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Strawman removed - start of actual implementation

Neon22 2014-05-19 16:14:50 -07:00
parent f37948d871
commit a046ee030f
1 changed files with 7 additions and 152 deletions
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159
Servos.md

@ -7,17 +7,17 @@ Each servo is listed with its update rate (pulse cycle) and pulse width.
* Cheap.
* Generally have +/-90 degree rotations about a centered rest position
* but can also be continuous rotation or other ranges (e.g. +/- 180 degree).
* Use a PWM mechanism to control their desired position with a central frequency approximately 1500 usecs (666 Hz).
* Use a PWM mechanism (but not standard PWM) to control their desired position with a central frequency approximately 1500 usecs (666 Hz).
* Need to get updates at from 20-65 times per second (Hz).
####Digital servos:
* have a higher refresh frequency - upto 400Hz and therefore:
* hold position better,
* have better torque, speed, and accuracy
* and therefore also use more power.
* therefore use more power.
* This higher rate is handled internally and so the digital servo keeps updating its position even when it receives external updates infrequently.
* but if signals are received at a higher rate the servo can update more responsively.
* are more expensive.
* more expensive than analog.
* some also have other communication options. E.g. serial ports.
* This Servo class is for traditional PWM control only and does not address these.
@ -87,153 +87,8 @@ The pyboard has 23 pins that can output hardware PWM. It has 12x 16bit timers an
The Teensy3.1 has 12 pins that can output PWM but (I think) only 3 Timers. So a software interrupt routine would be an excellent library for the Teensy. The Teensy 3.1 has PWM 12bit resolution. Some data here: https://www.pjrc.com/teensy/td_pulse.html
####Straw man code
So Servo setup might look like the following.
ISR defined within - need to be weritten in c so as to use interrupts. Initially just software based.
```
#!/usr/bin/python
####Implementation
The actual implementation on the pyboard is set to only adjust the 4 lines dedicated to Servo control.
The code wouuld need to be updated or replaced to drive more pins as servos.
The Servo is driven by hardware using TIM5 which neatly is designed to control exactly the four pins allocated to Servos on the Pyboard.
### Potential Servo implementation ideas
### top level servo pool
# servos = Servo_pool(update_rate, Servo_pool.SOFTWARE) # optional rate in Hz
# servos.set_desired_update_rate(freq_in_Hz)
# servos.update_rate() # actual update rate
##
# s1 = servos.add(pin, serrvoargs)
# s1.setup(min_width, detent_width, max_width)
# s1.move(percent) # set pulse width for this percent
# s1.remove() # deletes servo from pool
## Optionally if angle is important.
# s1.set_angles(min, max) # set angle values for rotate function
# s1.rotate(angle)
import Servo_ISR # C lib which exposes interrupt request routine for servos.
# has:
# - isr = Servo_ISR(type) # creates a non-runing interrupt service routine for Servos (h/w or s/w)
# - Servo_ISR.start() #
# - Servo_ISR.stop() #
# - Servo_ISR.set_rate(Hz) # ISR will interrupt at this rate
# - Servo_ISR.set_active(pin_width_pairs) # list of python class variables of pin, pulse_width pairs
# - E.g. [[s1.pin, s1.value], [s2.pin, s2.value]]
# - When started this ISR routine will step through the list one pair at each interrupt.
# Setting the pin to active high pulse of that width in usecs
# H/w interrupt wil exit very quickly as pulse happens without its attention
# S/w interrupt wil need to wait or trigger itself to come back and switch pulse off at right time.
class Servo_pool(object):
SOFTWRE = 0
HARDWARE = 1
def __init__(self, update_rate=50, ISR_type=Servo_pool.HARDWARE):
" holds all servos, allocates to ISRs "
self.pool = []
self.desired_rate = update_rate # user wants this rate
self.rate = update_rate # the rate we can actually do (may be lower than desired)
self.isrs = []
class ISR(self):
""" holds a number of servos - externally managed
- rate is in Hz
"""
IDLE = 0
STARTED = 1
def __init__(self, rate, ISR_type):
self.isr_type = ISR_type
self.my_servos = []
self.pin_width_pairs = []
self.state = ISR.IDLE
self.isr = Servo_ISR(ISR_type)
self.rate = rate
self.set_rate(rate)
def add_servo(self, servo):
" "
self.my_servos.append(servo)
self.pin_width_pairs.append([servo.pin, servo.value])
def remove_servo(self, servo):
" "
self.my_servos.pop(servo)
pos = self.pin_width_pairs.index([servo.pin, servo.value])
self.pin_width_pairs.pop(pos)
# !! deal with empty my_servos
def start(self):
self.isr.start()
self.state = ISR.STARTED
def stop(self):
self.isr.stop()
self.state = ISR.IDLE
def set_rate(self, rate):
self.isr.set_rate(rate)
def add(self, pin, *args, **kwargs):
s = Servo(self, pin, *args, **kwargs)
self.pool.append(s) # !! check for existing etc...
# do we have enough ISRs
# add servo to ISR's my_servos list
# !! should we degrade update_rate ?
if not self.isrs:
isr = ISR(self.rate, self.isr_type)
self.isrs.append(isr)
else:
if self.need_new_isr_p():
isr = ISR(self.rate, self.isr_type)
self.isrs.append(isr)
else: # use existing (last)
isr = self.isrs[-1]
#
isr.add_servo(s)
if isr.state == ISR.IDLE:
isr.start() # we added one - lets go!
return s
def remove_servo(self, servo):
" servo wants itself removed form ISR routines and list of servos "
pass # !!
def need_new_isr_p(self):
" do we need a new isr "
# check to see if adding one more to latest isr group will bust interrupts
if len(self.isrs[-1]) * 3/100.0 > 10.0/self.desired_rate:
#rate will drop if we add - need new ISR
return True
else: return False
class Servo(object):
" hold servo settings "
def __init__(self, pool, pin, min_angle=-90, detent=0, max_angle=90, min_width=1000, detent_width=1500, max_width=2000):
self.pool = pool
self.pin = pin
self.min_width = min_width
self.detent_width = detent_width
self.max_width = max_width
#
self.detent = 0
self.min_angle = min_angle
self.max_angle = max_angle
#
self.value = detent_width # pulse width used by ISR routine
def move(self, percent):
" move servo to this percent of range defined by angles"
# !! set self.value to pulse width needed.
# !! two linear interps - min-detent, detent-max
pass
def rotate(self, angle):
" move servo to angle as cal using min. max angles "
# !! set self.value to pulse width needed
# !! two linear interps - min-detent, detent-max
pass
def remove(self):
" take self out of servo pool "
self.pool.remove_servo(self)
```