not a native Windows API function */
{
struct timespec _t;
clock_gettime(CLOCK_REALTIME, &_t);
return _t.tv_sec*1000 + lround(_t.tv_nsec/1e6);
return GetTickCount();
}
/* Move a single step. If this were running on the Arduino we would holding pulse high for delayMicroSeconds */
void moveOneStep()
/* Move a single step. If this were running on the Arduino we would holding pulse high for delayMicroSeconds */
{
if (p != 0) /* p=0 is code for "don't make steps" */
{

349
src/lab_2/SimplisticRampStepper/SimplisticRampStepper.ino Normal file
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@@ -0,0 +1,349 @@
/* Stepper motor demonstration program written by Arthur Jones,
4 November 2018. Implements a simplistic and ineffective ramping
algorithm but provides framework for implementation of LeibRamp
algorithm described by Aryeh Eiderman, http://hwml.com/LeibRamp.pdf
Makes use of background work and some aspects of code developed
by Choaran Wang, 2017-18. This in turn incorporates some ideas
used in the AccelStepper library:
https://www.airspayce.com/mikem/arduino/AccelStepper/
Serial input aspects are based closely upon:
http://forum.arduino.cc/index.php?topic=396450
Example 4 - Receive a number as text and convert it to an int
Modified to read a long */
// #define USEINTERRUPTS
const int stepPin = 13;
const int dirPin = 9;
const bool FWDS = true;
const bool BWDS = false;
#ifdef USEINTERRUPTS
const long ticksPerSec = 16000000; // Clock speed of Arduino
#else
const long ticksPerSec = 1000000; // microseconds in this case
#endif
/* Define permissible parameters for motor */
// For testing by watching LED: try movements in order of 100 steps
//float accelSteps=20; /* leave this as a variable as we may over-write it */
//const float minSpeed = 2.0;
//const float maxPermissSpeed = 20.0;
//const float maxAccel = 10.0;
//const long stepLengthMus = 10000;
// For lab testing with real motor: try movements in the order of 3000 steps
float accelSteps=1000; /* leave this as a variable as we may over-write it */
const float minSpeed=10.0;
const float maxPermissSpeed=1000.0;
const float maxAccel=500.0;
const long stepLengthMus=100;
/* Intervals in milliseconds for user-defined timed loops */
const long printInterval = 1000;
/* Global variables used for loop timing */
unsigned long prevMillisPrint = 0; /* stores last time values were printed */
/* Global variables used in serial input */
enum {numChars = 32};
char receivedChars[numChars]; /* an array to store the received data */
long dataNumber = 0; /* Value read from serial monitor input */
boolean newData = false;
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
double maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
volatile float p; /* Step interval in clock ticks or microseconds */
float p1, ps; /* Minimum and maximum step periods */
double deltaP; /* You'll be able to get rid of this later */
double R; /* Multiplying constant used in Eiderman's algorithm */
/* Global variable used for noting previous time of a step in timed loop */
long prevStepTime;
void setup()
{
long stepsToGo = 0;
currentPosition = 0;
goToPosition(dataNumber);
pinMode(stepPin, OUTPUT);
pinMode(dirPin, OUTPUT);
Serial.begin(9600);
Serial.println("Enter target position in number of steps and hit return");
// If USEINTERRUPTS is defined at the start of the program this section will be used
#ifdef USEINTERRUPTS
cli();
TCCR1A = 0; // No output compare
TCCR1B = 0;
TCCR1B |= (1 << WGM12); //CTC mode
OCR1A = 0; // Set to zero for the present time: catch this to switch interrupt off
TCCR1B |= (1 << CS12); // 256 prescaler: overwritten in ISR
TIMSK1 |= (1 << OCIE1A); //enable timer compare interrupt
sei();
#else //
// Use built-in Arduino function micros() to get the time in microseconds since the program started running.
// Documentation: https://www.arduino.cc/reference/en/language/functions/time/micros/
prevStepTime = micros(); // This is a built-in Arduino function.
#endif
}
void loop()
{
unsigned long currentMillis = millis();
unsigned long currentMicros;
recvWithEndMarker();
stepsToGo = computeStepsToGo();
if (convertNewNumber())
{
/* Only get to this stage if there was new data to convert */
if (stepsToGo <= 0)
{
/* Only get to this stage if not busy, otherwise will have thrown away input */
goToPosition(dataNumber);
/* Delete these and replace with Leib Ramp formulae */
double maxInterval = ((double)ticksPerSec) / minSpeed;
ps = ((double)ticksPerSec) / maxPermissSpeed;
deltaP = (maxInterval - ps) / accelSteps;
/* End of section requiring redefinitions */
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
/* Definiiton of S where ther is no constant speed period - check it is still applicable */
accelSteps = (long)(stepsToGo / 2);
/* Need to redefine maxSpeed here as we never fully accelerate */
}
/* Will need to over-write these with correct initial value of p and p1, along with R */
p = maxInterval;
p1 = (double)ticksPerSec/minSpeed;
/* End of section requiring redefinitions */
ps = ((double)ticksPerSec) / maxSpeed; /* Eq 7 in paper: this is OK */
#ifdef USEINTERRUPTS
if (p != 0)
{
// Re-enable interrupts if non-zero steps
TIMSK1 |= (1 << OCIE1A);
}
#endif
}
}
#ifndef USEINTERRUPTS
/* Timed loop for stepping, and associated coding */
currentMicros = micros();
if (currentMicros - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMicros;
computeNewSpeed();
}
#endif
/* Timed loop for printing */
if (currentMillis - prevMillisPrint >= printInterval)
{
/* Save the last time output was printed */
prevMillisPrint = currentMillis;
printLoop();
}
}
void moveOneStep()
/* Move a single step, holding pulse high for delayMicroSeconds */
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
digitalWrite(stepPin, HIGH);
if (direction == FWDS)
{
/* Is something missing here? */
currentPosition++;
}
else
{
/* Is something missing here? */
currentPosition--;
}
delayMicroseconds(stepLengthMus);
digitalWrite(stepPin, LOW);
}
}
void computeNewSpeed()
/* Calcuate new value of step interval p based on constants defined in loop() */
{
/* You may need to declare some temporary variables for this function... */
stepsToGo = computeStepsToGo();
if (stepsToGo == 0)
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo > accelSteps && (long)p > long(ps))
/* Speeding up */
{
/* Delete this simplistic change to p and replace with something else */
p -= deltaP;
}
else if (stepsToGo <= accelSteps)
/* Slowing down */
{
/* Delete this simplistic change to p and replace with something else */
p += deltaP;
}
else
/* Running at constant speed */
{
/* For simpplistic approach, p=p so do nothing to it.
But you will need to put something here for Leib ramp ... */
}
/* Update to step interval based on Leib ramp algorithm, using temporary variables */
/* Need to ensure rounding error does not cause drift outside acceptable interval range:
replace p with relevant bound if it strays outside - so need to write some code here */
}
long computeStepsToGo()
/* Work out how far the stepper motor still needs to move */
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
void goToPosition(long newPosition)
/* Set the target position and determine direction of intended movement */
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}
void recvWithEndMarker()
/* Receive data from serial port finishing with "newline" character.
Based on http://forum.arduino.cc/index.php?topic=396450 Example 4 */
{
static byte ndx = 0;
char endMarker = '\n';
char rc;
if (Serial.available() > 0)
{
rc = Serial.read();
if (rc != endMarker)
{
receivedChars[ndx] = rc;
ndx++;
if (ndx >= numChars)
{
ndx = numChars - 1;
}
}
else
{
receivedChars[ndx] = '\0'; // terminate the string
ndx = 0;
newData = true;
}
}
}
bool convertNewNumber()
/* Converts character string to long integer only if there are new
data to convert, otherwise returns false */
{
if (newData)
{
dataNumber = 0.0; // new for this version
dataNumber = atol(receivedChars); // new for this version
newData = false;
return true;
}
else
{
return false;
}
}
void printLoop()
/* Print current position of stepper using timed loop */
{
/* Sample all counters one after the other to avoid delay-related offsets */
Serial.print("Current position = ");
Serial.print(currentPosition);
Serial.print("\r\n");
}
#ifdef USEINTERRUPTS
ISR(TIMER1_COMPA_vect)
/* Interrupt service routine which essentially just calls moveOneStep and computeNewSpeed.
However, it also changes the prescale value on-the-fly so that the full range of possible
step rates can be exploited, from around 0.25 Hz upwards, limited by step pulse width. */
{
if (p == 0)
{
// Disable interrupt to avoid endless calling of interrupt if not needed
TIMSK1 &= !(1 << OCIE1A);
}
moveOneStep();
/* Adapt prescaler to keep OCR1A as large as possible within acceptable range */
if (p < 65536)
{
// Prescaler 1
OCR1A = (long)p - 1;
TCCR1B = (TCCR1B & 0xF8) | 0x01;
}
else if (p < 524288)
{
// Prescaler 8
OCR1A = ((long)p >> 3) - 1;
TCCR1B = (TCCR1B & 0xF8) | 0x02;
}
else if (p < 4194304)
{
// Prescaler 64
OCR1A = ((long)p >> 6) - 1;
TCCR1B = (TCCR1B & 0xF8) | 0x03;
}
else if (p < 16777216)
{
// Prescaler 256
OCR1A = ((long)p >> 8) - 1;
TCCR1B = (TCCR1B & 0xF8) | 0x04;
}
else
{
// Prescaler 1024
OCR1A = ((long)p >> 10) - 1;
TCCR1B = (TCCR1B & 0xF8) | 0x05;
}
computeNewSpeed();
}
#endif

177
src/lab_2/SimplisticRampStepperMac.c Normal file
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@@ -0,0 +1,177 @@
// Simplistic Ramp Stepper program with millis function adapted for MacOS
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
/* Only needed in Windows program to maintain compatibility with Arduino version of C/C++ */
typedef enum { false, true } bool;
#define true 1
#define false 0
const bool FWDS = true;
const bool BWDS = false;
const long ticksPerSec = 1000; // ms on PC
// on Arduino it is 1E6 for micros (for s/w) or 1.6E7 for 62.5 ns ticks (for h/w)
void moveOneStep();
void computeNewSpeed();
long computeStepsToGo();
void goToPosition(long newPosition);
long millis(void);
/* Note: we are using global variables ONLY to preserve compatibility with the Arduino program structure.
They should not normally be used in C or C++ programs as they make for a poor software design. */
/* Global variables relating to stepper motor position counting etc. */
long stepsToGo; /* Number of steps left to make in present movement */
long targetPosition; /* Intended destination of motor for given movement */
volatile long currentPosition = 0; /* Position in steps of motor relative to startup position */
float maxSpeed; /* Maximum speed in present movement (not nec. max permitted) */
bool direction; /* Direction of present movement: FWDS or BWDS */
/* Global variables used in simplistic and Leib Ramp algorithms */
volatile float p; /* Step interval in clock ticks or microseconds */
float ps; /* Maximum step periods */
float deltaP; /* You'll be able to get rid of this later */
/* Global variable used for noting previous time of a step in timed loop and for calculating speed and accel */
long prevStepTime=0;
long millisAtStart;
float prevSpeed=0.0;
/* Define permissible parameters for motor */
// For testing on PC only, not for use in Arduino program: try movements in order of 50-100 steps
float accelSteps=20; /* leave this as a variable as we may over-write it */
const float minSpeed = 1.0; // in steps/s
const float maxPermissSpeed = 20.0; // in steps/s
const float maxAccel = 10.0; // in steps/s^2
int main(int argc, char *argv[])
{
unsigned long currentMillis = millis();
prevStepTime = 0;
long positionToMoveTo;
sscanf(argv[1], "%ld", &positionToMoveTo);
printf(" Time (s), Speed (steps/s), Accel (steps/s^2), Posit'n (steps), Step time (ticks)\n");
goToPosition(positionToMoveTo);
/* -------------------------------------------------------------- */
/* Start of pre-computation code - only executed once per profile */
float maxInterval = ((float)ticksPerSec) / minSpeed;
ps = ((float)ticksPerSec) / maxPermissSpeed;
deltaP = (maxInterval - ps) / accelSteps;
stepsToGo = computeStepsToGo();
maxSpeed = maxPermissSpeed;
if (2 * accelSteps > stepsToGo)
{
accelSteps = (long)(stepsToGo / 2);
}
p = maxInterval;
ps = ((float)ticksPerSec) / maxSpeed;
/* End of pre-computation code */
/* -------------------------------------------------------------- */
millisAtStart = millis(); /* Needed only to tabulate speed vs. time */
/* Timed loop for stepping */
while(stepsToGo > 0)
{
currentMillis = millis();
if (currentMillis - prevStepTime >= p)
{
moveOneStep();
prevStepTime = currentMillis;
computeNewSpeed();
}
}
return 0;
}
/* Only needed for compatibility with Arduino program because millis() is not a native MacOS function */
long millis(void)
{
struct timespec _t;
clock_gettime(CLOCK_REALTIME, &_t);
return _t.tv_sec*1000 + lround(_t.tv_nsec/1e6);
}
/* Move a single step. If this were running on the Arduino we would holding pulse high for delayMicroSeconds */
void moveOneStep()
{
if (p != 0) /* p=0 is code for "don't make steps" */
{
// Print to screen instead of making a step
if (direction == FWDS)
{
currentPosition++;
}
else
{
currentPosition--;
}
/* Instead of actually making step, print out parameters for current step */
float speed = (float)(ticksPerSec)/p;
float accel = (float)(ticksPerSec)*(speed-prevSpeed)/p;
printf("%16.3f, %16.3f, %16.3f, %16ld, %16.3f\n", 0.001*(millis()-millisAtStart), speed, accel, currentPosition, p);
prevSpeed = speed;
}
}
/* Calcuate new value of step interval p based on constants defined in timed loop */
void computeNewSpeed()
{
stepsToGo = computeStepsToGo();
/* Start of on-the-fly step calculation code, executed once per step */
if (stepsToGo == 0)
{
p = 0; // Not actually a zero step interval, used to switch stepping off
return;
}
else if (stepsToGo >= accelSteps && (long)p > (long)ps) // Changed to make ramps even length
/* Speeding up */
{
p -= deltaP;
}
else if (stepsToGo <= accelSteps)
/* Slowing down */
{
p += deltaP;
}
/* else p is unchanged: running at constant speed */
/* End of on-the-fly step calculation code */
}
/* Work out how far the stepper motor still needs to move */
long computeStepsToGo()
{
if (direction == FWDS)
{
return targetPosition - currentPosition;
}
else
{
return currentPosition - targetPosition;
}
}
/* Set the target position and determine direction of intended movement */
void goToPosition(long newPosition)
{
targetPosition = newPosition;
if (targetPosition - currentPosition > 0)
{
direction = FWDS;
}
else
{
direction = BWDS;
}
}

165
src/submission.md
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@@ -1,9 +1,8 @@
---
author: Akbar Rahman (20386125)
date: \today
title: Change Me
tags: [ change_me ]
uuid: Change Me
title: MMME3085---Lab 2 Coursework
tags: [ mmme, mmme3086 ]
documentclass: article
geometry:
- margin=1in
@@ -12,7 +11,163 @@ geometry:
\maketitle
\thispagestyle{empty}
\newpage
\tableofcontents
# Question 1
As you increase the proportional gain, you increase the responsiveness of the motor to error,
but it is easy to go too high and cause the motor to oscillate around the target position.
This is because the motor current is set proportional to the error.
This means that if the motor is spinning too quickly, the proportional control will not slow
down the motor in time to avoid overshoot.
Additionally, if the target position is set too close to the motor, the proportional control
maybe not push enough current to motor to actually get it spinning in some cases.
# Question 2
When derivative control is added at low levels (0.02) it reduces the oscillations.
This is because derivative control only considers the rate of change of of the error
and tries to bring the rate of change to zero.
This means that adds a *damping* effect to the controller, slowing it down when it's moving,
and thereby reducing/eliminating overshoot and oscillations.
# Question 3
There are two if statements in the loop function as the controller will work best and be able to respond
to changes faster if the control functions are run more frequently.
The faster the better.
However, the Arduino does not really need to print to serial every time as it is only used to ensure
the Arduino is running properly.
If `prevMillisControl` and `prevMillisPrint` was replaced with just one variable, the `printLoop` function
would never run as the variable would have been updated to equal `currentMillis` before the print loop's
if statement will check its condition.
# Question 4
First the library is `include`d on line 4:
```c
#include <PID_V1.h>
```
Then a PID object is created using the `myPID` function on line 48.
This object holds all the properties of the PID controller including values of $K_p$, $K_i$, and $K_d$,
as well as a pointers to variables with the current motor position, speed, and set point.
```c
PID myPID(&encoderPosnMeasured, &percentSpeed, &positionSetPoint, Kp, Ki, Kd, DIRECT);
```
Some initialisation is run in `setup` on lines 89 and 90:
```c
myPID.SetOutputLimits(-100,100);
myPID.SetMode(AUTOMATIC);
```
Then the main control loop starts.
The `loop` function runs the `controlLoop` function every 20 milliseconds (as defined by
`controlInterval`) on line 101.
The `controlLoop` function retrieves the current motor position and stores it in the variable
that the PID controller has a pointer to.
`myPID.Compute()` is then called to recompute the motor speed required to get to the set point
and this is stored in the `percentSpeed` variable as the controller has a pointer to it.
This new speed is passed to the `driveMotorPercent` function to update the motor's speed.
\newpage
# Header
# Question 5
The mathematically complex operations in `loop()` as it is run infrequently.
This is because it is inside an if statement with condition `convertNewNumber()`, which
returns `false` if there is no new data to convert (i.e. if there has not been any serial input
since the last loop).
Essentially, the complex operations only run once per serial input, meaning it is run very infrequently
compared to how many times the loop runs.
# Question 6
Complex operations in `computeNewSpeed()` have been avoided because this function runs very frequently
(on the order of microseconds).
Therefore it is important that the function does not consume too many processor cycles,
else the Arduino will be able to do little else.
# Question 7
If the stepper motor is run too quickly, steps will be skipped and it will not accelerate or
accelerate slowly.
It also makes a different noise to normal operation.
This is because the pole pairs of the motor will be activated too soon if attempting to spin
the motor too fast.
If they are activated too soon, they will not have the desired effect of speeding up the rotation
of the shaft, as the magnets of the motor will not be aligned as needed.
This is also why the steppers use a ramp function, so that the shaft has time accelerate to the
desired speed without skipping steps.
\newpage
# Question 8
```{ .matplotlib caption="A plot of velocity and acceleration for SimplisticRampStepper" dpi=300 }
import numpy as np
import matplotlib.pyplot as plt
TIME = 'Time_s'
SPEED = 'Speed_stepss'
ACCEL = 'Accel_stepss2'
POS = 'Positn_steps'
STEP = 'Step_time_ticks'
data = np.genfromtxt("csv/SimplisticRampStepper_out_50.csv",
delimiter=",", names=True, dtype=float)
fig, ax1 = plt.subplots()
ax2 = ax1.twinx()
lines1 = ax1.plot(data[TIME], data[SPEED], label='Speed [steps/s]', color='tab:blue')
lines2 = ax2.plot(data[TIME], data[ACCEL], label='Acceleration [steps/s^2]', color='tab:red')
ax1.set_ylabel('Speed [steps/s]')
ax2.set_ylabel('Acceleration [steps/s^2]')
lines = lines1 + lines2
ax1.legend(lines, [ l.get_label() for l in lines ])
ax1.set_xlabel("Time [s]")
fig.tight_layout()
```
```{ .matplotlib caption="A plot of velocity and acceleration for LeibRampStepper" dpi=300 }
import numpy as np
import matplotlib.pyplot as plt
TIME = 'Time_s'
SPEED = 'Speed_stepss'
ACCEL = 'Accel_stepss2'
POS = 'Positn_steps'
STEP = 'Step_time_ticks'
data = np.genfromtxt("csv/LeibRampStepper_out_50.csv",
delimiter=",", names=True, dtype=float)
fig, ax1 = plt.subplots()
ax2 = ax1.twinx()
lines1 = ax1.plot(data[TIME], data[SPEED], label='Speed [steps/s]', color='tab:blue')
lines2 = ax2.plot(data[TIME], data[ACCEL], label='Acceleration [steps/s^2]', color='tab:red')
ax1.set_ylabel('Speed [steps/s]')
ax2.set_ylabel('Acceleration [steps/s^2]')
lines = lines1 + lines2
ax1.legend(lines, [ l.get_label() for l in lines ], loc='upper right')
ax1.set_xlabel("Time [s]")
fig.tight_layout()
```

2
submission.mk
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@@ -1 +1 @@
SUBMISSION_FILENAME=changeme.pdf
SUBMISSION_FILENAME=mmme3086_lab2_coursework_akbar_alvi_rahman_20386125.pdf