# -*- coding: utf-8 -*- # ***************************************************************************** # # This program is free software; you can redistribute it and/or modify it under # the terms of the GNU General Public License as published by the Free Software # Foundation; either version 2 of the License, or (at your option) any later # version. # # This program is distributed in the hope that it will be useful, but WITHOUT # ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS # FOR A PARTICULAR PURPOSE. See the GNU General Public License for more # details. # # You should have received a copy of the GNU General Public License along with # this program; if not, write to the Free Software Foundation, Inc., # 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA # # Module authors: # Markus Zolliker # # ***************************************************************************** """driver for phytron motors limits switches are not yet implemented """ import time from frappy.core import Done, Command, EnumType, FloatRange, IntRange, \ HasIO, Parameter, Property, Drivable, PersistentMixin, PersistentParam, \ StringIO, StringType, IDLE, BUSY, ERROR, Limit from frappy.errors import CommunicationFailedError, HardwareError from frappy.features import HasOffset from frappy.states import HasStates, status_code, Retry class PhytronIO(StringIO): end_of_line = '\x03' # ETX timeout = 0.5 identification = [('0IVR', 'MCC Minilog .*')] def communicate(self, command): ntry = 5 warn = None for itry in range(ntry): try: _, _, reply = super().communicate('\x02' + command).partition('\x02') if reply[0] == '\x06': # ACK break raise CommunicationFailedError(f'missing ACK {reply!r} (cmd: {command!r})') except Exception as e: if itry < ntry - 1: warn = e else: raise if warn: self.log.warning('needed %d retries after %r', itry, warn) return reply[1:] class Motor(HasOffset, HasStates, PersistentMixin, HasIO, Drivable): axis = Property('motor axis X or Y', StringType(), default='X') address = Property('address', IntRange(0, 15), default=0) circumference = Property('cirumference for rotations or zero for linear', FloatRange(0), default=360) encoder_mode = Parameter('how to treat the encoder', EnumType('encoder', NO=0, READ=1, CHECK=2), default=1, readonly=False) value = PersistentParam('angle', FloatRange(unit='deg')) status = PersistentParam() target = Parameter('target angle', FloatRange(unit='deg'), readonly=False) speed = Parameter('', FloatRange(0, 20, unit='deg/s'), readonly=False) accel = Parameter('', FloatRange(2, 250, unit='deg/s/s'), readonly=False) encoder_tolerance = Parameter('', FloatRange(unit='deg'), readonly=False, default=0.01) sign = PersistentParam('', IntRange(-1,1), readonly=False, default=1) encoder = Parameter('encoder reading', FloatRange(unit='deg')) backlash = PersistentParam("""backlash compensation\n offset for always approaching from the same side""", FloatRange(unit='deg'), readonly=False, default=0) target_min = Limit() target_max = Limit() alive_time = PersistentParam('alive time for detecting restarts', FloatRange(), default=0, export=False) ioClass = PhytronIO _step_size = None # degree / step _blocking_error = None # None or a string indicating the reason of an error needing clear_errors _running = False # status indicates motor is running STATUS_MAP = { '08': (IDLE, ''), '01': (ERROR, 'power stage failure'), '02': (ERROR, 'power too low'), '04': (ERROR, 'power stage over temperature'), '07': (ERROR, 'no power stage'), '80': (ERROR, 'encoder failure'), } def get(self, cmd): return self.communicate(f'{self.address:x}{self.axis}{cmd}') def set(self, cmd, value): # make sure e format is not used, max 8 characters strvalue = f'{value:.6g}' if 'e' in strvalue: if abs(value) <= 1: # very small number strvalue = f'{value:.7f}' elif abs(value) < 99999999: # big number strvalue = f'{value:.0f}' else: raise ValueError(f'number ({value}) must not have more than 8 digits') self.communicate(f'{self.address:x}{self.axis}{cmd}{strvalue}') def set_get(self, cmd, value, query): self.set(cmd, value) return self.get(query) def read_alive_time(self): now = time.time() axisbit = 1 << int(self.axis == 'Y') active_axes = int(self.get('P37R')) # adr 37 is a custom address with no internal meaning if not axisbit & active_axes: # power cycle detected and this axis not yet active self.set('P37S', axisbit | active_axes) # activate axis if now < self.alive_time + 7 * 24 * 3600: # the device was running within last week # inform the user about the loss of position by the need of doing clear_errors self._blocking_error = 'lost position' else: # do silently self.clear_errors() self.alive_time = now self.saveParameters() return now def read_value(self): return float(self.get('P20R')) * self.sign def read_encoder(self): if self.encoder_mode == 'NO': return self.value return float(self.get('P22R')) * self.sign def write_sign(self, value): self.sign = value self.saveParameters() return Done def get_step_size(self): self._step_size = float(self.get('P03R')) def read_speed(self): if self._step_size is None: # avoid repeatedly reading step size, as this is polled and will not change self.get_step_size() return float(self.get('P14R')) * self._step_size def write_speed(self, value): self.get_step_size() # read step size anyway, it does not harm return float(self.set_get('P14S', round(value / self._step_size), 'P14R')) * self._step_size def read_accel(self): if not self._step_size: self.get_step_size() return float(self.get('P15R')) * self._step_size def write_accel(self, value): self.get_step_size() return float(self.set_get('P15S', round(value / self._step_size), 'P15R')) * self._step_size def check_target(self, value): self.checkLimits(value) self.checkLimits(value + self.backlash) def write_target(self, value): self.read_alive_time() if self._blocking_error: self.status = ERROR, 'clear_errors needed after ' + self._blocking_error raise HardwareError(self.status[1]) self.saveParameters() if self.backlash: # drive first to target + backlash # we do not optimize when already driving from the right side self.set('A', self.sign * (value + self.backlash)) else: self.set('A', self.sign * value) self.start_machine(self.driving) self._running = True return value def read_status(self): sysstatus = self.communicate(f'{self.address:x}SE') sysstatus = sysstatus[1:4] if self.axis == 'X' else sysstatus[5:8] self._running = sysstatus[0] != '1' status = self.STATUS_MAP.get(sysstatus[1:]) or (ERROR, f'unknown error {sysstatus[1:]}') if status[0] == ERROR: self._blocking_error = status[1] return status return super().read_status() # status from state machine def check_moving(self): prev_enc = self.encoder if self.encoder_mode != 'NO': enc = self.read_encoder() else: enc = self.value if not self._running: # at target return False if self.encoder_mode != 'CHECK': return True e1, e2 = sorted((prev_enc, enc)) if e1 - self.encoder_tolerance <= self.value <= e2 + self.encoder_tolerance: return True self.log.error('encoder lag: %g not within %g..%g', self.value, e1, e2) self.get('S') # stop self.saveParameters() self._blocking_error = 'encoder lag error' raise HardwareError(self._blocking_error) @status_code(BUSY) def driving(self, sm): if self.check_moving(): return Retry if self.backlash: # drive to real target self.set('A', self.sign * self.target) return self.driving_to_final_position return self.finishing @status_code(BUSY) def driving_to_final_position(self, sm): if self.check_moving(): return Retry return self.finishing @status_code(BUSY) def finishing(self, sm): if sm.init: sm.mismatch_count = 0 # finish pos = self.read_value() enc = self.read_encoder() if (self.encoder_mode == 'CHECK' and abs(enc - pos) > self.encoder_tolerance): if sm.mismatch_count > 2: self.log.error('encoder mismatch: abs(%g - %g) < %g', enc, pos, self.encoder_tolerance) self._blocking_error = 'encoder does not match pos' raise HardwareError(self._blocking_error) sm.mismatch_count += 1 return Retry self.saveParameters() return self.final_status(IDLE, '') @status_code(BUSY) def stopping(self, sm): if self._running: return Retry return self.final_status(IDLE, 'stopped') @Command def stop(self): self.get('S') self.start_machine(self.stopping, status=(BUSY, 'stopping')) @Command def clear_errors(self): """Reset error, set position to encoder""" self.read_value() if self._blocking_error: newenc = enc = self.read_encoder() pos = self.value if abs(enc - pos) > self.encoder_tolerance or self.encoder_mode == 'NO': if self.circumference: # bring encoder value either within or as close as possible to the given range if enc < self.target_min: mid = self.target_min + 0.5 * min(self.target_max - self.target_min, self.circumference) elif enc > self.target_max: mid = self.target_max - 0.5 * min(self.target_max - self.target_min, self.circumference) else: mid = enc newenc += round((mid - enc) / self.circumference) * self.circumference if newenc != enc and self.encoder_mode != 'NO': self.log.info(f'enc {enc} -> {newenc}') self.set('P22S', newenc * self.sign) if newenc != pos: self.log.info(f'pos {pos} -> {newenc}') self.set('P20S', newenc * self.sign) # set pos to encoder self.read_value() self.status = 'IDLE', 'after error reset' self._blocking_error = None self.target = self.value # clear error in target