Darian Johnson6/11/2017 -
I am still waiting for my LoRa sensors to arrive; in the meantime, I've started writing the logic that will interpret the sensor data. This code will run on the base station. The flow is:
- Base station requests sensor data
- Satellite station returns sensor values
- Base station interprets data and sends commands to satellite station
- Satellite station takes requested action (water compost, open vent, etc)
- Base station saves sensor data to database
- Base station saves UI data (warning colors, messages) to database for easy retrieval
The first pass of the code is below:
from datetime import timedelta, datetime
import json
def main:
# TODO implement
#return 'Hello from Lambda'
tempMessageArray = [
"Your compost is at optimal levels.", #0
"Your compost is ready for use. At your convenience, move your sensors to a new compost pile/layer.", #1
"Your compost heating cycle is complete and is in a 'curing stage'.", #2
"Your compost has reached an unsafe temperature. Immediately turn the compost and add water.", #3
"Your compost has reached unhealthily temperature. At your convenience, turn compost and add 'brown' (Carbon-rich) materials.", #4
"Your compost temperature is slightly higher than optimal. You may want to turn the compost and add 'brown' materials.", #5
"Your compost temperature is slightly higher than optimal, but is staring to cool off. I will let you know if any action is required.", #6
"Your compost is at optimal temperature.", #7
"Your compost temperature is slightly lower than optimal, but is staring to warm up. I will let you know if any action is required.", #8
"Your compost temperature is slightly lower than optimal, and is continuing to cool. At your convenience, turn compost and add 'green' (Nitrogen-rich) materials.", #9
"Your compost temperature is slightly lower than optimal, and is continuing to cool. The ambient temperature is low, so you should cover your compost to continue aerobic composting." #10
]
moistureMessageArray = [
"Your compost moisture content is too high. Turn your compost and add 'green' (Nitrogen-rich) materials.", #0
"Your compost moisture content is too high but is starting to dry out. I will let you know if any action is required.", #1
"Your compost is at optimal moisture levels.", #2
"Your compost moisture content is too dry, but is starting to reach optimal moisture. I will let you know if any action is required.", #3
"Your compost is too dry and requires your attention. You need to turn and water your compost." #4
]
#warnings
success = "alert alert-success"
info = "alert alert-info"
warning = "alert alert-warning"
danger = "alert alert-danger"
#Limits
tempDanger = 175
tempHigh = 160
tempOK = 140
tempLow = 90
moistHigh = 60
moistLow = 40
#get inputs for analysis
sensorDataJSON = getSensorData()
trendDataJSON = getTrendData()
days = handleDateLogic()
#set variables
tempF = sensorDataJSON["tempF"]
tempC = sensorDataJSON["tempC"]
moisture = sensorDataJSON["moisture"]
methane = sensorDataJSON["methane"]
waterLevel = sensorDataJSON["waterLevel"]
ambientTemp = sensorDataJSON["ambientTemp"]
tempTrend = trendDataJSON['tempTrend']
moistTrend = trendDataJSON['moistTrend']
tempAlert = info
moistAlert = info
methaneAlert = info
waterLevelAlert = info
OverallMsg = tempMessageArray[0]
msgPriority = 3 #1 = trumps all other actions, #2 additive
if days > 35:
OverallMsg = tempMessageArray[1]
elif days > 25:
OverallMsg = tempMessageArray[2]
else: # the compost is not ready
################################################################
#Handle Temperatures
if tempF > tempDanger:
addWater()
openVent()
tempAlert = danger
OverallMsg = tempMessageArray[3]
msgPriority = 1
elif tempDanger >= tempF > tempHigh:
addWater()
openVent()
tempAlert = danger
OverallMsg = tempMessageArray[4]
msgPriority = 1
elif tempHigh >= tempF > tempOK:
if tempTrend < 1:
openVent()
tempAlert = warning
OverallMsg = tempMessageArray[5]
msgPriority = 2
else:
tempAlert = warning
OverallMsg = tempMessageArray[6]
msgPriority = 2
elif tempOK >= tempF > tempLow:
tempAlert = success
OverallMsg = tempMessageArray[7]
msgPriority = 3
else:
closeVent()
if tempTrend > 0:
tempAlert = warning
OverallMsg = tempMessageArray[8]
msgPriority = 2
else:
if ambientTemp =="low":
tempAlert = danger
OverallMsg = tempMessageArray[10]
msgPriority = 1
else:
tempAlert = warning
OverallMsg = tempMessageArray[9]
msgPriority = 2
#######################################################################
#handle Moisture content
if moisture> moistHigh:
if moistTrend>=0:
moistAlert = danger
if msgPriority > 1: #this message will trump any other message besides temp priority 3
OverallMsg = moistureMessageArray[0]
openVent()
msgPriority = 1
else:
moistAlert = warning
if msgPriority == 2: # this message is appended to any existing P2 messages
OverallMsg = OverallMsg + " " + moistureMessageArray[1]
openVent()
msgPriority = 2
elif msgPriority == 3:#this message is replaces any P3 messages
OverallMsg = moistureMessageArray[1]
openVent()
msgPriority = 2
elif moistHigh >=moisture> moistLow:
moistAlert = success
else:
if moistTrend<1:
moistAlert = danger
if msgPriority > 1: #this message will trump any other message besides priority 1
OverallMsg = moistureMessageArray[4]
closeVent()
addWater()
msgPriority = 1
else:
moistAlert = warning
if msgPriority == 2: # this message is appended to any existing P2 messages
OverallMsg = OverallMsg + " " + moistureMessageArray[3]
addWater()
msgPriority = 2
elif msgPriority == 3:#this message is replaces any P3 messages
OverallMsg = moistureMessageArray[3]
addWater()
msgPriority = 2
#######################
#Handle Water Level
if waterLevel <= 0:
waterLevelMsg = "Refill"
waterLevelAlert = danger
else:
waterLevelMsg = "Ok"
waterLevelAlert = success
#######################
#Handle Methane Level
if methane > 50000:
methaneAlert = danger
elif 50000 >= methane > 10000:
methaneAlert = warning
else:
methaneAlert = success
writeToDatabase()
return OverallMsg
#####################################################
def getSensorData(): #stub to get sensor data
#read request and recieve data from sensors
#return data to function
tempF = 85
tempC = (tempF - 32) * 5/9
ambientTempF = 50
if ambientTempF <=40:
ambientTemp = "low"
else:
ambientTemp = "high"
return {"tempF":tempF, "tempC": tempC, "ambientTemp": ambientTemp, "moisture":30, "methane": 23.1, "waterLevel": -1}
def getTrendData(): #stub to get trend data
#analyze historical data
#set thresholds for what up/down/and steady
#return data to function
return {"tempTrend":1,"moistTrend":1}
def handleDateLogic(): #stub to handle date logic
#settings for readiness
daysWhenReady = 35
daysAtSafeTempLevel = 25
today = datetime.today()
#calculations based on trends - hardcoded for testing
calcDaysAtSafeTempLevel = 1 #will need to read from database
dateOfLastTemp = datetime.strptime('2017-06-01', "%Y-%m-%d") #will need to read from database
if calcDaysAtSafeTempLevel >= daysAtSafeTempLevel:
dateOf25thDay = datetime.strptime('2017-05-25', "%Y-%m-%d")
daysSince25th = abs((today - dateOf25thDay).days)
return daysSince25th + daysAtSafeTempLevel
else:
return calcDaysAtSafeTempLevel
def addWater(): #stub to send command to satellite station to add water
return 'ok'
def openVent(): #stub to send command to satellite station to open vent
return 'ok'
def closeVent(): #stub to send command to satellite station to close vent
return 'ok'
def writeToDatabase(): #stub to write values to database
return 'ok'
def persistSensorData(): #stub to write values to database for trend analysis
return 'ok'
Discussions
Become a Hackaday.io Member
Create an account to leave a comment. Already have an account? Log In.