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23 Commits

Author SHA1 Message Date
Roy 991f5d06ea [update] use 4hstia calibration down 2023-04-06 09:06:05 +08:00
Roy 614a9c0b0f [update] hstia pA->nA & hsrtia_b is 8bytes 2023-03-31 10:16:50 +08:00
Roy 22eb8a09f4 [update] fix hsrtia_a & hsrtia_b & hsrtia_c Negative number error 2023-03-22 16:52:40 +08:00
Roy dbd7431124 [update] hsrtia_a & hsrtia_b & hsrtia_c receive from elite is 5bytes 2023-03-22 13:39:14 +08:00
Roy 15c15275a7 [update] update AC_AMP defalut value 2023-03-21 16:04:27 +08:00
Roy 836d75b77e [update] new idle mode (eis1.0) 2023-03-21 16:02:49 +08:00
Roy 417bdd91a4 [update] update librery parameter:CA_VOLT 2023-03-08 10:09:06 +08:00
Roy 62ee763e2c [update] update EDC decoder 2023-03-07 17:55:00 +08:00
Roy 44e9e4cb67 [update] update BAT library 2023-03-07 17:43:41 +08:00
Roy 38537563fd [update] new idle mode 2023-01-09 17:27:03 +08:00
Roy 375372996d [update] update TRIG local name pattern 2023-01-07 16:55:03 +08:00
Roy d79491db8b [update] optimize connection 2023-01-07 11:00:44 +08:00
peterlu14 5a35da98ac [update] trigger json add parameter TIME_DURATION 2023-01-03 15:31:55 +08:00
peterlu14 9c054bd733 [update] change table name project_report -> project_reports & project_meta -> project_metas 2022-12-28 13:21:00 +08:00
peterlu14 64412f9376 [update] change meta_project_info to project_meta & alter table project_meta column cycle type string to jsonb 2022-12-28 11:13:37 +08:00
peterlu14 97034d6b32 [update] remove README $ text & add apache2 install 2022-12-22 09:39:44 +00:00
peterlu14 f065bad826 delete db first controller info 2022-12-20 11:31:35 +08:00
peterlu14 9c1dafd003 [debug] fix create project log error 2022-12-19 11:06:53 +08:00
Roy 03443ada99 [update] take EIS_AC_AMP parameter error 2022-12-07 14:20:30 +08:00
Roy 17dc5470e7 Merge remote-tracking branch 'origin/dev/scheduler_log' into dev/fix_Amp_cali 2022-12-02 17:44:13 +08:00
peterlu14 695f37c2dd [update] gitignore log 2022-12-01 15:18:47 +08:00
peterlu14 690f859e86 [update] idle fix & scheduler log & cycle count 2022-12-01 15:18:04 +08:00
Roy 0ed4d0594a [update] print something 2022-11-29 14:44:00 +08:00
22 changed files with 2030 additions and 251 deletions
+1
View File
@@ -7,3 +7,4 @@
/.vscode
/media
python/biopro/sever/_identify.py
*.log
+34 -27
View File
@@ -158,8 +158,8 @@ reboot
###### Set pi password
```
$cd ~
$passwd
cd ~
passwd
Current password:raspberry
New password:5k6zj454778225
Retype new password:5k6zj454778225
@@ -198,11 +198,11 @@ exit 0
### MQTT broker install
###### 1.Install mosquitto
$sudo apt-get install mosquitto mosquitto-clients
sudo apt-get install mosquitto mosquitto-clients
###### 2.Enable Remote Access
$sudo vim /etc/mosquitto/conf.d/default.conf
sudo vim /etc/mosquitto/conf.d/default.conf
add the code following as:
```
@@ -213,13 +213,13 @@ protocol websockets
allow_anonymous true
```
###### 3.restart mqtt broker
$sudo systemctl restart mosquitto
sudo systemctl restart mosquitto
###### 4.Robust MQTT
create mosquitto_restart.sh
$cd ~
$sudo vim mosquitto_restart.sh
cd ~
sudo vim mosquitto_restart.sh
add the code following as:
@@ -236,16 +236,16 @@ echo "$SERVICE is currently running" >> /home/ubuntu/cron.log
exit 0
```
###### 5.add mosquitto_restart.sh to root routing
$sudo chmod +x mosquitto_restart.sh
$sudo -i
$crontab -e
sudo chmod +x mosquitto_restart.sh
sudo -i
crontab -e
add the code following as:
```
*/5 * * * * /home/pi/mosquitto_restart.sh
```
###### 6.Auto run MQTT broker when when pi-start
$sudo vim /etc/rc.local
sudo vim /etc/rc.local
add the code following as:
```
@@ -254,31 +254,31 @@ sudo nohup systemctl restart mosquitto
### Setting up a Routed Wireless Access Point
###### 1.Install AP and Management Software
$sudo apt install hostapd
$sudo systemctl unmask hostapd
$sudo systemctl enable hostapd
$sudo apt install dnsmasq
$sudo DEBIAN_FRONTEND=noninteractive apt install -y netfilter-persistent iptables-persistent
sudo apt install hostapd
sudo systemctl unmask hostapd
sudo systemctl enable hostapd
sudo apt install dnsmasq
sudo DEBIAN_FRONTEND=noninteractive apt install -y netfilter-persistent iptables-persistent
###### 2.Set up the Network Router
$sudo nano /etc/dhcpcd.conf
sudo nano /etc/dhcpcd.conf
```
interface wlan0
static ip_address=192.168.2.1/24
nohook wpa_supplicant
```
$sudo nano /etc/sysctl.d/routed-ap.conf
sudo nano /etc/sysctl.d/routed-ap.conf
```
# Enable IPv4 routing
net.ipv4.ip_forward=1
```
$sudo iptables -t nat -A POSTROUTING -o eth0 -j MASQUERADE
$sudo netfilter-persistent save
$sudo mv /etc/dnsmasq.conf /etc/dnsmasq.conf.orig
sudo iptables -t nat -A POSTROUTING -o eth0 -j MASQUERADE
sudo netfilter-persistent save
sudo mv /etc/dnsmasq.conf /etc/dnsmasq.conf.orig
$sudo nano /etc/dnsmasq.conf
sudo nano /etc/dnsmasq.conf
```
interface=wlan0 # Listening interface
@@ -289,10 +289,10 @@ address=/gw.wlan/192.168.2.1
# Alias for this router
```
###### 3.Ensure Wireless Operation
$sudo rfkill unblock wlan
sudo rfkill unblock wlan
###### 4.Configure the AP Software
$sudo nano /etc/hostapd/hostapd.conf
sudo nano /etc/hostapd/hostapd.conf
```
country_code=TW
@@ -317,11 +317,13 @@ wme_enabled=1
ht_capab=[HT40+][SHORT-GI-40]
```
###### 5.Running the new Wireless AP
$sudo systemctl reboot
sudo systemctl reboot
### Install Apache2
sudo apt install apache2
### Set web site
$sudo vim ./sites-available/000-default.conf
### Deploy web site
sudo vim /etc/apache2/sites-available/000-default.conf
```
<VirtualHost *:8080> #80------>8080
# The ServerName directive sets the request scheme, hostname and port that
@@ -363,6 +365,11 @@ $sudo vim ./sites-available/000-default.conf
> https://www.raspberrypi.org/documentation/configuration/wireless/access-point-routed.md
# ChangeLog
[2022.12.28]
change meta_project_info to project_metas
change project_report to project_reports
alter table project_meta column cycle type string to jsonb
[2022.11.16]
add python package SQLAlchemy
add new column project(int4) in postgresSQL table recording_meta_datas
@@ -6,11 +6,11 @@ from sqlalchemy.dialects.postgresql import JSONB
from .base import Base
class MetaProjectInfo(Base):
__tablename__ = "meta_project_info"
__tablename__ = "project_metas"
id = Column(Integer, primary_key=True)
project = Column(String(36))
cycle = Column(String)
cycle = Column(JSONB)
task = Column(JSONB)
serial_number = Column(Integer)
deleted = Column(Boolean, default = False)
+1 -1
View File
@@ -6,7 +6,7 @@ from sqlalchemy.dialects.postgresql import JSONB
from .base import Base
class ProjectReport(Base):
__tablename__ = "project_report"
__tablename__ = "project_reports"
id = Column(Integer, primary_key=True)
name = Column(String)
+5 -15
View File
@@ -660,7 +660,7 @@ class CC2650Device(Device):
break
elif device_type == 'EISZeroOne':
i = 0
i = 1
request_times = 0
while i < 13:
try:
@@ -2177,23 +2177,12 @@ class CC2650SingleMasterCentralDevice(CC2650MasterDevice, Synchronized):
else:
for dev in self._found:
if dev.mac_address == address:
# send device mac and addrType
try:
# print('send_connect',bytes(connect_ins))
self._cc2650.send("bytes", bytes(connect_ins))
except SerialTimeoutException as e:
raise RecvTimeout('device CC2650 connect fail') from e
else:
sleep(2)
# connection establish done?
for retry_recv_ack in range(5):
self._cc2650.send("bytes", bytes((0, 0, 0, 0)))
try:
# send device mac and addrType
self._cc2650.send("bytes", bytes(connect_ins))
sleep(1.5)
con_done = self._cc2650.recv_uart(timeout = 0.1)
except RecvTimeout:
@@ -2202,6 +2191,7 @@ class CC2650SingleMasterCentralDevice(CC2650MasterDevice, Synchronized):
# is the ack valid?
if con_done is None:
self.log_info("recv connection timeout, retry... ")
continue
elif con_done[0] is 46 and \
+1 -1
View File
@@ -856,7 +856,7 @@ class DeviceManager(MasterDevice, Synchronized):
def _idle(self, device: Device, expr: AnyStr):
self._handler.device_internal_command(device.device_id,
'idle',
InternalInstruction.PREDEFINED_IDLE,
None)
def _device_data_format_cali(self, device: Device, expr: str, cali: bytes = None):
+195 -167
View File
@@ -884,20 +884,54 @@ class I4V4Z4T4DataDecoder(RecDataDecoder):
def decode(self, data: bytes) -> Optional[RecordingData]:
if len(data) < 18:
return None
voltage = 0
mem_cnt = data[1]
time_stamp: float = struct.unpack('<I', data[4:8])[0] # unit: ms 0x18030000
current = struct.unpack('<i', data[8:12])[0] # unit: nA
voltage = struct.unpack('<i', data[12:16])[0] # unit: uV
impedance = struct.unpack('<i', data[16:20])[0] # unit: mOm
#/* Elite Notify data:
# * +--------+----------+---------+---------+---------+-----------+-----------------+
# * | id(1B) | time(4B) | ch1(4B) | ch2(4B) | ch3(4B) | cycle(2B) | finish_flag(1B) |
# * | bat(4B) | notify#(1B) | ch4(4B) | ch5(4B) | ch6(4B) | __(3B) |
# * +---------+-------------+---------+---------+---------+--------+
# */
#/*
# * EliteADCControl(): use ADC plot, and send what data to controller
# * +---------------------------+-----------+-----------+-----------+-----------+-----------+
# * | MODE | ch1 | ch2 | ch3 | cycle | ch4 |
# * +---------------------------+-----------+-----------+-----------+-----------+-----------+
# * | CURVE_IV | Iin | Vout | Vin | | Vmon |
# * | CURVE_IV_CY | Iin | Vout | Vin | v | Vmon |
# * | CURVE_VO | Iin | Vout | Vin | | Vmon |
# * | CURVE_RT | Iin | Vout | R | | Vmon |
# * | CURVE_VT | Iin | Vin | | | |
# * | CURVE_IT | Iin | Vin | Vout | | Vmon |
# * | CURVE_CC | Iin | Vin | Vout | | Vmon |
# * | CURVE_CP | Iin | Vout-Vin | Vout | | Vmon |
# * | CURVE_CV | Iin | Vout-Vin | Vout | v | Vmon |
# * | CURVE_LSV | Iin | Vout-Vin | Vout | | Vmon |
# * | CURVE_CA | Iin | Vout-Vin | Vout | | Vmon |
# * | CURVE_OCP | Iin | Vmon-Vin | Vin | | Vmon |
# * | CURVE_UNI_PULSE | pul1_Iin | pul2_Iin | | | |
# * | CURVE_DPV | c1&c2_avg | Vout-Vin | Vout | | Vmon |
# * | CURVE_DPV_SMPRATE | Iin | Vout-Vin | Vout | | Vmon |
# * | CURVE_DPV_ADVANCE | c1&c2_avg | Vout-Vin | Vout | | Vmon |
# * | CURVE_DPV_ADVANCE_SMPRATE | Iin | Vout-Vin | Vout | | Vmon |
# * +---------------------------+-----------+-----------+-----------+-----------+-----------+
# *
# * ps. c1_avg = pul1_Iin
# * ps. c2_avg = pul2_Iin
# */
cycle_number = struct.unpack('<H', data[20:22])[0]
finish_mode_falg = data[22]
battery = struct.unpack('<i', data[23:27])[0]
elite_notify_times = data[27]
notify_one = struct.unpack('<i', data[28:32])[0]
notify_two = struct.unpack('<i', data[32:36])[0]
notify_three = struct.unpack('<i', data[36:40])[0]
mem_cnt = data[1]
time_stamp: float = struct.unpack('<I', data[1+3:5+3])[0]
ch1 = struct.unpack('<i', data[5+3:9+3])[0] # unit: nA
ch2 = struct.unpack('<i', data[9+3:13+3])[0] # unit: uV
ch3 = struct.unpack('<i', data[13+3:17+3])[0] # unit: mOm
cycle_number = struct.unpack('<H', data[17+3:19+3])[0]
finish_mode_falg = data[19+3]
battery = struct.unpack('<i', data[20+3:24+3])[0]
elite_notify_times = data[24+3]
ch4 = struct.unpack('<i', data[25+3:29+3])[0]
ch5 = struct.unpack('<i', data[29+3:33+3])[0]
ch6 = struct.unpack('<i', data[33+3:37+3])[0]
# self._show_data = True
mem_wrong_information = struct.unpack('<i', data[43:47])[0] # mem_wrong_information = green retry, green wrong, red retry, red wrong
@@ -924,25 +958,29 @@ class I4V4Z4T4DataDecoder(RecDataDecoder):
else:
if self._show_data:
print('|', time_stamp, '|', delta, '|', int(time_stamp * 1000 / 2),
'|', current, '|', voltage, '|', impedance, '|', cycle_number,
'|', notify_one, '|', notify_two, '|', notify_three,
'|', finishMode, '@', str(self.device))
'|', ch1, '|', ch2, '|', ch3, '|', cycle_number,
'|', ch4, '|', ch5, '|', ch6,
'|', finishMode, '@', str(self.device), flush = True)
# print('|', '{:10}'.format(time_stamp),
# '|', '{:4}'.format(delta),
# '|', '{:10}'.format(int(time_stamp * 1000 / 2)),
# '|', '{:10}'.format(current),
# '|', '{:10}'.format(voltage),
# '|', '{:10}'.format(impedance),
# '|', '{:5}'.format(cycle_number),
# '|', '{:1}'.format(finishMode),
# '@', str(self.device), '|')
# print('|', '{:10}'.format(time_stamp),
# '|', '{:4}'.format(delta),
# '|', '{:10}'.format(int(time_stamp * 1000 / 2)), #[usec]
# '|', '{:10}'.format(ch1), #[nA]
# '|', '{:10}'.format(ch2), #[uV]
# '|', '{:10}'.format(ch3),
# '|', '{:5}'.format(cycle_number),
# '|', '{:10}'.format(ch4), #Voutin[uV]
# '|', '{:10}'.format(ch5),
# '|', '{:10}'.format(ch6),
# '|', '{:5}'.format(battery), #[mV]
# '|', '{:4}'.format(elite_notify_times),
# '|', '{:1}'.format(finishMode),
# '@', str(self.device), '|', flush = True)
# print('|', '{:5}'.format(mem_wrong_information),
# '|', '{:2}'.format(ram_num),
# '|', '{:2}'.format(broken_flag),
# '@', str(self.device), '|')
pass
# print('|', '{:5}'.format(mem_wrong_information),
# '|', '{:2}'.format(ram_num),
# '|', '{:2}'.format(broken_flag),
# '@', str(self.device), '|')
if finishMode == True:
print("finishMode full data:", list(data), datetime.now())
@@ -951,13 +989,13 @@ class I4V4Z4T4DataDecoder(RecDataDecoder):
self._mode_stop = 0
ret = RecordingData(self.device, int(time_stamp * 1000 / 2), 0)
ret.append_data(0, current)
ret.append_data(1, voltage)
ret.append_data(2, impedance)
ret.append_data(0, ch1)
ret.append_data(1, ch2)
ret.append_data(2, ch3)
ret.append_data(3, cycle_number)
ret.append_data(4, notify_one)
ret.append_data(5, notify_two)
ret.append_data(6, notify_three)
ret.append_data(4, ch4)
ret.append_data(5, ch5)
ret.append_data(6, ch6)
# ret.append_data(4, battery)
# ret.append_data(5, elite_notify_times)
# ret.append_data(6, mem_cnt)
@@ -1360,7 +1398,6 @@ class EISZeroOneDataDecoder(RecDataDecoder):
self._mode_stop = 0
self._cycle_start_time = []
self._ac_amp: int = 0
self._mode: int = 0
self._last_phase = 0
self._first_phase_flag = 1
@@ -1377,16 +1414,13 @@ class EISZeroOneDataDecoder(RecDataDecoder):
@staticmethod
def _decode_cali_coeff(cali_coeff: bytes) -> Optional[List[Tuple[int, int]]]:
if cali_coeff != b'':
cis_data_len = 20
cali_table = []
hsrtia_a = []
hsrtia_b = []
hsrtia_c = []
hsrtia_d = []
rolloff = []
phase_coeff = []
phase_offset = []
# phase_coeff = [[0]*4 for i in range(4)]
# phase_offset = [[0]*4 for i in range(4)]
phase_coeff = numpy.zeros([4, 4], dtype = int)
phase_offset = numpy.zeros([4, 4], dtype = int)
@@ -1400,104 +1434,107 @@ class EISZeroOneDataDecoder(RecDataDecoder):
# ]
#######################################
# print('cali_coeff', cali_coeff)
cutoff_freq = struct.unpack('>I', cali_coeff[1:5])[0] * 100 #4
# temp = struct.unpack('>B', cali_coeff[5:6])[0] #1
# hsrtia_200r = struct.unpack('>B', cali_coeff[6:7])[0] #1
# hsrtia_5k = struct.unpack('>H', cali_coeff[7:9])[0] #2
# hsrtia_20k = struct.unpack('>H', cali_coeff[6:8])[0] #2
# hsrtia_160k = struct.unpack('>I', cali_coeff[8:12])[0] #4
#Lv[0] 160k
cis_cali_packet = 1
index = (cis_cali_packet - 1) * cis_data_len
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0])
hsrtia_b.append(struct.unpack('>q', cali_coeff[index+5:index+13])[0])
rolloff.append(struct.unpack('>i', cali_coeff[index+13:index+17])[0])
index = 20
cis_cali_packet = 2
index = (cis_cali_packet - 1) * cis_data_len
g = 0
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 40
cis_cali_packet = 3
index = (cis_cali_packet - 1) * cis_data_len
g = 0
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
#Lv[0] 160k
index = 60
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0]/1e8)
hsrtia_b.append(struct.unpack('>i', cali_coeff[index+5:index+9])[0]/1e8)
hsrtia_c.append(struct.unpack('>i', cali_coeff[index+9:index+13])[0])
#Lv[1] 20k
index = 80
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0]/1e8)
hsrtia_b.append(struct.unpack('>i', cali_coeff[index+5:index+9])[0]/1e8)
hsrtia_c.append(struct.unpack('>i', cali_coeff[index+9:index+13])[0])
cis_cali_packet = 4
index = (cis_cali_packet - 1) * cis_data_len
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0])
hsrtia_b.append(struct.unpack('>q', cali_coeff[index+5:index+13])[0])
rolloff.append(struct.unpack('>i', cali_coeff[index+13:index+17])[0])
cis_cali_packet = 5
index = (cis_cali_packet - 1) * cis_data_len
g = 1
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
cis_cali_packet = 6
index = (cis_cali_packet - 1) * cis_data_len
g = 1
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
#Lv[2] 5k
index = 100
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0]/1e8)
hsrtia_b.append(struct.unpack('>i', cali_coeff[index+5:index+9])[0]/1e8)
hsrtia_c.append(struct.unpack('>i', cali_coeff[index+9:index+13])[0])
cis_cali_packet = 7
index = (cis_cali_packet - 1) * cis_data_len
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0])
hsrtia_b.append(struct.unpack('>q', cali_coeff[index+5:index+13])[0])
rolloff.append(struct.unpack('>i', cali_coeff[index+13:index+17])[0])
cis_cali_packet = 8
index = (cis_cali_packet - 1) * cis_data_len
g = 2
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
cis_cali_packet = 9
index = (cis_cali_packet - 1) * cis_data_len
g = 2
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
#Lv[3] 200R
index = 120
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0]/1e8)
hsrtia_b.append(struct.unpack('>i', cali_coeff[index+5:index+9])[0]/1e8)
hsrtia_c.append(struct.unpack('>i', cali_coeff[index+9:index+13])[0])
cis_cali_packet = 10
index = (cis_cali_packet - 1) * cis_data_len
hsrtia_a.append(struct.unpack('>i', cali_coeff[index+1:index+5])[0])
hsrtia_b.append(struct.unpack('>q', cali_coeff[index+5:index+13])[0])
rolloff.append(struct.unpack('>i', cali_coeff[index+13:index+17])[0])
index = 140
g = 1
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 160
g = 1
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 180
g = 2
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 200
g = 2
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 220
cis_cali_packet = 11
index = (cis_cali_packet - 1) * cis_data_len
g = 3
phase_coeff[0][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[0][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[1][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[1][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
index = 240
cis_cali_packet = 12
index = (cis_cali_packet - 1) * cis_data_len
g = 3
phase_coeff[2][g] = struct.unpack('>i', cali_coeff[index+1:index+5])[0]
phase_offset[2][g] = struct.unpack('>i', cali_coeff[index+5:index+9])[0]
phase_coeff[3][g] = struct.unpack('>i', cali_coeff[index+9:index+13])[0]
phase_offset[3][g] = struct.unpack('>i', cali_coeff[index+13:index+17])[0]
# print('cutoff_freq', cutoff_freq)
# print('hsrtia_a', hsrtia_a)
# print('hsrtia_b', hsrtia_b)
# print('hsrtia_c', hsrtia_c)
# print('phase_coeff')
# print(phase_coeff)
# print('phase_offset')
# print(phase_offset)
print('hsrtia_a', hsrtia_a)
print('hsrtia_b', hsrtia_b)
print('rolloff', rolloff)
print('phase_coeff')
print(phase_coeff)
print('phase_offset')
print(phase_offset)
cali_table.append((cutoff_freq, phase_coeff, phase_offset, hsrtia_a, hsrtia_b, hsrtia_c, hsrtia_d))
cali_table.append((phase_coeff, phase_offset, hsrtia_a, hsrtia_b, rolloff))
return cali_table
else:
@@ -1528,8 +1565,13 @@ class EISZeroOneDataDecoder(RecDataDecoder):
cycle_number = struct.unpack('>H', data[17+3:19+3])[0]
d19 = data[19+3]
gain = data[20+3]
finishMode = (d19 & 0x80) >> 7
finishMode = (d19 & 0x80) >> 7
ch4 = struct.unpack('<i', data[21+3:25+3])[0] # Amp[uV]
notify_one = struct.unpack('<i', data[25+3:29+3])[0]
notify_two = struct.unpack('<i', data[29+3:33+3])[0]
notify_three = struct.unpack('<i', data[33+3:37+3])[0]
if time_stamp == 0:
self._start_return_data = True
@@ -1549,39 +1591,23 @@ class EISZeroOneDataDecoder(RecDataDecoder):
if self.cali_coeff is not None and (self._mode == 0 or self._mode == 5):
hsrtia_a = []
hsrtia_b = []
hsrtia_c = []
hsrtia_d = []
cutoff_freq, phase_coeff, phase_offset, hsrtia_a, hsrtia_b, hsrtia_c, hsrtia_d = self.cali_coeff[0]
voltage_amp = round(self._ac_amp * 800 / 2047) # use UI value
rolloff = []
phase_coeff, phase_offset, hsrtia_a, hsrtia_b, rolloff = self.cali_coeff[0]
if (self._mode == 0 or self._mode == 5):
img = ch1
real = ch2
freq = ch3
fre_idx = 0
voltage_amp = round(ch4 / 1000) # Amp[mV]
rolloff_cali = rolloff[gain]
# rolloff_cali = cutoff_freq/1e5
rolloff_cali = hsrtia_c[gain]
voltage_mag = math.sqrt(img ** 2 + real ** 2) * (1 + freq ** 2 / rolloff_cali ** 2 / 1e4)
# if (gain == 3):
# current = hsrtia_a[gain] * math.exp(hsrtia_b[gain] * voltage_mag) + hsrtia_c[gain] * math.exp(hsrtia_d[gain] * voltage_mag)
# else:
current = (voltage_mag ** 2 * hsrtia_a[gain] + voltage_mag * hsrtia_b[gain]) / 1e8 #[nA]
current = voltage_mag ** 2 * hsrtia_a[gain] + voltage_mag * hsrtia_b[gain]
# current = voltage_mag ** 2 * hsrtia_a[gain] + voltage_mag * hsrtia_b[gain] + hsrtia_c[gain]
# print(current)
# print(voltage_mag)
# print(hsrtia_a[gain])
# print(hsrtia_b[gain])
# print(hsrtia_c[gain])
if (current != 0):
# impedance = voltage_amp * 1000_000 / 1.414213 / current
impedance = voltage_amp * 707106.78 / current
# impedance[mOhm] = voltage_amp[mv] * 1000000 / 1.414213 / current[nA] #RMS=amp*SQRT(2), SQRT(2)=1.414213
impedance = voltage_amp * 707106.78 / current
else:
impedance = 0
@@ -1600,37 +1626,33 @@ class EISZeroOneDataDecoder(RecDataDecoder):
phase = raw_phase - ideal_raw_phase
phase = phase % 180 if phase % 180<=90 else phase % 180-180
# last_phase_to90 = self._last_phase % 180 if self._last_phase % 180<=90 else self._last_phase % 180-180
# diff = phase - last_phase_to90
# if (self._first_phase_flag):
# # self._last_phase = phase
# self._first_phase_flag = 0
# elif (abs(diff) >= 90):
# phase = self._last_phase + diff + (180 if diff<0 else-180)
# else:
# phase = self._last_phase + diff
# self._last_phase = phase
imag_after_cal = impedance * math.sin(round(phase) * math.pi / 180)
real_after_cal = impedance * math.cos(round(phase) * math.pi / 180)
imag_after_cal = round(impedance * math.sin(phase * math.pi / 180))
real_after_cal = round(impedance * math.cos(phase * math.pi / 180))
if self._show_data:
if (self._mode == 0 or self._mode == 5):
print('|', '{:10}'.format(time_stamp),
'|', '{:5}'.format(delta),
'|', '{:6}'.format(ch1),
'|', '{:6}'.format(ch2),
'|', '{:8}'.format(ch3 / 100),
'|', '{:6}'.format(round(voltage_mag)),
'|', '{:5}'.format(int(imag_after_cal)),
'|', '{:5}'.format(int(real_after_cal)),
'|', '{:5}'.format(round(impedance)),
'|', '{:5}'.format(round(phase, 1)),
'|', '{:5}'.format(round(current, 3)),
'|', '{:1}'.format(gain),
'|', '{:1}'.format(finishMode),
'@', str(self.device), '|', flush = True)
'|', '{:5}'.format(delta),
'|', '{:5}'.format(ch1), #raw_img
'|', '{:5}'.format(ch2), #raw_real
'|', '{:8}'.format(ch3 * 10), '[mHz]', #Frequency [mHz]
'|', '{:5}'.format(cycle_number), #cycle
'|', '{:5}'.format(round(imag_after_cal)), '[Ohm]', #Z_imag [Ohm]
'|', '{:5}'.format(round(real_after_cal)), '[Ohm]', #Z_real [Ohm]
'|', '{:5}'.format(round(impedance)), '[Ohm]', #Impedance [Ohm]
'|', '{:5}'.format(round(phase*1000)), '[mdegree]', #Phase [millidegree]
'|', '{:5}'.format(round(current)), '[nA]', #Current [nA]
'|', '{:1}'.format(gain), #gain
'|', '{:1}'.format(finishMode), #finishMode
'@', str(self.device), '|', flush = True)
print('|', '{:10}'.format(time_stamp),
'|', '{:5}'.format(delta),
'|', '{:5}'.format(notify_one),
'|', '{:5}'.format(notify_two),
'|', '{:5}'.format(notify_three),
'|', '{:5}'.format(voltage_amp), #amp[mV]
'|', flush = True)
pass
else:
print('|', '{:10}'.format(time_stamp),
@@ -1651,17 +1673,23 @@ class EISZeroOneDataDecoder(RecDataDecoder):
self._mode_stop = 0
ret = RecordingData(self.device, int(time_stamp * 1000 / 2), 0)
if self._mode == 0 or self._mode == 5: #EIS Mode
ret.append_data(0, ch1) #Raw Imag
ret.append_data(1, ch2) #Raw Real
if self._mode == 0 or self._mode == 5:
ret.append_data(0, ch1) #raw_img
ret.append_data(1, ch2) #raw_real
ret.append_data(2, ch3 * 10) #Frequency [mHz]
ret.append_data(3, cycle_number)
ret.append_data(4, round(imag_after_cal)) #Z_imag [Ohm]
ret.append_data(5, round(real_after_cal)) #Z_real [Ohm]
ret.append_data(3, cycle_number) #cycle
ret.append_data(4, imag_after_cal) #Z_imag [Ohm]
ret.append_data(5, real_after_cal) #Z_real [Ohm]
ret.append_data(6, round(impedance)) #Impedance [Ohm]
ret.append_data(7, round(phase)) #Phase [degree]
ret.append_data(7, round(phase*1000)) #Phase [millidegree]
ret.append_data(8, round(current)) #Current [nA]
ret.append_data(9, gain) #Gain Level
ret.append_data(9, gain) #gain
#debug data
ret.append_data(10, notify_one)
ret.append_data(11, notify_two)
ret.append_data(12, notify_three)
ret.append_data(13, voltage_amp) #amp[mV]
else: #CV Mode
ret.append_data(0, ch1) #Iin [nA]
+34 -4
View File
@@ -1,6 +1,7 @@
import sys
import json
import threading
import logging
from time import time, sleep
from datetime import datetime
@@ -46,10 +47,20 @@ class Project(threading.Thread):
self._count = 1 #流水號
self.log_verbose = log_verbose
self._logger = logging.getLogger('project')
self._logger.setLevel('DEBUG')
self._formatter = logging.Formatter('[%(asctime)s.%(msecs)03d] %(message)s', datefmt='%Y-%m-%d %H:%M:%S')
self._formatter_with_nothing = logging.Formatter('%(message)s')
self.setup_project(project)
self.setup_device(self._device)
# create log file handler
fh = logging.FileHandler(f'/home/pi/logger/project/{self.uuid}.log', mode="w")
fh.setFormatter(self._formatter)
self._logger.addHandler(fh)
def setup_project(self, project):
for (key, value) in project.items():
if key in key_list.keys():
@@ -141,9 +152,19 @@ class Project(threading.Thread):
parameter_set = self._task_manager.running_task.parameter_set
return next((x for x in parameter_set if parameter_set[x]['target'] == device_address), None)
def get_cycle(self, task):
for index, _cycle in enumerate(self.cycle):
if task.uuid in _cycle['range']:
return _cycle
def run(self):
# project status change running (1)
self._status = 1
# save start time
self._start_time = time()
# saving & broadcast message
self._logger.info('Project ' + self.name + ' start')
self.log_verbose('Project ' + self.name + ' start')
self.mqtt_thread.broadcast_command('project:' + self._name + ' start at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
@@ -171,8 +192,12 @@ class Project(threading.Thread):
if action.type == 'cycle' and condition.type == 'previous_task_done':
self.mqtt_thread.broadcast_command('project:task ' + task.name + ' start at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
self._task_manager.set_running_task(task)
cycle_info = self.get_cycle(task)
if cycle_info['useID'] == False:
self._logger.info(f'---------- Cycle {task.name} Round {cycle_info["count"]} -----------')
if action.type == 'cycle' and condition.type == 'until_button_trigger':
self._task_manager.running_task.stop()
self._logger.info(f'---------- Cycle {cycle_info["id"]} Round {cycle_info["count"]} -----------')
if self._task_manager.running_task != None:
if self._task_manager.running_task.uuid == task.uuid and action.type == 'cycle' and condition.type == 'after_task_run':
@@ -181,6 +206,7 @@ class Project(threading.Thread):
if action.type == 'start':
if task.status != 1:
self._task_manager.set_running_task(task)
self._logger.info(f'Task {str(self._task_manager.running_task.name)} start')
self.mqtt_thread.broadcast_command('project:task ' + task.name + ' start at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
# elif action.type == 'stop':
# self.mqtt_thread.broadcast_command('project:task ' + str(self._task_manager.running_task.name) + ' stop at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
@@ -198,6 +224,7 @@ class Project(threading.Thread):
if action.target is not None:
device = self._complete_device[action.target]
if ((action.type == 'start' and device.status == 0) or (action.type == 'stop' and device.status == 1)):
self._logger.info(f'Device {device.mac_address_in_str} {action.type}')
self.log_verbose('Project' + self.name + 'Task ' + task.name + ' match_condition ' + condition.type + ' trigger_action ' + action.type + ' ' + str(action.target))
task_info = task.get_task_info(action)
instruction_set = getattr(self._instruction_set, action.type, None)
@@ -232,26 +259,28 @@ class Project(threading.Thread):
self.log_verbose('file name ' + task_info['file_name'])
if instruction_set != None and self.get_device_parameter_set(action.target) != None:
if action.type == 'start':
self._count += 1
for instruction in instruction_set:
print('instruction 1', device, instruction, datetime.now())
args = list(map(lambda arg: task_info[arg], instruction['arguments']))
target=getattr(device, instruction['method'])(*args)
print('instruction 2', device, instruction, datetime.now())
if action.type == 'start':
self._count += 1
delay_time += (time() - now)
# check task not running then stop
if self.check_running_task_not_run() == True:
# self._logger.info(f'taskType {self._task_manager.running_task.name} {self._task_manager.running_task.type}')
if self._task_manager.running_task.type == '':
self._logger.info(f'Task {self._task_manager.running_task.name} stop')
self.mqtt_thread.broadcast_command('project:task ' + str(self._task_manager.running_task.name) + ' stop at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
self._task_manager.running_task.stop()
# check project done then close project
if self.check_project_done() == True:
print('project stop at', datetime.now())
self.close()
self.stop()
if self._time_interval - delay_time > 0:
sleep(self._time_interval - delay_time)
@@ -268,6 +297,7 @@ class Project(threading.Thread):
self._status = 2
self._end_time = time()
self._stop_flag = True
self._logger.info('Project ' + self.name + ' stop')
self.mqtt_thread.broadcast_command('project:project ' + str(self._name) + ' stop at ' + datetime.now().strftime('%Y-%m-%d %H:%M:%S.%f')[:-3])
def close(self):
+15 -2
View File
@@ -56,6 +56,11 @@ class TaskManager():
def get_index_by_uuid(self, uuid):
return next((i for i, x in enumerate(self.task_list) if x.uuid == uuid), None)
def check_task_is_cycle_start(self, task):
for index, cycle in enumerate(self._cycle_list):
if cycle['range'][0] == task.uuid:
return index
def check_task_is_cycle_end(self, task):
for index, cycle in enumerate(self._cycle_list):
@@ -121,6 +126,7 @@ class TaskManager():
if self._prev_task.status == 1:
self._prev_task.stop()
# if reach cycle end, count < max, then go to cycle start
cycle_start_index = self.check_task_is_cycle_start(task)
cycle_index = self.check_task_is_cycle_end(task)
if cycle_index is None:
# print('next', self._running_task.name, self._running_task.next)
@@ -135,14 +141,21 @@ class TaskManager():
cycle = self._cycle_list[cycle_index]
if int(cycle['count']) < int(cycle['max']):
self._next_task.append(self.get_task_by_uuid(cycle['range'][0]))
cycle['count'] += 1
# cycle['count'] += 1
else:
for task_uuid in self._running_task.next:
_task = next((task for task in self._task_list if task.uuid == task_uuid), None)
if _task != None:
_task.reset()
self._next_task.append(_task)
cycle['count'] = 1
# cycle['count'] = 1
if cycle_start_index != None:
cycle = self._cycle_list[cycle_start_index]
if int(cycle['count']) < int(cycle['max']):
cycle['count'] += 1
else:
cycle['count'] = 1
except RuntimeError as e:
print(e)
+1 -1
View File
@@ -553,7 +553,7 @@ class DataBaseProcess(Process):
return True
def project_insert(self, device_id, _data):
sql_str = 'INSERT INTO "public"."meta_project_info" ('
sql_str = 'INSERT INTO "public"."project_metas" ('
sql_set = []
for item in _data.keys():
sql_str = sql_str + str(item) + ', '
+1 -1
View File
@@ -34,7 +34,7 @@ from biopro.api.device import DeviceAPI
from biopro.project.project_manager import ProjectManager
from biopro.db.base import Base, Session, engine
from biopro.db.project_report import ProjectReport
from biopro.db.meta_project_info import MetaProjectInfo
from biopro.db.project_meta import MetaProjectInfo
_RUNTIME_COMPILE = False
-1
View File
@@ -158,7 +158,6 @@ class RecordingProcess(Process):
elif isinstance(decoder, EISZeroOneDataDecoder):
# get amp_gain from meta file
decoder._mode = self._meta_file.configuration.get_parameter('MODE')
decoder._ac_amp = self._meta_file.configuration.get_parameter('EIS_AC_AMP')
return decoder
File diff suppressed because it is too large Load Diff
@@ -6,7 +6,7 @@
"major_product_number": 0,
"minor_product_number": 3,
"major_version_number": 1,
"minor_version_number": 0
"minor_version_number": 1
},
"constant": {
"TIME_MAX": 100000,
@@ -780,7 +780,7 @@
"expression": "VALUE"
}
},
"VOLT_VSCAN": {
"CA_VOLT": {
"description": "Voltage of VScan",
"record_meta": true,
"initial": 25000,
@@ -1301,7 +1301,7 @@
"curve_const_vscan": {
"type": "RIS",
"parameter": {
"va": "VOLT_VSCAN",
"va": "CA_VOLT",
"pa": "ADC_LEVEL_I_15",
"pb": "ADC_LEVEL_V_IN_15",
"pc": "DAC_LEVEL_V_OUT_15",
@@ -33,6 +33,7 @@
0,
1,
1,
1,
1
],
"domain": {
@@ -617,7 +618,8 @@
"Open Circuit Potential",
"Pulse Sensing",
"Differential Pulse Voltammetry (DPV)",
"Chronopotentiometry"
"Chronopotentiometry",
"Idle"
]
},
"VOLT_ORIGIN": {
@@ -818,7 +820,7 @@
"expression": "VALUE"
}
},
"VOLT_VSCAN": {
"CA_VOLT": {
"description": "Voltage of VScan",
"record_meta": true,
"initial": 25000,
@@ -949,6 +951,7 @@
"10": "cali_dac_test",
"11": "cali_adc_test",
"12": "",
"17": "idle",
"*": "start_data"
}
}
@@ -976,6 +979,9 @@
"VIS_STI",
"_cdr('1X;4X>ADC_VALUE_I')"
],
"idle": [
"_idle()"
],
"start_data": [
"data_format",
"_notify(True)",
@@ -1023,7 +1029,7 @@
"6": "const_current",
"7": "curve_cv3",
"8": "curve_lsv",
"9": "curve_const_vscan",
"9": "curve_ca",
"13": "curve_ocp",
"14": "curve_pulse_sensing",
"15": "curve_dpv",
@@ -1360,10 +1366,10 @@
"2B>pe"
]
},
"curve_const_vscan": {
"curve_ca": {
"type": "RIS",
"parameter": {
"va": "VOLT_VSCAN",
"va": "CA_VOLT",
"pa": "ADC_LEVEL_I_15",
"pb": "ADC_LEVEL_V_IN_15",
"pc": "DAC_LEVEL_V_OUT_15",
@@ -1,12 +1,12 @@
{
"name": "Elite_EDC_1.5r2",
"name": "Elite_EDC_1.5re",
"version": "1.2.30",
"match_rule": {
"local_name_pattern": "Elite.*",
"major_product_number": 0,
"minor_product_number": 2,
"major_version_number": 1,
"minor_version_number": 8
"minor_version_number": 7
},
"constant": {
"TIME_MAX": 100000,
@@ -33,6 +33,7 @@
0,
1,
1,
1,
1
],
"domain": {
@@ -617,7 +618,8 @@
"Open Circuit Potential",
"Pulse Sensing",
"Differential Pulse Voltammetry (DPV)",
"Chronopotentiometry"
"Chronopotentiometry",
"Idle"
]
},
"VOLT_ORIGIN": {
@@ -818,7 +820,7 @@
"expression": "VALUE"
}
},
"VOLT_VSCAN": {
"CA_VOLT": {
"description": "Voltage of VScan",
"record_meta": true,
"initial": 25000,
@@ -949,6 +951,7 @@
"10": "cali_dac_test",
"11": "cali_adc_test",
"12": "",
"17": "idle",
"*": "start_data"
}
}
@@ -976,6 +979,9 @@
"VIS_STI",
"_cdr('1X;4X>ADC_VALUE_I')"
],
"idle": [
"_idle()"
],
"start_data": [
"data_format",
"_notify(True)",
@@ -1023,7 +1029,7 @@
"6": "const_current",
"7": "curve_cv3",
"8": "curve_lsv",
"9": "curve_const_vscan",
"9": "curve_ca",
"13": "curve_ocp",
"14": "curve_pulse_sensing",
"15": "curve_dpv",
@@ -1360,10 +1366,10 @@
"2B>pe"
]
},
"curve_const_vscan": {
"curve_ca": {
"type": "RIS",
"parameter": {
"va": "VOLT_VSCAN",
"va": "CA_VOLT",
"pa": "ADC_LEVEL_I_15",
"pb": "ADC_LEVEL_V_IN_15",
"pc": "DAC_LEVEL_V_OUT_15",
@@ -820,7 +820,7 @@
"expression": "VALUE"
}
},
"VOLT_VSCAN": {
"CA_VOLT": {
"description": "Voltage of VScan",
"record_meta": true,
"initial": 25000,
@@ -1029,7 +1029,7 @@
"6": "const_current",
"7": "curve_cv3",
"8": "curve_lsv",
"9": "curve_const_vscan",
"9": "curve_ca",
"13": "curve_ocp",
"14": "curve_pulse_sensing",
"15": "curve_dpv",
@@ -1366,10 +1366,10 @@
"2B>pe"
]
},
"curve_const_vscan": {
"curve_ca": {
"type": "RIS",
"parameter": {
"va": "VOLT_VSCAN",
"va": "CA_VOLT",
"pa": "ADC_LEVEL_I_15",
"pb": "ADC_LEVEL_V_IN_15",
"pc": "DAC_LEVEL_V_OUT_15",
@@ -34,6 +34,7 @@
0,
1,
1,
1,
1
],
"domain": {
@@ -98,7 +99,8 @@
"V-T Graph",
"R-T Graph",
"EIS constant frequency",
"Dev Mode"
"Dev Mode",
"Idle"
]
},
"GENERAL_HS_RTIA": {
@@ -141,7 +143,7 @@
"EIS_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -213,7 +215,7 @@
"CF_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -370,10 +372,14 @@
{
"expression": "MODE",
"when": {
"7": "idle",
"*": "start_data"
}
}
],
"idle": [
"_idle()"
],
"start_data": [
"data_format_cali",
"_notify(True)",
@@ -143,7 +143,7 @@
"EIS_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -215,7 +215,7 @@
"CF_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -143,7 +143,7 @@
"EIS_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -215,7 +215,7 @@
"CF_AC_AMP": {
"description": "AC Amplitude",
"record_meta": true,
"initial": 25,
"initial": 26,
"domain": [
2048
]
@@ -2,16 +2,27 @@
"name": "Elite_TRIG_0.1",
"version": "1.2.30",
"match_rule": {
"local_name_pattern": "Trigger.*",
"local_name_pattern": "Elite.*",
"major_product_number": 0,
"minor_product_number": 5,
"major_version_number": 1,
"minor_version_number": 0
},
"constant": {
"TIME_MAX": 100000
},
"parameters": {
"TIME_DURATION": {
"description": "timer",
"record_meta": true,
"initial": 0,
"domain": [
"TIME_MAX"
],
"value": {
"expression": "VALUE"
}
},
"ACC_a_out0": {
"description": "Switch of analog current channel 1",
"record_meta": true,
@@ -142,7 +153,8 @@
"description": "working mode",
"record_meta": true,
"value": [
"Analog Current Control (ACC)"
"Analog Current Control (ACC)",
"Idle"
]
},
+15
View File
@@ -7,8 +7,23 @@ sudo apt-get install python3-numpy
# install python module SQLAlchemy
pip3 install SQLAlchemy
# create folder to save project logger
mkdir -p /home/pi/logger/project
# add column cycle in projects
sudo su -c "psql -d postgres -c \"ALTER TABLE projects ADD COLUMN IF NOT EXISTS cycle JSONB;\"" postgres
# add column project in recording_data_metas
sudo su -c "psql -d postgres -c \"ALTER TABLE recording_data_metas ADD COLUMN IF NOT EXISTS project Int4;\"" postgres
# remove default controller info
sudo su -c "psql -d postgres -c \"DELETE FROM controllers WHERE name='WTP_NONE';\"" postgres
# change table name from meta_project_info to project_metas
sudo su -c "psql -d postgres -c \"ALTER TABLE IF EXISTS meta_project_info RENAME TO project_metas;\"" postgres
# change table name from project_report to project_reports
sudo su -c "psql -d postgres -c \"ALTER TABLE IF EXISTS project_report RENAME TO project_reports;\"" postgres
# change table project_meta column cycle to type jsonb
sudo su -c "psql -d postgres -c \"ALTER TABLE project_metas ALTER COLUMN cycle type jsonb USING (cycle::jsonb);\"" postgres