def dev_write(self, *args):
try:
self.dev_sleep()
return TCPModbusClient.dev_write(self.serverloc[0],
self.serverloc[1],
self.modbus_addr, *args)
except:
return None
def read_scale(self, modbus_addr):
"""Read the scale register on a dent"""
self.modbus_addr = modbus_addr
response = self.dev_read(self.scale_register, 3)
data = [(TCPModbusClient.get_val(response.modbus_reg_val, i) & 0xffff)
for i in range(0, response.modbus_val_bytes / 2)]
if len(data) != 3:
return None
# return the scaling indicator expressed by the dent
return data[1]
def read_scale(self, modbus_addr):
"""Read the scale register on a dent"""
self.modbus_addr = modbus_addr
response = self.dev_read(self.scale_register, 3)
data = [(TCPModbusClient.get_val(response.modbus_reg_val, i) & 0xffff)
for i in range(0, response.modbus_val_bytes / 2)]
if len(data) != 3:
return None
# return the scaling indicator expressed by the dent
return data[1]
class VerisMeter:
all_meters = range(1, 43)
register_map = {
'current_scale': (1000, 1041),
'power_scale': (1042, 1083),
'energy_scale': (1084, 1125),
'kwh': (1168, 1251),
'kwh_fl': (2000, 2083),
'kw': (1252, 1293),
'pf': (1294, 1335),
'current': (1336, 1377),
'pkw': (1378, 1419),
'maxkw': (1420, 1461),
'pcurrent': (1462, 1503),
'maxcurrent': (1504, 1545),
'reset': (1126, 1167),
}
val_clear_kw = 10203
val_clear_max = 29877
def __init__(self, server, port, bus_addr):
self.server = server
self.port = port
self.bus_addr = bus_addr
self.logger = logging.getLogger('VerisMeter')
self.last_reading_time = 0.0
self.last_reset_energy = None
self.last_reset_time = 0.0
self.boot_time = time.time()
def get_current(self):
values = self.read_reg_range(self.register_map['current'])
scales = self.read_reg_range(self.register_map['current_scale'])
return self.scale_vals(values, scales)
def get_power(self):
values = self.read_reg_range(self.register_map['kw'])
scales = self.read_reg_range(self.register_map['power_scale'])
return self.scale_vals(values, scales)
def get_powerfactor(self):
values = self.read_reg_range(self.register_map['pf'])
scales = [-3] * len(values)
return self.scale_vals(values, scales)
def get_energy_totals(self):
values_16bit = self.read_reg_range(self.register_map['kwh'])
scale = self.read_reg_range(self.register_map['energy_scale'])
values = []
for i in range(0, len(values_16bit) / 2):
values.append(((values_16bit[i * 2] & 0xffff) << 16)
| (values_16bit[i * 2 + 1] & 0xffff))
return self.scale_vals(values, scale)
def get_energy(self, current=None):
if not current:
current = self.get_energy_totals()
if not self.last_reset_energy:
return current
return map(lambda x, y: x - y, current, self.last_reset_energy)
def reset_energy(self, vals=None):
# reset doesn't seem to work reliably -- just remember what it was last time
if not vals:
newvals = self.get_energy_totals()
else:
newvals = vals
self.last_reset_time = time.time()
self.last_reset_energy = newvals
def scale_vals(self, vals, scale):
return map(lambda x, y: x * (10**y), vals, scale)
def read_reg_range(self, (start, end)):
start -= 1
end -= 1
if end < start:
self.logger.error("read_reg_range: invalid range: (%i, %i)" %
(start, end))
return None
self.logger.debug("read_reg_range: %i:%i" % (start, end))
now = time.time()
if now - self.last_reading_time < 2:
time.sleep(2 - (now - self.last_reading_time))
response = TCPModbusClient.dev_read(self.server, self.port,
self.bus_addr, start,
end - start + 1)
self.last_reading_time = time.time()
self.logger.debug("read_reg_range: %i response bytes",
response.modbus_val_bytes)
return [
TCPModbusClient.get_val(response.modbus_reg_val, i)
for i in range(0, response.modbus_val_bytes / 2)
]
def update(self, elt, scale, modbus_addr):
self.modbus_addr = modbus_addr
response = self.dev_read(4000, 70)
time.sleep(2)
data = [(TCPModbusClient.get_val(response.modbus_reg_val, i) & 0xffff)
for i in range(0, response.modbus_val_bytes / 2)]
if len(data) != 70:
print "Short read from", self.serverloc, modbus_addr
return
reading_time = int(time.time())
base = '/%s' % elt
self.add(base + '/ABC/true_energy', reading_time,
float(self.to_word(data[0:2])) / e_d(scale))
self.add(base + '/ABC/reactive_energy', reading_time,
float(self.to_word(data[7:9])) / e_d(scale))
self.add(base + '/ABC/apparent_energy', reading_time,
float(self.to_word(data[10:12])) / e_d(scale))
self.add(base + '/ABC/true_power', reading_time,
float(data[2]) / e_d(scale))
# min=data[6], max=data[5]))
self.add(base + '/ABC/reactive_power', reading_time,
float(data[9]) / e_d(scale))
self.add(base + '/ABC/apparent_power', reading_time,
float(data[12]) / e_d(scale))
self.add(base + '/ABC/displacement_pf', reading_time,
float(data[13]) / 100)
self.add(base + '/ABC/apparent_pf', reading_time,
float(data[14]) / 100)
self.add(base + '/ABC/current', reading_time,
float(data[15]) / c_d(scale))
# line frequency divisor is not in the datasheet, but called Dent to verify 3-26-2010
self.add(base + '/ABC/line_frequency', reading_time,
float(data[21]) / 100)
self.add(base + '/AB/volts', reading_time,
float(data[18]) / v_d(scale))
self.add(base + '/BC/volts', reading_time,
float(data[19]) / v_d(scale))
self.add(base + '/AC/volts', reading_time,
float(data[20]) / v_d(scale))
def w_i(d, i):
return d[i] | (d[i+1] << 16)
for (i,v) in [(0,'A'), (1,'B'), (2,'C')]:
base = '/%s/%s/' % (elt, v)
self.add(base + 'true_energy', reading_time,
float(w_i(data, 22+(i*2))) / e_d(scale))
self.add(base + 'reactive_energy', reading_time,
float(w_i(data, 31+(i*2))) / e_d(scale))
self.add(base + 'apparent_energy', reading_time,
float(w_i(data, 40+(i*2))) / e_d(scale))
self.add(base + 'true_power', reading_time,
float(data[28+i]) / e_d(scale))
self.add(base + 'reactive_power', reading_time,
float(data[37+i]) / e_d(scale))
self.add(base + 'apparent_power', reading_time,
float(data[46+i]) / e_d(scale))
self.add(base + 'displacement_pf', reading_time,
float(data[49+i]) / 100)
self.add(base + 'apparent_pf', reading_time,
float(data[52+i]) / 100)
self.add(base + 'current', reading_time,
float(data[55+i]) / c_d(scale))
self.add(base + 'phase-neutral_voltage', reading_time,
float(data[58+i]) / v_d(scale))
def dev_write(self, *args):
try:
self.dev_sleep()
return TCPModbusClient.dev_write(self.serverloc[0], self.serverloc[1],self.modbus_addr,*args)
except:
return None
def update(self, elt, scale, modbus_addr):
self.modbus_addr = modbus_addr
response = self.dev_read(4000, 70)
time.sleep(2)
data = [(TCPModbusClient.get_val(response.modbus_reg_val, i) & 0xffff)
for i in range(0, response.modbus_val_bytes / 2)]
if len(data) != 70:
print "Short read from", self.serverloc, modbus_addr
return
reading_time = int(time.time())
base = '/%s' % elt
self.add(base + '/ABC/true_energy', reading_time,
float(self.to_word(data[0:2])) / e_d(scale))
self.add(base + '/ABC/reactive_energy', reading_time,
float(self.to_word(data[7:9])) / e_d(scale))
self.add(base + '/ABC/apparent_energy', reading_time,
float(self.to_word(data[10:12])) / e_d(scale))
self.add(base + '/ABC/true_power', reading_time,
float(data[2]) / e_d(scale))
# min=data[6], max=data[5]))
self.add(base + '/ABC/reactive_power', reading_time,
float(data[9]) / e_d(scale))
self.add(base + '/ABC/apparent_power', reading_time,
float(data[12]) / e_d(scale))
self.add(base + '/ABC/displacement_pf', reading_time,
float(data[13]) / 100)
self.add(base + '/ABC/apparent_pf', reading_time,
float(data[14]) / 100)
self.add(base + '/ABC/current', reading_time,
float(data[15]) / c_d(scale))
# line frequency divisor is not in the datasheet, but called Dent to verify 3-26-2010
self.add(base + '/ABC/line_frequency', reading_time,
float(data[21]) / 100)
self.add(base + '/AB/volts', reading_time,
float(data[18]) / v_d(scale))
self.add(base + '/BC/volts', reading_time,
float(data[19]) / v_d(scale))
self.add(base + '/AC/volts', reading_time,
float(data[20]) / v_d(scale))
def w_i(d, i):
return d[i] | (d[i + 1] << 16)
for (i, v) in [(0, 'A'), (1, 'B'), (2, 'C')]:
base = '/%s/%s/' % (elt, v)
self.add(base + 'true_energy', reading_time,
float(w_i(data, 22 + (i * 2))) / e_d(scale))
self.add(base + 'reactive_energy', reading_time,
float(w_i(data, 31 + (i * 2))) / e_d(scale))
self.add(base + 'apparent_energy', reading_time,
float(w_i(data, 40 + (i * 2))) / e_d(scale))
self.add(base + 'true_power', reading_time,
float(data[28 + i]) / e_d(scale))
self.add(base + 'reactive_power', reading_time,
float(data[37 + i]) / e_d(scale))
self.add(base + 'apparent_power', reading_time,
float(data[46 + i]) / e_d(scale))
self.add(base + 'displacement_pf', reading_time,
float(data[49 + i]) / 100)
self.add(base + 'apparent_pf', reading_time,
float(data[52 + i]) / 100)
self.add(base + 'current', reading_time,
float(data[55 + i]) / c_d(scale))
self.add(base + 'phase-neutral_voltage', reading_time,
float(data[58 + i]) / v_d(scale))
