MSA-2113: Multi-Input Multi-Output device with 2 low voltage signal inputs and 2 low voltage relay outputs. Device handler allows user to see all 4 device endpoints and control each relay independently and view signal status as a voltage or (open/closed) status, depending on the signal type that is connected. There's two devices type handlers (a-side & b-side). These are for users to be able to create separate devices for each of the relays and inputs, so they can control them with rules and scenes in smart-home monitor or other smart-apps.

devicetypes/fortrezz/fortrezz-mimo2-b-side.src/fortrezz-mimo2-b-side.groovy

@@ -0,0 +1,102 @@
+/**
+ *  FortrezZ MIMO2+ B-Side
+ *
+ *  Copyright 2016 FortrezZ, LLC
+ *
+ *  Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
+ *  in compliance with the License. You may obtain a copy of the License at:
+ *
+ *      http://www.apache.org/licenses/LICENSE-2.0
+ *
+ *  Unless required by applicable law or agreed to in writing, software distributed under the License is distributed
+ *  on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
+ *  for the specific language governing permissions and limitations under the License.
+ *
+ */
+metadata {
+	definition (name: "FortrezZ MIMO2+ B-Side", namespace: "fortrezz", author: "FortrezZ, LLC") {
+		capability "Contact Sensor"
+		capability "Relay Switch"
+		capability "Switch"
+		capability "Voltage Measurement"
+        capability "Refresh"
+	}
+    
+	tiles {
+         standardTile("switch", "device.switch", width: 2, height: 2) {
+            state "on", label: "Relay 2 On", action: "off", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-On-104-edit.png", backgroundColor: "#53a7c0"            
+			state "off", label: "Relay 2 Off", action: "on", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-Off-104-edit.png", backgroundColor: "#ffffff"
+        }
+        standardTile("anaDig1", "device.anaDig1", inactiveLabel: false) {
+			state "open", label: '${name}', icon: "st.contact.contact.open", backgroundColor: "#ffa81e"
+			state "closed", label: '${name}', icon: "st.contact.contact.closed", backgroundColor: "#79b821"
+            state "val", label:'${currentValue}v', unit:"", defaultState: true
+		}
+        standardTile("refresh", "device.switch", inactiveLabel: false, decoration: "flat") {
+			state "default", label:'', action:"refresh.refresh", icon:"st.secondary.refresh"
+		}
+        standardTile("powered", "device.powered", inactiveLabel: false) {
+			state "powerOn", label: "Power On", icon: "st.switches.switch.on", backgroundColor: "#79b821"
+			state "powerOff", label: "Power Off", icon: "st.switches.switch.off", backgroundColor: "#ffa81e"
+		}
+		standardTile("configure", "device.configure", inactiveLabel: false, decoration: "flat") {
+			state "configure", label:'', action:"configuration.configure", icon:"st.secondary.configure"
+		}
+        standardTile("blank", "device.blank", inactiveLabel: true, decoration: "flat") {
+        	state("blank", label: '')
+        }
+		main (["switch"])
+		details(["switch", "anaDig1", "blank", "blank", "refresh", "powered"])
+	}
+}
+
+// parse events into attributes
+def parse(String description) {
+	log.debug "Parsing '${description}'"
+	// TODO: handle 'contact' attribute
+	// TODO: handle 'switch' attribute
+	// TODO: handle 'switch' attribute
+	// TODO: handle 'voltage' attribute
+
+}
+
+def eventParse(evt) {
+	log.debug("Event: ${evt.name}=${evt.value}")
+    switch(evt.name) {
+    	case "powered":
+        	sendEvent(name: evt.name, value: evt.value)
+        	break
+    	case "switch2":
+        	sendEvent(name: "switch", value: evt.value)
+        	break
+    	case "contact2":
+        	sendEvent(name: "contact", value: evt.value)
+        	break
+    	case "voltage2":
+        	sendEvent(name: "voltage", value: evt.value)
+        	break
+    	case "relay2":
+        	sendEvent(name: evt.name, value: evt.value)
+        	break
+    	case "anaDig2":
+        	sendEvent(name: "anaDig1", value: evt.value)
+        	break
+    }
+}
+
+// handle commands
+def on() {
+    parent.on2(device.id)
+	log.debug("Executing 'on'")
+	// TODO: Send Event to parent device for "on2"
+}
+
+def off() {
+    parent.off2(device.id)
+	log.debug("Executing 'off'")
+	// TODO: Send Event to parent device for "off2"
+}
+def refresh() {
+	parent.refresh2(device.id)
+    log.debug("Executing 'refresh'")
+}

devicetypes/fortrezz/fortrezz-mimo2.src/fortrezz-mimo2.groovy

@@ -0,0 +1,379 @@
+/**
+ *  MIMO2 Device Handler
+ *
+ *  Copyright 2016 FortrezZ, LLC
+ *
+ *  Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
+ *  in compliance with the License. You may obtain a copy of the License at:
+ *
+ *      http://www.apache.org/licenses/LICENSE-2.0
+ *
+ *  Unless required by applicable law or agreed to in writing, software distributed under the License is distributed
+ *  on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
+ *  for the specific language governing permissions and limitations under the License.
+ *
+ */
+metadata {
+	definition (name: "FortrezZ MIMO2+", namespace: "fortrezz", author: "FortrezZ, LLC") {
+		capability "Alarm"
+		capability "Contact Sensor"
+		capability "Switch"
+		capability "Voltage Measurement"
+        capability "Configuration"
+        capability "Refresh"
+        
+        attribute "powered", "string"
+        attribute "relay", "string"
+        
+        attribute "relay2", "string"
+        attribute "contact2", "string"
+        attribute "voltage2", "string"
+        
+		command "on"
+		command "off"
+        command "on2"
+        command "off2"
+        
+        fingerprint deviceId: "0x2100", inClusters: "0x5E,0x86,0x72,0x5A,0x59,0x71,0x98,0x7A"
+	}
+    
+    preferences {
+
+        input ("RelaySwitchDelay", "decimal", title: "Delay between relay switch on and off in seconds. Only Numbers 0 to 3 allowed. 0 value will remove delay and allow relay to function as a standard switch:\nRelay 1", description: "Numbers 0 to 3.1 allowed.", defaultValue: 0, required: false, displayDuringSetup: true)
+        input ("RelaySwitchDelay2", "decimal", title: "Relay 2", description: "Numbers 0 to 3.1 allowed.", defaultValue: 0, required: false, displayDuringSetup: true)
+        input ("Sig1AD", "bool", title: "Switch off for digital, on for analog:\nSIG1", required: false, displayDuringSetup: true)
+        input ("Sig2AD", "bool", title: "SIG2", required: false, displayDuringSetup: true)
+        } // the range would be 0 to 3.1, but the range value would not accept 3.1, only whole numbers (i tried paranthesis and fractions too. :( )
+
+       
+	tiles {
+         standardTile("switch", "device.switch", width: 2, height: 2) {
+            state "on", label: "Relay 1 On", action: "off", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-On-104-edit.png", backgroundColor: "#53a7c0"            
+			state "off", label: "Relay 1 Off", action: "on", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-Off-104-edit.png", backgroundColor: "#ffffff"
+
+        }
+         standardTile("switch2", "device.switch2", width: 2, height: 2, inactiveLabel: false) {
+            state "on", label: "Relay 2 On", action: "off2", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-On-104-edit.png", backgroundColor: "#53a7c0"
+			state "off", label: 'Relay 2 Off', action: "on2", icon: "http://swiftlet.technology/wp-content/uploads/2016/06/Switch-Off-104-edit.png", backgroundColor: "#ffffff"
+        }
+        standardTile("anaDig1", "device.anaDig1", inactiveLabel: false) {
+			state "open", label: '${name}', icon: "st.contact.contact.open", backgroundColor: "#ffa81e"
+			state "closed", label: '${name}', icon: "st.contact.contact.closed", backgroundColor: "#79b821"
+            state "val", label:'${currentValue}v', unit:"", defaultState: true
+		}
+        standardTile("anaDig2", "device.anaDig2", inactiveLabel: false) {
+			state "open", label: '${name}', icon: "st.contact.contact.open", backgroundColor: "#ffa81e"
+			state "closed", label: '${name}', icon: "st.contact.contact.closed", backgroundColor: "#79b821"
+            state "val", label:'${currentValue}v', unit:"", defaultState: true
+		}
+        standardTile("refresh", "device.switch", inactiveLabel: false, decoration: "flat") {
+			state "default", label:'', action:"refresh.refresh", icon:"st.secondary.refresh"
+		}
+        standardTile("powered", "device.powered", inactiveLabel: false) {
+			state "powerOn", label: "Power On", icon: "st.switches.switch.on", backgroundColor: "#79b821"
+			state "powerOff", label: "Power Off", icon: "st.switches.switch.off", backgroundColor: "#ffa81e"
+		}
+		standardTile("configure", "device.configure", inactiveLabel: false, decoration: "flat") {
+			state "configure", label:'', action:"configuration.configure", icon:"st.secondary.configure"
+		}
+        standardTile("blank", "device.blank", inactiveLabel: true, decoration: "flat") {
+        	state("blank", label: '')
+        }
+		main (["switch"])
+		details(["switch", "anaDig1", "blank", "switch2", "anaDig2", "blank", "configure", "refresh", "powered"])
+	}
+}
+
+// parse events into attributes
+def parse(String description) {
+	def result = null
+	def cmd = zwave.parse(description)
+    
+    if (cmd.CMD == "7105") {				//Mimo sent a power loss report
+    	log.debug "Device lost power"
+    	sendEvent(name: "powered", value: "powerOff", descriptionText: "$device.displayName lost power")
+    } else {
+    	sendEvent(name: "powered", value: "powerOn", descriptionText: "$device.displayName regained power")
+    }
+	if (cmd) {
+    	def eventReturn = zwaveEvent(cmd)
+        if(eventReturn in physicalgraph.device.HubMultiAction) {
+        	result = eventReturn
+        }
+        else {
+        	result = createEvent(eventReturn)
+        }
+	}
+    log.debug "Parse returned ${result} $cmd.CMD"
+	return result
+}
+
+def updated() { // neat built-in smartThings function which automatically runs whenever any setting inputs are changed in the preferences menu of the device handler
+    
+    if (state.count == 1) // this bit with state keeps the function from running twice ( which it always seems to want to do) (( oh, and state.count is a variable which is nonVolatile and doesn't change per every parse request.
+    {
+        state.count = 0
+        log.debug "Settings Updated..."
+        return response(delayBetween([
+            configure(), // the response() function is used for sending commands in reponse to an event, without it, no zWave commands will work for contained function
+            refresh()
+            ], 200))
+    }
+    else {state.count = 1}
+}
+
+def zwaveEvent(physicalgraph.zwave.commands.basicv1.BasicSet cmd) // basic set is essentially our digital sensor for SIG1 and SIG2 - it doesn't use an endpoint so we are having it send a multilevelGet() for SIG1 and SIG2 to see which one triggered.
+{
+	log.debug "sent a BasicSet command"
+	return response(refresh())
+}
+
+def zwaveEvent(int endPoint, physicalgraph.zwave.commands.sensorbinaryv1.SensorBinaryReport cmd) // event to get the state of the digital sensor SIG1 and SIG2
+{
+	log.debug "sent a sensorBinaryReport command"
+	return response(refresh())
+}
+
+def zwaveEvent(int endPoint, physicalgraph.zwave.commands.switchbinaryv1.SwitchBinaryReport cmd) // event for seeing the states of relay 1 and relay 2
+{
+	def map = [:] // map for containing the name and state fo the specified relay
+    if (endPoint == 3)
+    {
+    	if (cmd.value) // possible values are 255 and 0 (0 is false)
+    		{map.value = "on"}
+    	else
+    		{map.value = "off"}
+        map.name = "switch"
+        log.debug "sent a SwitchBinary command $map.name $map.value" // the map is only used for debug messages. not for the return command to the device
+        return [name: "switch", value: cmd.value ? "on" : "off"]
+    }
+    else if (endPoint == 4)
+    {
+    	if (cmd.value)
+    		{map.value = "on"}
+    	else
+    		{map.value = "off"}
+        map.name = "switch2"
+        sendEvent(name: "relay2", value: "$map.value")
+        log.debug "sent a SwitchBinary command $map.name $map.value" // the map is only used for debug messages. not for the return command to the device
+        return [name: "switch2", value: cmd.value ? "on" : "off"]
+    }
+}
+   
+def zwaveEvent (int endPoint, physicalgraph.zwave.commands.sensormultilevelv5.SensorMultilevelReport cmd) // sensorMultilevelReport is used to report the value of the analog voltage for SIG1
+{
+	def map = [:]
+    def stdEvent = [:]
+    def voltageVal = CalculateVoltage(cmd.scaledSensorValue) // saving the scaled Sensor Value used to enter into a large formula to determine actual voltage value
+    if (endPoint == 1) //endPoint 1 is for SIG1
+    {
+    	if (state.AD1 == false) // state.AD1 is  to determine which state the anaDig1 tile should be in (either analogue or digital mode)
+        {
+        	map.name = "anaDig1"
+            stdEvent.name = "contact"
+            if (voltageVal < 2) { // DK changed to 2v to follow LED behavior
+            	map.value = "closed"
+                stdEvent.value = "closed"
+            }
+            else
+            {
+            	map.value = "open"
+                stdEvent.value = "open"
+            } 
+        }
+        else //or state.AD1 is true for analogue mode
+        {
+        	map.name = "anaDig1"
+            stdEvent.name = "voltage"
+        	map.value = voltageVal
+            stdEvent.value = voltageVal
+        	map.unit = "v"
+            stdEvent.unit = "v"
+        }
+    }
+    else if (endPoint == 2) // endpoint 2 is for SIG2
+    {
+        if (state.AD2 == false)
+        {
+        	map.name = "anaDig2"
+            stdEvent.name = "contact2"
+            if (voltageVal < 2) {
+            	map.value = "closed"
+                stdEvent.value = "closed"
+            }
+            else
+            {
+            	map.value = "open"
+                stdEvent.value = "open"
+            } 
+        }
+        else
+        {
+        	map.name = "anaDig2"
+            stdEvent.name = "voltage2"
+        	map.value = voltageVal
+            stdEvent.value = voltageVal
+        	map.unit = "v"
+            stdEvent.unit = "v"
+        }
+    }
+	log.debug "sent a SensorMultilevelReport $map.name $map.value"
+    sendEvent(stdEvent)
+    return map
+}
+
+def zwaveEvent(physicalgraph.zwave.commands.securityv1.SecurityMessageEncapsulation cmd) { //standard security encapsulation event code (should be the same on all device handlers)
+    def encapsulatedCommand = cmd.encapsulatedCommand()
+    // can specify command class versions here like in zwave.parse
+    if (encapsulatedCommand) {
+        return zwaveEvent(encapsulatedCommand)
+    }
+}
+
+// MultiChannelCmdEncap and MultiInstanceCmdEncap are ways that devices
+// can indicate that a message is coming from one of multiple subdevices
+// or "endpoints" that would otherwise be indistinguishable
+def zwaveEvent(physicalgraph.zwave.commands.multichannelv3.MultiChannelCmdEncap cmd) {
+    def encapsulatedCommand = cmd.encapsulatedCommand()
+    log.debug ("Command from endpoint ${cmd.sourceEndPoint}: ${encapsulatedCommand}")
+
+    if (encapsulatedCommand) {
+        return zwaveEvent(cmd.sourceEndPoint, encapsulatedCommand)
+    }
+}
+
+def zwaveEvent(int endPoint, physicalgraph.zwave.commands.multichannelassociationv2.MultiChannelAssociationReport cmd) {
+	
+    log.debug "sent an Association Report"
+    log.debug " ${cmd.groupingIdentifier}"
+    //return [:]
+}
+
+def zwaveEvent(physicalgraph.zwave.Command cmd) {
+	// Handles all Z-Wave commands we aren't interested in
+     log.debug("Un-parsed Z-Wave message ${cmd}")
+	return [:]
+}
+
+def CalculateVoltage(ADCvalue) // used to calculate the voltage based on the collected Scaled sensor value of the multilevel sensor event
+{
+    def volt = (((2.396*(10**-17))*(ADCvalue**5)) - ((1.817*(10**-13))*(ADCvalue**4)) + ((5.087*(10**-10))*(ADCvalue**3)) - ((5.868*(10**-7))*(ADCvalue**2)) + ((9.967*(10**-4))*(ADCvalue)) - (1.367*(10**-2)))
+	return volt.round(1)
+}
+	
+
+def configure() {
+	log.debug "Configuring...." 
+    def sig1
+    def sig2
+    if (Sig1AD == true)
+    {	sig1 = 0x01
+        state.AD1 = true}
+    else if (Sig1AD == false) 
+    {	sig1 = 0x40
+    	state.AD1 = false}
+    if (Sig2AD == true)
+    {	sig2 = 0x01
+    	state.AD2 = true}
+    else if (Sig2AD == false) 
+    {	sig2 = 0x40
+    	state.AD2 = false}
+    
+	def delay = (RelaySwitchDelay*10).toInteger() // the input which we get from the user is a string and is in seconds while the MIMO2 configuration requires it in 100ms so - change to integer and multiply by 10  
+    def delay2 = (RelaySwitchDelay2*10).toInteger() // the input which we get from the user is a string and is in seconds while the MIMO2 configuration requires it in 100ms so - change to integer and multiply by 10
+	if (delay > 31) 
+    {
+        log.debug "Relay 1 input ${delay / 10} set too high. Max value is 3.1"
+        delay = 31
+    }
+    if (delay < 0) 
+    {
+        log.debug "Relay 1 input ${delay / 10} set too low. Min value is 0"
+        delay = 0
+    }
+    if (delay2 > 31) 
+    {
+    	log.debug "Relay 2 input ${delay2 / 10} set too high. Max value is 3.1"
+    	delay2 = 31
+    }
+     if (delay2 < 0) 
+    {
+    	log.debug "Relay 2 input ${delay2 / 10} set too low. Min value is 0"
+    	delay = 0
+    } 
+
+    
+    
+    return delayBetween([
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:3, nodeId:[zwaveHubNodeId]), 0),
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:2, nodeId:[zwaveHubNodeId]), 0),
+
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:2, nodeId:[zwaveHubNodeId]), 1),
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:2, nodeId:[zwaveHubNodeId]), 2),
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:1, nodeId:[zwaveHubNodeId]), 3),
+        encap(zwave.multiChannelAssociationV2.multiChannelAssociationSet(groupingIdentifier:1, nodeId:[zwaveHubNodeId]), 4),
+
+        secure(zwave.configurationV1.configurationSet(configurationValue: [sig1], parameterNumber: 3, size: 1)), // sends a multiLevelSensor report every 30 seconds for SIG1
+        secure(zwave.configurationV1.configurationSet(configurationValue: [sig2], parameterNumber: 9, size: 1)), // sends a multiLevelSensor report every 30 seconds for SIG2
+        secure(zwave.configurationV1.configurationSet(configurationValue: [delay], parameterNumber: 1, size: 1)), // configurationValue for parameterNumber means how many 100ms do you want the relay
+        																										// to wait before it cycles again / size should just be 1 (for 1 byte.)
+        secure(zwave.configurationV1.configurationSet(configurationValue: [delay2], parameterNumber: 2, size: 1)),
+        
+    ], 200)
+}
+
+def on() {	
+	return encap(zwave.basicV1.basicSet(value: 0xff), 3) // physically changes the relay from on to off and requests a report of the relay
+    // oddly, smartThings automatically sends a switchBinaryGet() command whenever the above basicSet command is sent, so we don't need to send one here.
+}
+
+def off() {
+    return encap(zwave.basicV1.basicSet(value: 0x00), 3) // physically changes the relay from on to off and requests a report of the relay
+		// oddly, smartThings automatically sends a switchBinaryGet() command whenever the above basicSet command is sent, so we don't need to send one here.
+}
+
+def on2() {
+   return encap(zwave.basicV1.basicSet(value: 0xff), 4)
+        // oddly, smartThings automatically sends a switchBinaryGet() command whenever the above basicSet command is sent, so we don't need to send one here.
+}
+
+def off2() {
+    return encap(zwave.basicV1.basicSet(value: 0x00), 4)
+        // oddly, smartThings automatically sends a switchBinaryGet() command whenever the above basicSet command is sent, so we don't need to send one here.
+}
+
+def refresh() {
+	log.debug "Refresh"
+	return delayBetween([
+         encap(zwave.sensorMultilevelV5.sensorMultilevelGet(), 1),// requests a report of the anologue input voltage for SIG1
+         encap(zwave.sensorMultilevelV5.sensorMultilevelGet(), 2),// requests a report of the anologue input voltage for SIG2
+         encap(zwave.switchBinaryV1.switchBinaryGet(), 3), //requests a report of the relay to make sure that it changed for Relay 1
+         encap(zwave.switchBinaryV1.switchBinaryGet(), 4), //requests a report of the relay to make sure that it changed for Relay 2
+       ],200)
+}
+
+def refreshZWave() {
+	log.debug "Refresh (Z-Wave Response)"
+	return delayBetween([
+         encap(zwave.sensorMultilevelV5.sensorMultilevelGet(), 1),// requests a report of the anologue input voltage for SIG1
+         encap(zwave.sensorMultilevelV5.sensorMultilevelGet(), 2),// requests a report of the anologue input voltage for SIG2
+         encap(zwave.switchBinaryV1.switchBinaryGet(), 3), //requests a report of the relay to make sure that it changed for Relay 1
+         encap(zwave.switchBinaryV1.switchBinaryGet(), 4) //requests a report of the relay to make sure that it changed for Relay 2
+       ],200)
+}
+
+private secureSequence(commands, delay=200) { // decided not to use this
+	return delayBetween(commands.collect{ secure(it) }, delay)
+}
+
+private secure(physicalgraph.zwave.Command cmd) { //take multiChannel message and securely encrypts the message so the device can read it
+	return zwave.securityV1.securityMessageEncapsulation().encapsulate(cmd).format()
+}
+
+private encap(cmd, endpoint) { // takes desired command and encapsulates it by multiChannel and then sends it to secure() to be wrapped with another encapsulation for secure encryption
+	if (endpoint) {
+		return secure(zwave.multiChannelV3.multiChannelCmdEncap(bitAddress: false, sourceEndPoint:0, destinationEndPoint: endpoint).encapsulate(cmd))
+	} else {
+		return secure(cmd)
+	}
+}

devicetypes/plaidsystems/spruce-sensor.src/spruce-sensor.groovy

@@ -73,7 +73,7 @@ metadata {
 					[value: 64, color: "#44B621"],
 					[value: 80, color: "#3D79D9"],
 					[value: 96, color: "#0A50C2"]
-				], icon:"st.Weather.weather12"
+				]
 		}
         
         valueTile("maxHum", "device.maxHum", canChangeIcon: false, canChangeBackground: false) {

devicetypes/smartthings/aeon-key-fob.src/aeon-key-fob.groovy

@@ -133,8 +133,8 @@ def updated() {
 }
 
 def initialize() {
-	// Device only goes OFFLINE when Hub is off
-	sendEvent(name: "DeviceWatch-Enroll", value: JsonOutput.toJson([protocol: "zwave", scheme:"untracked"]), displayed: false)
+	// Arrival sensors only goes OFFLINE when Hub is off
+	sendEvent(name: "DeviceWatch-Enroll", value: JsonOutput.toJson([protocol: "zigbee", scheme:"untracked"]), displayed: false)
 
 	def zwMap = getZwaveInfo()
 	def buttons = 4 // Default for Key Fob

devicetypes/smartthings/aeon-minimote.src/aeon-minimote.groovy

@@ -111,6 +111,7 @@ def configure() {
 	return cmds
 }
 
+
 def installed() {
 	initialize()
 }
@@ -120,7 +121,7 @@ def updated() {
 }
 
 def initialize() {
-	// Device only goes OFFLINE when Hub is off
-	sendEvent(name: "DeviceWatch-Enroll", value: JsonOutput.toJson([protocol: "zwave", scheme:"untracked"]), displayed: false)
+	// Arrival sensors only goes OFFLINE when Hub is off
+	sendEvent(name: "DeviceWatch-Enroll", value: JsonOutput.toJson([protocol: "zigbee", scheme:"untracked"]), displayed: false)
 	sendEvent(name: "numberOfButtons", value: 4)
 }

devicetypes/smartthings/aeon-multisensor-gen5.src/README.md

@@ -27,9 +27,13 @@ Works with:
 ## Device Health
 
 Aeon Labs MultiSensor (Gen 5) is polled by the hub.
-Aeon MultiSensor Gen5 reports in once every hour.
+As of hubCore version 0.14.38 the hub sends up reports every 15 minutes regardless of whether the state changed.
+Device-Watch allows 2 check-in misses from device plus some lag time. So Check-in interval = (2*15 + 2)mins = 32 mins.
+Not to mention after going OFFLINE when the device is plugged back in, it might take a considerable amount of time for
+the device to appear as ONLINE again. This is because if this listening device does not respond to two poll requests in a row,
+it is not polled for 5 minutes by the hub. This can delay up the process of being marked ONLINE by quite some time.
 
-* __122min__ checkInterval
+* __32min__ checkInterval
 
 ## Troubleshooting
 

devicetypes/smartthings/aeon-multisensor-gen5.src/aeon-multisensor-gen5.groovy

@@ -100,12 +100,12 @@ metadata {
 
 def installed(){
 // Device-Watch simply pings if no device events received for 32min(checkInterval)
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
+	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
 }
 
 def updated(){
 // Device-Watch simply pings if no device events received for 32min(checkInterval)
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
+	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
 }
 
 def parse(String description)

devicetypes/smartthings/aeon-multisensor.src/README.md

@@ -28,9 +28,13 @@ Works with:
 ## Device Health
 
 Aeon Labs MultiSensor is polled by the hub.
-Aeon MultiSensor reports in once every hour.
+As of hubCore version 0.14.38 the hub sends up reports every 15 minutes regardless of whether the state changed.
+Device-Watch allows 2 check-in misses from device plus some lag time. So Check-in interval = (2*15 + 2)mins = 32 mins.
+Not to mention after going OFFLINE when the device is plugged back in, it might take a considerable amount of time for
+the device to appear as ONLINE again. This is because if this listening device does not respond to two poll requests in a row,
+it is not polled for 5 minutes by the hub. This can delay up the process of being marked ONLINE by quite some time.
 
-* __122min__ checkInterval
+* __32min__ checkInterval
 
 ## Battery Specification
 

devicetypes/smartthings/aeon-multisensor.src/aeon-multisensor.groovy

@@ -96,12 +96,12 @@ metadata {
 
 def installed(){
 // Device-Watch simply pings if no device events received for 32min(checkInterval)
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
+	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
 }
 
 def updated(){
 // Device-Watch simply pings if no device events received for 32min(checkInterval)
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
+	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
 }
 
 // Parse incoming device messages to generate events

devicetypes/smartthings/ct100-thermostat.src/ct100-thermostat.groovy

@@ -6,6 +6,7 @@ metadata {
 		capability "Relative Humidity Measurement"
 		capability "Thermostat"
 		capability "Battery"
+		capability "Configuration"
 		capability "Refresh"
 		capability "Sensor"
 		capability "Health Check"
@@ -14,173 +15,161 @@ metadata {
 
 		command "switchMode"
 		command "switchFanMode"
-		command "lowerHeatingSetpoint"
-		command "raiseHeatingSetpoint"
-		command "lowerCoolSetpoint"
-		command "raiseCoolSetpoint"
+		command "quickSetCool"
+		command "quickSetHeat"
 
 		fingerprint deviceId: "0x08", inClusters: "0x43,0x40,0x44,0x31,0x80,0x85,0x60"
 		fingerprint mfr:"0098", prod:"6401", model:"0107", deviceJoinName: "2Gig CT100 Programmable Thermostat"
 	}
 
-	tiles {
-		multiAttributeTile(name:"temperature", type:"generic", width:3, height:2, canChangeIcon: true) {
-			tileAttribute("device.temperature", key: "PRIMARY_CONTROL") {
-				attributeState("temperature", label:'${currentValue}°', icon: "st.alarm.temperature.normal",
-					backgroundColors:[
-							// Celsius
-							[value: 0, color: "#153591"],
-							[value: 7, color: "#1e9cbb"],
-							[value: 15, color: "#90d2a7"],
-							[value: 23, color: "#44b621"],
-							[value: 28, color: "#f1d801"],
-							[value: 35, color: "#d04e00"],
-							[value: 37, color: "#bc2323"],
-							// Fahrenheit
-							[value: 40, color: "#153591"],
-							[value: 44, color: "#1e9cbb"],
-							[value: 59, color: "#90d2a7"],
-							[value: 74, color: "#44b621"],
-							[value: 84, color: "#f1d801"],
-							[value: 95, color: "#d04e00"],
-							[value: 96, color: "#bc2323"]
-					]
-				)
-			}
-			tileAttribute("device.batteryIcon", key: "SECONDARY_CONTROL") {
-				attributeState "ok_battery", label:'${currentValue}%', icon:"st.arlo.sensor_battery_4"
-				attributeState "low_battery", label:'Low Battery', icon:"st.arlo.sensor_battery_0"
-			}
-		}
-		standardTile("mode", "device.thermostatMode", width:2, height:2, inactiveLabel: false, decoration: "flat") {
-			state "off", action:"switchMode", nextState:"to_heat", icon: "st.thermostat.heating-cooling-off"
-			state "heat", action:"switchMode", nextState:"to_cool", icon: "st.thermostat.heat"
-			state "cool", action:"switchMode", nextState:"...", icon: "st.thermostat.cool"
-			state "auto", action:"switchMode", nextState:"...", icon: "st.thermostat.auto"
-			state "emergency heat", action:"switchMode", nextState:"...", icon: "st.thermostat.emergency-heat"
-			state "to_heat", action:"switchMode", nextState:"to_cool", icon: "st.secondary.secondary"
-			state "to_cool", action:"switchMode", nextState:"...", icon: "st.secondary.secondary"
-			state "...", label: "...", action:"off", nextState:"off", icon: "st.secondary.secondary"
-		}
-		standardTile("fanMode", "device.thermostatFanMode", width:2, height:2, inactiveLabel: false, decoration: "flat") {
-			state "auto", action:"switchFanMode", icon: "st.thermostat.fan-auto"
-			state "on", action:"switchFanMode", icon: "st.thermostat.fan-on"
-			state "circulate", action:"switchFanMode", icon: "st.thermostat.fan-circulate"
-		}
-		valueTile("humidity", "device.humidity", width:2, height:2, inactiveLabel: false, decoration: "flat") {
-			state "humidity", label:'${currentValue}%', icon:"st.Weather.weather12"
-		}
-		standardTile("lowerHeatingSetpoint", "device.heatingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "heatingSetpoint", action:"lowerHeatingSetpoint", icon:"st.thermostat.thermostat-left"
-		}
-		valueTile("heatingSetpoint", "device.heatingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "heatingSetpoint", label:'${currentValue}° heat', backgroundColor:"#ffffff"
-		}
-		standardTile("raiseHeatingSetpoint", "device.heatingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "heatingSetpoint", action:"raiseHeatingSetpoint", icon:"st.thermostat.thermostat-right"
-		}
-		standardTile("lowerCoolSetpoint", "device.coolingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "coolingSetpoint", action:"lowerCoolSetpoint", icon:"st.thermostat.thermostat-left"
-		}
-		valueTile("coolingSetpoint", "device.coolingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "coolingSetpoint", label:'${currentValue}° cool', backgroundColor:"#ffffff"
-		}
-		standardTile("raiseCoolSetpoint", "device.heatingSetpoint", width:2, height:1, inactiveLabel: false, decoration: "flat") {
-			state "heatingSetpoint", action:"raiseCoolSetpoint", icon:"st.thermostat.thermostat-right"
-		}
+	// simulator metadata
+	simulator {
+		status "off"            : "command: 4003, payload: 00"
+		status "heat"           : "command: 4003, payload: 01"
+		status "cool"           : "command: 4003, payload: 02"
+		status "auto"           : "command: 4003, payload: 03"
+		status "emergencyHeat"  : "command: 4003, payload: 04"
 
-		standardTile("refresh", "device.thermostatMode", width:2, height:2, inactiveLabel: false, decoration: "flat") {
+		status "fanAuto"        : "command: 4403, payload: 00"
+		status "fanOn"          : "command: 4403, payload: 01"
+		status "fanCirculate"   : "command: 4403, payload: 06"
+
+		status "heat 60"        : "command: 4303, payload: 01 09 3C"
+		status "heat 72"        : "command: 4303, payload: 01 09 48"
+
+		status "cool 76"        : "command: 4303, payload: 02 09 4C"
+		status "cool 80"        : "command: 4303, payload: 02 09 50"
+
+		status "temp 58"        : "command: 3105, payload: 01 2A 02 44"
+		status "temp 62"        : "command: 3105, payload: 01 2A 02 6C"
+		status "temp 78"        : "command: 3105, payload: 01 2A 03 0C"
+		status "temp 86"        : "command: 3105, payload: 01 2A 03 34"
+
+		status "idle"           : "command: 4203, payload: 00"
+		status "heating"        : "command: 4203, payload: 01"
+		status "cooling"        : "command: 4203, payload: 02"
+
+		// reply messages
+		reply "2502": "command: 2503, payload: FF"
+	}
+
+	tiles {
+		valueTile("temperature", "device.temperature", width: 2, height: 2) {
+			state("temperature", label:'${currentValue}°',
+				backgroundColors:[
+					[value: 32, color: "#153591"],
+					[value: 44, color: "#1e9cbb"],
+					[value: 59, color: "#90d2a7"],
+					[value: 74, color: "#44b621"],
+					[value: 84, color: "#f1d801"],
+					[value: 92, color: "#d04e00"],
+					[value: 98, color: "#bc2323"]
+				]
+			)
+		}
+		standardTile("mode", "device.thermostatMode", inactiveLabel: false, decoration: "flat") {
+			state "off", label:'${name}', action:"switchMode", nextState:"to_heat"
+			state "heat", label:'${name}', action:"switchMode", nextState:"to_cool"
+			state "cool", label:'${name}', action:"switchMode", nextState:"..."
+			state "auto", label:'${name}', action:"switchMode", nextState:"..."
+			state "emergency heat", label:'${name}', action:"switchMode", nextState:"..."
+			state "to_heat", label: "heat", action:"switchMode", nextState:"to_cool"
+			state "to_cool", label: "cool", action:"switchMode", nextState:"..."
+			state "...", label: "...", action:"off", nextState:"off"
+		}
+		standardTile("fanMode", "device.thermostatFanMode", inactiveLabel: false, decoration: "flat") {
+			state "fanAuto", label:'${name}', action:"switchFanMode"
+			state "fanOn", label:'${name}', action:"switchFanMode"
+			state "fanCirculate", label:'${name}', action:"switchFanMode"
+		}
+		controlTile("heatSliderControl", "device.heatingSetpoint", "slider", height: 1, width: 2, inactiveLabel: false) {
+			state "setHeatingSetpoint", action:"quickSetHeat", backgroundColor:"#e86d13"
+		}
+		valueTile("heatingSetpoint", "device.heatingSetpoint", inactiveLabel: false, decoration: "flat") {
+			state "heat", label:'${currentValue}° heat', backgroundColor:"#ffffff"
+		}
+		controlTile("coolSliderControl", "device.coolingSetpoint", "slider", height: 1, width: 2, inactiveLabel: false) {
+			state "setCoolingSetpoint", action:"quickSetCool", backgroundColor: "#00a0dc"
+		}
+		valueTile("coolingSetpoint", "device.coolingSetpoint", inactiveLabel: false, decoration: "flat") {
+			state "cool", label:'${currentValue}° cool', backgroundColor:"#ffffff"
+		}
+		valueTile("humidity", "device.humidity", inactiveLabel: false, decoration: "flat") {
+			state "humidity", label:'${currentValue}% humidity', unit:""
+		}
+		valueTile("battery", "device.battery", inactiveLabel: false, decoration: "flat") {
+			state "battery", label:'${currentValue}% battery', unit:""
+		}
+		standardTile("refresh", "device.thermostatMode", inactiveLabel: false, decoration: "flat") {
 			state "default", action:"refresh.refresh", icon:"st.secondary.refresh"
 		}
 		main "temperature"
-		details(["temperature", "mode", "fanMode", "humidity", "lowerHeatingSetpoint", "heatingSetpoint", "raiseHeatingSetpoint", "lowerCoolSetpoint", "coolingSetpoint", "raiseCoolSetpoint", "refresh"])
+		details(["temperature", "mode", "fanMode", "heatSliderControl", "heatingSetpoint", "coolSliderControl", "coolingSetpoint", "refresh", "humidity", "battery"])
 	}
 }
 
 def updated() {
-	// If not set update ManufacturerSpecific data
-	if (!getDataValue("manufacturer")) {
-		sendHubCommand(new physicalgraph.device.HubAction(zwave.manufacturerSpecificV2.manufacturerSpecificGet().format()))
-	}
-	initialize()
+	// Device-Watch simply pings if no device events received for 32min(checkInterval)
+	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
 }
 
 def installed() {
-	// Configure device
-	def cmds = []
-	cmds << new physicalgraph.device.HubAction(zwave.associationV1.associationSet(groupingIdentifier:1, nodeId:[zwaveHubNodeId]).format())
-	cmds << new physicalgraph.device.HubAction(zwave.manufacturerSpecificV2.manufacturerSpecificGet().format())
-	sendHubCommand(cmds)
-	initialize()
-}
-
-def initialize() {
 	// Device-Watch simply pings if no device events received for 32min(checkInterval)
 	sendEvent(name: "checkInterval", value: 2 * 15 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
-	// Poll device for additional data that will be updated by refresh tile
-	refresh()
 }
 
 def parse(String description)
 {
-	def result = null
+	def result = []
 	if (description == "updated") {
 	} else {
 		def zwcmd = zwave.parse(description, [0x42:2, 0x43:2, 0x31: 2, 0x60: 3])
 		if (zwcmd) {
-			result = zwaveEvent(zwcmd)
-			// Check battery level at least once every 2 days
-			if (!state.lastbatt || now() - state.lastbatt > 48*60*60*1000) {
-				sendHubCommand(new physicalgraph.device.HubAction(zwave.batteryV1.batteryGet().format()))
-			}
+			result += zwaveEvent(zwcmd)
 		} else {
 			log.debug "$device.displayName couldn't parse $description"
 		}
 	}
 	if (!result) {
-		return []
+		return null
 	}
-	return [result]
+	if (result.size() == 1 && (!state.lastbatt || now() - state.lastbatt > 48*60*60*1000)) {
+		result << response(zwave.batteryV1.batteryGet().format())
+	}
+	log.debug "$device.displayName parsed '$description' to $result"
+	result
 }
 
-def zwaveEvent(physicalgraph.zwave.commands.multichannelv3.MultiInstanceCmdEncap cmd) {
-	def encapsulatedCommand = cmd.encapsulatedCommand([0x31: 3])
-	log.debug ("multiinstancev1.MultiInstanceCmdEncap: command from instance ${cmd.instance}: ${encapsulatedCommand}")
+def zwaveEvent(physicalgraph.zwave.commands.multichannelv3.MultiChannelCmdEncap cmd) {
+	def result = null
+	def encapsulatedCommand = cmd.encapsulatedCommand([0x42:2, 0x43:2, 0x31: 2])
+	log.debug ("Command from endpoint ${cmd.sourceEndPoint}: ${encapsulatedCommand}")
 	if (encapsulatedCommand) {
-		zwaveEvent(encapsulatedCommand)
+		result = zwaveEvent(encapsulatedCommand)
+		if (cmd.sourceEndPoint == 1) {    // indicates a response to refresh() vs an unrequested update
+			def event = ([] + result)[0]  // in case zwaveEvent returns a list
+			def resp = nextRefreshQuery(event?.name)
+			if (resp) {
+				log.debug("sending next refresh query: $resp")
+				result = [] + result + response(["delay 200", resp])
+			}
+		}
 	}
+	result
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatsetpointv2.ThermostatSetpointReport cmd)
 {
-	def sendCmd = []
-	def unit = getTemperatureScale()
 	def cmdScale = cmd.scale == 1 ? "F" : "C"
-	def setpoint = getTempInLocalScale(cmd.scaledValue, cmdScale)
+	def temp = convertTemperatureIfNeeded(cmd.scaledValue, cmdScale, cmd.precision)
+	def unit = getTemperatureScale()
+	def map1 = [ value: temp, unit: unit, displayed: false ]
 	switch (cmd.setpointType) {
 		case 1:
-			//map1.name = "heatingSetpoint"
-			sendEvent(name: "heatingSetpoint", value: setpoint, unit: unit, displayed: false)
-			updateThermostatSetpoint("heatingSetpoint", setpoint)
-			// Enforce coolingSetpoint limits, as device doesn't
-			if (setpoint > getTempInLocalScale("coolingSetpoint")) {
-				sendCmd << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointSet(
-						setpointType: 2, scale: cmd.scale, precision: cmd.precision, scaledValue: cmd.scaledValue).format())
-				sendCmd << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 2).format())
-				sendHubCommand(sendCmd)
-			}
+			map1.name = "heatingSetpoint"
 			break;
 		case 2:
-			//map1.name = "coolingSetpoint"
-			sendEvent(name: "coolingSetpoint", value: setpoint, unit: unit, displayed: false)
-			updateThermostatSetpoint("coolingSetpoint", setpoint)
-			// Enforce heatingSetpoint limits, as device doesn't
-			if (setpoint < getTempInLocalScale("heatingSetpoint")) {
-				sendCmd << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointSet(
-						setpointType: 1, scale: cmd.scale, precision: cmd.precision, scaledValue: cmd.scaledValue).format())
-				sendCmd << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 1).format())
-				sendHubCommand(sendCmd)
-			}
+			map1.name = "coolingSetpoint"
 			break;
 		default:
 			log.debug "unknown setpointType $cmd.setpointType"
@@ -191,55 +180,33 @@ def zwaveEvent(physicalgraph.zwave.commands.thermostatsetpointv2.ThermostatSetpo
 	state.size = cmd.size
 	state.scale = cmd.scale
 	state.precision = cmd.precision
+
+	def mode = device.latestValue("thermostatMode")
+	if (mode && map1.name.startsWith(mode) || (mode == "emergency heat" && map1.name == "heatingSetpoint")) {
+		def map2 = [ name: "thermostatSetpoint", value: temp, unit: unit ]
+		[ createEvent(map1), createEvent(map2) ]
+	} else {
+		createEvent(map1)
+	}
 }
 
-// thermostatSetpoint is not displayed by any tile as it can't be predictable calculated due to
-// the device's quirkiness but it is defined by the capability so it must be set, set it to the most likely value
-def updateThermostatSetpoint(setpoint, value) {
-	def scale = getTemperatureScale()
-	def heatingSetpoint = (setpoint == "heatingSetpoint") ? value : getTempInLocalScale("heatingSetpoint")
-	def coolingSetpoint = (setpoint == "coolingSetpoint") ? value : getTempInLocalScale("coolingSetpoint")
-	def mode = device.currentValue("thermostatMode")
-	def thermostatSetpoint = heatingSetpoint    // corresponds to (mode == "heat" || mode == "emergency heat")
-	if (mode == "cool") {
-		thermostatSetpoint = coolingSetpoint
-	}
-	// Just set to average of heating + cooling for mode off and auto
-	if (mode == "off" || mode == "auto") {
-		thermostatSetpoint = getTempInLocalScale((heatingSetpoint + coolingSetpoint)/2, scale)
-	}
-	sendEvent(name: "thermostatSetpoint", value: thermostatSetpoint, unit: scale)
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.sensormultilevelv2.SensorMultilevelReport cmd) {
+def zwaveEvent(physicalgraph.zwave.commands.sensormultilevelv2.SensorMultilevelReport cmd)
+{
 	def map = [:]
 	if (cmd.sensorType == 1) {
 		map.name = "temperature"
 		map.unit = getTemperatureScale()
-		map.value = getTempInLocalScale(cmd.scaledSensorValue, (cmd.scale == 1 ? "F" : "C"))
+		map.value = convertTemperatureIfNeeded(cmd.scaledSensorValue, cmd.scale == 1 ? "F" : "C", cmd.precision)
 	} else if (cmd.sensorType == 5) {
 		map.name = "humidity"
 		map.unit = "%"
 		map.value = cmd.scaledSensorValue
 	}
-	sendEvent(map)
+	createEvent(map)
 }
 
-def zwaveEvent(physicalgraph.zwave.commands.sensormultilevelv3.SensorMultilevelReport cmd) {
-	def map = [:]
-	if (cmd.sensorType == 1) {
-		map.name = "temperature"
-		map.unit = getTemperatureScale()
-		map.value = getTempInLocalScale(cmd.scaledSensorValue, (cmd.scale == 1 ? "F" : "C"))
-	} else if (cmd.sensorType == 5) {
-		map.value = cmd.scaledSensorValue
-		map.unit = "%"
-		map.name = "humidity"
-	}
-	sendEvent(map)
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.thermostatoperatingstatev2.ThermostatOperatingStateReport cmd) {
+def zwaveEvent(physicalgraph.zwave.commands.thermostatoperatingstatev2.ThermostatOperatingStateReport cmd)
+{
 	def map = [name: "thermostatOperatingState" ]
 	switch (cmd.operatingState) {
 		case physicalgraph.zwave.commands.thermostatoperatingstatev2.ThermostatOperatingStateReport.OPERATING_STATE_IDLE:
@@ -264,7 +231,12 @@ def zwaveEvent(physicalgraph.zwave.commands.thermostatoperatingstatev2.Thermosta
 			map.value = "vent economizer"
 			break
 	}
-	sendEvent(map)
+	def result = createEvent(map)
+	if (result.isStateChange && device.latestValue("thermostatMode") == "auto" && (result.value == "heating" || result.value == "cooling")) {
+		def thermostatSetpoint = device.latestValue("${result.value}Setpoint")
+		result = [result, createEvent(name: "thermostatSetpoint", value: thermostatSetpoint, unit: getTemperatureScale())]
+	}
+	result
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatfanstatev1.ThermostatFanStateReport cmd) {
@@ -280,256 +252,203 @@ def zwaveEvent(physicalgraph.zwave.commands.thermostatfanstatev1.ThermostatFanSt
 			map.value = "running high"
 			break
 	}
-	sendEvent(map)
+	createEvent(map)
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport cmd) {
-	def map = [name: "thermostatMode", data:[supportedThermostatModes: state.supportedModes]]
+	def map = [name: "thermostatMode"]
+	def thermostatSetpoint = null
 	switch (cmd.mode) {
 		case physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport.MODE_OFF:
 			map.value = "off"
 			break
 		case physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport.MODE_HEAT:
 			map.value = "heat"
+			thermostatSetpoint = device.latestValue("heatingSetpoint")
 			break
 		case physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport.MODE_AUXILIARY_HEAT:
 			map.value = "emergency heat"
+			thermostatSetpoint = device.latestValue("heatingSetpoint")
 			break
 		case physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport.MODE_COOL:
 			map.value = "cool"
+			thermostatSetpoint = device.latestValue("coolingSetpoint")
 			break
 		case physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeReport.MODE_AUTO:
 			map.value = "auto"
+			def temp = device.latestValue("temperature")
+			def heatingSetpoint = device.latestValue("heatingSetpoint")
+			def coolingSetpoint = device.latestValue("coolingSetpoint")
+			if (temp && heatingSetpoint && coolingSetpoint) {
+				if (temp < (heatingSetpoint + coolingSetpoint) / 2.0) {
+					thermostatSetpoint = heatingSetpoint
+				} else {
+					thermostatSetpoint = coolingSetpoint
+				}
+			}
 			break
 	}
 	state.lastTriedMode = map.value
-	sendEvent(map)
-	updateThermostatSetpoint(null, null)
+	if (thermostatSetpoint) {
+		[ createEvent(map), createEvent(name: "thermostatSetpoint", value: thermostatSetpoint, unit: getTemperatureScale()) ]
+	} else {
+		createEvent(map)
+	}
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeReport cmd) {
-	def map = [name: "thermostatFanMode", data:[supportedThermostatFanModes: state.supportedFanModes]]
+	def map = [name: "thermostatFanMode", displayed: false]
 	switch (cmd.fanMode) {
-	case physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeReport.FAN_MODE_AUTO_LOW:
-			map.value = "auto"
+		case physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeReport.FAN_MODE_AUTO_LOW:
+			map.value = "fanAuto"
 			break
 		case physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeReport.FAN_MODE_LOW:
-			map.value = "on"
+			map.value = "fanOn"
 			break
 		case physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeReport.FAN_MODE_CIRCULATION:
-			map.value = "circulate"
+			map.value = "fanCirculate"
 			break
 	}
 	state.lastTriedFanMode = map.value
-	sendEvent(map)
+	createEvent(map)
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatmodev2.ThermostatModeSupportedReport cmd) {
-	def supportedModes = []
-	if(cmd.heat) { supportedModes << "heat" }
-	if(cmd.cool) { supportedModes << "cool" }
-	// Make sure off is before auto, this ensures the right setpoint is used based on current temperature when auto is set
-	if(cmd.off) { supportedModes << "off" }
-	if(cmd.auto) { supportedModes << "auto" }
-	if(cmd.auxiliaryemergencyHeat) { supportedModes << "emergency heat" }
+	def supportedModes = ""
+	if(cmd.off) { supportedModes += "off " }
+	if(cmd.heat) { supportedModes += "heat " }
+	if(cmd.auxiliaryemergencyHeat) { supportedModes += "emergency heat " }
+	if(cmd.cool) { supportedModes += "cool " }
+	if(cmd.auto) { supportedModes += "auto " }
 
 	state.supportedModes = supportedModes
-	sendEvent(name: "supportedThermostatModes", value: supportedModes, isStateChange: true, displayed: false)
+	[ createEvent(name:"supportedModes", value: supportedModes, displayed: false),
+	  response(zwave.thermostatFanModeV3.thermostatFanModeSupportedGet()) ]
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.thermostatfanmodev3.ThermostatFanModeSupportedReport cmd) {
-	def supportedFanModes = []
-	if(cmd.auto) { supportedFanModes << "auto" }
-	if(cmd.low) { supportedFanModes << "on" }
-	if(cmd.circulation) { supportedFanModes << "circulate" }
+	def supportedFanModes = ""
+	if(cmd.auto) { supportedFanModes += "fanAuto " }
+	if(cmd.low) { supportedFanModes += "fanOn " }
+	if(cmd.circulation) { supportedFanModes += "fanCirculate " }
 
 	state.supportedFanModes = supportedFanModes
-	sendEvent(name: "supportedThermostatFanModes", value: supportedFanModes, isStateChange: true, displayed: false)
+	[ createEvent(name:"supportedFanModes", value: supportedModes, displayed: false),
+	  response(refresh()) ]
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.basicv1.BasicReport cmd) {
-	log.debug "Zwave BasicReport: $cmd"
+	log.debug "Zwave event received: $cmd"
 }
 
 def zwaveEvent(physicalgraph.zwave.commands.batteryv1.BatteryReport cmd) {
-	def batteryState = cmd.batteryLevel
-	def map = [name: "battery", unit: "%", value: cmd.batteryLevel]
-	if ((cmd.batteryLevel == 0xFF) || (cmd.batteryLevel == 0x00)) {  // Special value for low battery alert
+	def map = [ name: "battery", unit: "%" ]
+	if (cmd.batteryLevel == 0xFF) {
 		map.value = 1
 		map.descriptionText = "${device.displayName} battery is low"
 		map.isStateChange = true
-		batteryState = "low_battery"
+	} else {
+		map.value = cmd.batteryLevel
 	}
 	state.lastbatt = now()
-	sendEvent(name: "batteryIcon", value: batteryState, displayed: false)
-	sendEvent(map)
+	createEvent(map)
 }
 
 def zwaveEvent(physicalgraph.zwave.Command cmd) {
 	log.warn "Unexpected zwave command $cmd"
 }
 
-def zwaveEvent(physicalgraph.zwave.commands.manufacturerspecificv2.ManufacturerSpecificReport cmd) {
-log.debug "ManufacturerSpecificReport ${cmd}: value:${cmd}"
-	if (cmd.manufacturerName) {
-		updateDataValue("manufacturer", cmd.manufacturerName)
-	}
-	if (cmd.productTypeId) {
-		updateDataValue("productTypeId", cmd.productTypeId.toString())
-	}
-	if (cmd.productId) {
-		updateDataValue("productId", cmd.productId.toString())
-	}
-}
-
 def refresh() {
-	// Only allow refresh every 2 minutes to prevent flooding the Zwave network
-	def timeNow = now()
-	if (!state.refreshTriggeredAt || (2 * 60 * 1000 < (timeNow - state.refreshTriggeredAt))) {
-		state.refreshTriggeredAt = timeNow
-		// refresh will request battery, prevent multiple request by setting lastbatt now
-		state.lastbatt = timeNow
-		// use runIn with overwrite to prevent multiple DTH instances run before state.refreshTriggeredAt has been saved
-		runIn(2, "poll", [overwrite: true])
+	// Use encapsulation to differentiate refresh cmds from what the thermostat sends proactively on change
+	def cmd = zwave.sensorMultilevelV2.sensorMultilevelGet()
+	zwave.multiChannelV3.multiChannelCmdEncap(destinationEndPoint:1).encapsulate(cmd).format()
+}
+
+def nextRefreshQuery(name) {
+	def cmd = null
+	switch (name) {
+		case "temperature":
+			cmd = zwave.thermostatModeV2.thermostatModeGet()
+			break
+		case "thermostatMode":
+			cmd = zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 1)
+			break
+		case "heatingSetpoint":
+			cmd = zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 2)
+			break
+		case "coolingSetpoint":
+			cmd = zwave.thermostatFanModeV3.thermostatFanModeGet()
+			break
+		case "thermostatFanMode":
+			cmd = zwave.thermostatOperatingStateV2.thermostatOperatingStateGet()
+			break
+		case "thermostatOperatingState":
+			// get humidity, multilevel sensor get to endpoint 2
+			cmd = zwave.sensorMultilevelV2.sensorMultilevelGet()
+			return zwave.multiChannelV3.multiChannelCmdEncap(destinationEndPoint:2).encapsulate(cmd).format()
+		default: return null
 	}
+	zwave.multiChannelV3.multiChannelCmdEncap(destinationEndPoint:1).encapsulate(cmd).format()
 }
 
-def poll() {
-	def cmds = []
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatModeV2.thermostatModeSupportedGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatFanModeV3.thermostatFanModeSupportedGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.multiChannelV3.multiInstanceCmdEncap(instance: 1).encapsulate(zwave.sensorMultilevelV3.sensorMultilevelGet()).format()) // temperature
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatModeV2.thermostatModeGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatFanModeV3.thermostatFanModeGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatOperatingStateV1.thermostatOperatingStateGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 1).format()) // HeatingSetpoint
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 2).format()) // CoolingSetpoint
-	cmds << new physicalgraph.device.HubAction(zwave.batteryV1.batteryGet().format())
-	cmds << new physicalgraph.device.HubAction(zwave.multiChannelV3.multiInstanceCmdEncap(instance: 2).encapsulate(zwave.sensorMultilevelV3.sensorMultilevelGet()).format()) // humidity
-	def time = getTimeAndDay()
-log.debug "time: $time"
-	if (time) {
-		cmds << new physicalgraph.device.HubAction(zwave.clockV1.clockSet(time).format())
-	}
-	// Add 3 seconds delay between each command to avoid flooding the Z-Wave network choking the hub 
-	sendHubCommand(cmds, 3000)
+def quickSetHeat(degrees) {
+	setHeatingSetpoint(degrees, 1000)
 }
 
-def raiseHeatingSetpoint() {
-	alterSetpoint(null, true, "heatingSetpoint")
+def setHeatingSetpoint(degrees, delay = 30000) {
+	setHeatingSetpoint(degrees.toDouble(), delay)
 }
 
-def lowerHeatingSetpoint() {
-	alterSetpoint(null, false, "heatingSetpoint")
-}
-
-def raiseCoolSetpoint() {
-	alterSetpoint(null, true, "coolingSetpoint")
-}
-
-def lowerCoolSetpoint() {
-	alterSetpoint(null, false, "coolingSetpoint")
-}
-
-// Adjusts nextHeatingSetpoint either .5° C/1° F) if raise true/false
-def alterSetpoint(degrees, raise, setpoint) {
+def setHeatingSetpoint(Double degrees, Integer delay = 30000) {
+	log.trace "setHeatingSetpoint($degrees, $delay)"
+	def deviceScale = state.scale ?: 1
+	def deviceScaleString = deviceScale == 2 ? "C" : "F"
 	def locationScale = getTemperatureScale()
-	def heatingSetpoint = getTempInLocalScale("heatingSetpoint")
-	def coolingSetpoint = getTempInLocalScale("coolingSetpoint")
-	def targetvalue = (setpoint == "heatingSetpoint") ? heatingSetpoint : coolingSetpoint
-	def delta = (locationScale == "F") ? 1 : 0.5
-	if (raise != null) {
-		targetvalue += raise ? delta : - delta
-	} else if (degrees) {
-		targetvalue = degrees
+	def p = (state.precision == null) ? 1 : state.precision
+
+	def convertedDegrees
+	if (locationScale == "C" && deviceScaleString == "F") {
+		convertedDegrees = celsiusToFahrenheit(degrees)
+	} else if (locationScale == "F" && deviceScaleString == "C") {
+		convertedDegrees = fahrenheitToCelsius(degrees)
 	} else {
-		log.warn "alterSetpoint called with neither up/down/degree information"
-		return
-	}
-	def data = enforceSetpointLimits(setpoint, [targetvalue: targetvalue, heatingSetpoint: heatingSetpoint, coolingSetpoint: coolingSetpoint])
-	// update UI without waiting for the device to respond, this to give user a smoother UI experience
-	// also, as runIn's have to overwrite and user can change heating/cooling setpoint separately separate runIn's have to be used
-	if (data.targetHeatingSetpoint) {
-		sendEvent("name": "heatingSetpoint", "value": data.targetHeatingSetpoint, unit: locationScale, eventType: "ENTITY_UPDATE")//, displayed: false)
-		runIn(4, "updateHeatingSetpoint", [data: data, overwrite: true])
-	}
-	if (data.targetCoolingSetpoint) {
-		sendEvent("name": "coolingSetpoint", "value": data.targetCoolingSetpoint, unit: locationScale, eventType: "ENTITY_UPDATE")//, displayed: false)
-		runIn(4, "updateCoolingSetpoint", [data: data, overwrite: true])
+		convertedDegrees = degrees
 	}
+
+	delayBetween([
+		zwave.thermostatSetpointV1.thermostatSetpointSet(setpointType: 1, scale: deviceScale, precision: p, scaledValue: convertedDegrees).format(),
+		zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 1).format()
+	], delay)
 }
 
-def updateHeatingSetpoint(data) {
-	updateSetpoints(data)
+def quickSetCool(degrees) {
+	setCoolingSetpoint(degrees, 1000)
 }
 
-def updateCoolingSetpoint(data) {
-	updateSetpoints(data)
+def setCoolingSetpoint(degrees, delay = 30000) {
+	setCoolingSetpoint(degrees.toDouble(), delay)
 }
 
-def enforceSetpointLimits(setpoint, data) {
-	// Enforce max/min for setpoints
-	def maxSetpoint = getTempInLocalScale(95, "F")
-	def minSetpoint = getTempInLocalScale(35, "F")
-	def targetvalue = data.targetvalue
-	def heatingSetpoint = null
-	def coolingSetpoint = null
-
-	if (targetvalue > maxSetpoint) {
-		targetvalue = maxSetpoint
-	} else if (targetvalue < minSetpoint) {
-		targetvalue = minSetpoint
-	}
-	// Enforce limits, for now make sure heating <= cooling, and cooling >= heating
-	if (setpoint == "heatingSetpoint") {
-		heatingSetpoint = targetvalue
-		coolingSetpoint = (heatingSetpoint > data.coolingSetpoint) ? heatingSetpoint : null
-	}
-	if (setpoint == "coolingSetpoint") {
-		coolingSetpoint = targetvalue
-		heatingSetpoint = (coolingSetpoint < data.heatingSetpoint) ? coolingSetpoint : null
-	}
-	return [targetHeatingSetpoint: heatingSetpoint, targetCoolingSetpoint: coolingSetpoint]
-}
-
-def setHeatingSetpoint(degrees) {
-	if (degrees) {
-		def data = enforceSetpointLimits("heatingSetpoint",
-				[targetvalue: degrees.toDouble(), heatingSetpoint: getTempInLocalScale("heatingSetpoint"), coolingSetpoint: getTempInLocalScale("coolingSetpoint")])
-		updateSetpoints(data)
-	}
-}
-
-def setCoolingSetpoint(degrees) {
-	if (degrees) {
-		def data = enforceSetpointLimits("coolingSetpoint",
-				[targetvalue: degrees.toDouble(), heatingSetpoint: getTempInLocalScale("heatingSetpoint"), coolingSetpoint: getTempInLocalScale("coolingSetpoint")])
-		updateSetpoints(data)
-	}
-}
-
-def updateSetpoints(data) {
-	def cmds = []
-	if (data.targetHeatingSetpoint) {
-		cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointSet(
-					setpointType: 1, scale: state.scale, precision: state.precision, scaledValue: convertToDeviceScale(data.targetHeatingSetpoint)).format())
-	}
-	if (data.targetCoolingSetpoint) {
-		cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointSet(
-					setpointType: 2, scale: state.scale, precision: state.precision, scaledValue: convertToDeviceScale(data.targetCoolingSetpoint)).format())
-	}
-
-	// Always request both setpoints in case thermostat changed both
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 1).format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 2).format())
-	sendHubCommand(cmds)
-}
-
-def convertToDeviceScale(setpoint) {
+def setCoolingSetpoint(Double degrees, Integer delay = 30000) {
+	log.trace "setCoolingSetpoint($degrees, $delay)"
+	def deviceScale = state.scale ?: 1
+	def deviceScaleString = deviceScale == 2 ? "C" : "F"
 	def locationScale = getTemperatureScale()
-	def deviceScale = (state.scale == 1) ? "F" : "C"
-	return (deviceScale == locationScale) ? setpoint :
-		(deviceScale == "F" ? celsiusToFahrenheit(setpoint.toBigDecimal()) : roundC(fahrenheitToCelsius(setpoint.toBigDecimal())))
+	def p = (state.precision == null) ? 1 : state.precision
+
+	def convertedDegrees
+	if (locationScale == "C" && deviceScaleString == "F") {
+		convertedDegrees = celsiusToFahrenheit(degrees)
+	} else if (locationScale == "F" && deviceScaleString == "C") {
+		convertedDegrees = fahrenheitToCelsius(degrees)
+	} else {
+		convertedDegrees = degrees
+	}
+
+	delayBetween([
+		zwave.thermostatSetpointV1.thermostatSetpointSet(setpointType: 2, scale: deviceScale, precision: p,	 scaledValue: convertedDegrees).format(),
+		zwave.thermostatSetpointV1.thermostatSetpointGet(setpointType: 2).format()
+	], delay)
 }
 
 /**
@@ -537,56 +456,78 @@ def convertToDeviceScale(setpoint) {
  * */
 def ping() {
 	log.debug "ping() called"
-	// Just get Operating State as it is not reported when it chnages and there's no need to flood more commands
-	sendHubCommand(new physicalgraph.device.HubAction(zwave.thermostatOperatingStateV1.thermostatOperatingStateGet().format()))
+	refresh()
+}
+
+def configure() {
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSupportedGet().format(),
+	], 2300)
+}
+
+def modes() {
+	["off", "heat", "cool", "auto", "emergency heat"]
 }
 
 def switchMode() {
-	def currentMode = device.currentValue("thermostatMode")
+	def currentMode = device.currentState("thermostatMode")?.value
 	def lastTriedMode = state.lastTriedMode ?: currentMode ?: "off"
-	def supportedModes = state.supportedModes
-	if (supportedModes) {
-		def next = { supportedModes[supportedModes.indexOf(it) + 1] ?: supportedModes[0] }
-		def nextMode = next(lastTriedMode)
-		setThermostatMode(nextMode)
-		state.lastTriedMode = nextMode
-	} else {
-		log.warn "supportedModes not defined"
+	def supportedModes = getDataByName("supportedModes")
+	def modeOrder = modes()
+	def next = { modeOrder[modeOrder.indexOf(it) + 1] ?: modeOrder[0] }
+	def nextMode = next(lastTriedMode)
+	if (supportedModes?.contains(currentMode)) {
+		while (!supportedModes.contains(nextMode) && nextMode != "off") {
+			nextMode = next(nextMode)
+		}
 	}
+	state.lastTriedMode = nextMode
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: modeMap[nextMode]).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], 1000)
 }
 
 def switchToMode(nextMode) {
-	def supportedModes = state.supportedModes
-	if (supportedModes && supportedModes.contains(nextMode)) {
-		setThermostatMode(nextMode)
+	def supportedModes = getDataByName("supportedModes")
+	if(supportedModes && !supportedModes.contains(nextMode)) log.warn "thermostat mode '$nextMode' is not supported"
+	if (nextMode in modes()) {
 		state.lastTriedMode = nextMode
+		"$nextMode"()
 	} else {
-		log.debug("ThermostatMode $nextMode is not supported by ${device.displayName}")
+		log.debug("no mode method '$nextMode'")
 	}
 }
 
 def switchFanMode() {
 	def currentMode = device.currentState("thermostatFanMode")?.value
 	def lastTriedMode = state.lastTriedFanMode ?: currentMode ?: "off"
-	def supportedFanModes = state.supportedFanModes
-	if (supportedFanModes) {
-		def next = { supportedFanModes[supportedFanModes.indexOf(it) + 1] ?: supportedFanModes[0] }
-		def nextMode = next(lastTriedMode)
-		setThermostatFanMode(nextMode)
-		state.lastTriedFanMode = nextMode
-	} else {
-		log.warn "supportedFanModes not defined"
+	def supportedModes = getDataByName("supportedFanModes") ?: "fanAuto fanOn"
+	def modeOrder = ["fanAuto", "fanCirculate", "fanOn"]
+	def next = { modeOrder[modeOrder.indexOf(it) + 1] ?: modeOrder[0] }
+	def nextMode = next(lastTriedMode)
+	while (!supportedModes?.contains(nextMode) && nextMode != "fanAuto") {
+		nextMode = next(nextMode)
 	}
+	switchToFanMode(nextMode)
 }
 
 def switchToFanMode(nextMode) {
-	def supportedFanModes = state.supportedFanModes
-	if (supportedFanModes && supportedFanModes.contains(nextMode)) {
-		setThermostatFanMode(nextMode)
-		state.lastTriedFanMode = nextMode
+	def supportedFanModes = getDataByName("supportedFanModes")
+	if(supportedFanModes && !supportedFanModes.contains(nextMode)) log.warn "thermostat mode '$nextMode' is not supported"
+
+	def returnCommand
+	if (nextMode == "fanAuto") {
+		returnCommand = fanAuto()
+	} else if (nextMode == "fanOn") {
+		returnCommand = fanOn()
+	} else if (nextMode == "fanCirculate") {
+		returnCommand = fanCirculate()
 	} else {
-		log.debug("FanMode $nextMode is not supported by ${device.displayName}")
+		log.debug("no fan mode '$nextMode'")
 	}
+	if(returnCommand) state.lastTriedFanMode = nextMode
+	returnCommand
 }
 
 def getDataByName(String name) {
@@ -602,10 +543,10 @@ def getModeMap() { [
 ]}
 
 def setThermostatMode(String value) {
-	def cmds = []
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatModeV2.thermostatModeSet(mode: modeMap[value]).format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatModeV2.thermostatModeGet().format())
-	sendHubCommand(cmds)
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: modeMap[value]).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def getFanModeMap() { [
@@ -615,70 +556,69 @@ def getFanModeMap() { [
 ]}
 
 def setThermostatFanMode(String value) {
-	def cmds = []
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatFanModeV3.thermostatFanModeSet(fanMode: fanModeMap[value]).format())
-	cmds << new physicalgraph.device.HubAction(zwave.thermostatFanModeV3.thermostatFanModeGet().format())
-	sendHubCommand(cmds)
+	delayBetween([
+		zwave.thermostatFanModeV3.thermostatFanModeSet(fanMode: fanModeMap[value]).format(),
+		zwave.thermostatFanModeV3.thermostatFanModeGet().format()
+	], standardDelay)
 }
 
 def off() {
-	switchToMode("off")
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: 0).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def heat() {
-	switchToMode("heat")
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: 1).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def emergencyHeat() {
-	switchToMode("emergency heat")
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: 4).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def cool() {
-	switchToMode("cool")
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: 2).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def auto() {
-	switchToMode("auto")
+	delayBetween([
+		zwave.thermostatModeV2.thermostatModeSet(mode: 3).format(),
+		zwave.thermostatModeV2.thermostatModeGet().format()
+	], standardDelay)
 }
 
 def fanOn() {
-	switchToFanMode("on")
+	delayBetween([
+		zwave.thermostatFanModeV3.thermostatFanModeSet(fanMode: 1).format(),
+		zwave.thermostatFanModeV3.thermostatFanModeGet().format()
+	], standardDelay)
 }
 
 def fanAuto() {
-	switchToFanMode("auto")
+	delayBetween([
+		zwave.thermostatFanModeV3.thermostatFanModeSet(fanMode: 0).format(),
+		zwave.thermostatFanModeV3.thermostatFanModeGet().format()
+	], standardDelay)
 }
 
 def fanCirculate() {
-	switchToFanMode("circulate")
+	delayBetween([
+		zwave.thermostatFanModeV3.thermostatFanModeSet(fanMode: 6).format(),
+		zwave.thermostatFanModeV3.thermostatFanModeGet().format()
+	], standardDelay)
 }
 
-private getTimeAndDay() {
-	def timeNow = now()
-	// Need to check that location have timeZone as SC may have created the location without setting it
-	// Don't update clock more than once a day
-	if (location.timeZone && (!state.timeClockSet || (24 * 60 * 60 * 1000 < (timeNow - state.timeClockSet)))) {
-		def currentDate = Calendar.getInstance(location.timeZone)
-		state.timeClockSet = timeNow
-		return [hour: currentDate.get(Calendar.HOUR_OF_DAY), minute: currentDate.get(Calendar.MINUTE), weekday: currentDate.get(Calendar.DAY_OF_WEEK)]
-	}
+private getStandardDelay() {
+	1000
 }
 
-// Get stored temperature from currentState in current local scale
-def getTempInLocalScale(state) {
-	def temp = device.currentState(state)
-	if (temp && temp.value && temp.unit) {
-		return getTempInLocalScale(temp.value.toBigDecimal(), temp.unit)
-	}
-	return 0
-}
-
-// get/convert temperature to current local scale
-def getTempInLocalScale(temp, scale) {
-	def scaledTemp = convertTemperatureIfNeeded(temp.toBigDecimal(), scale).toDouble()
-	return (getTemperatureScale() == "F" ? scaledTemp.round(0).toInteger() : roundC(scaledTemp))
-}
-
-def roundC (tempC) {
-	return (Math.round(tempC.toDouble() * 2))/2
-}

devicetypes/smartthings/smartsense-motion-sensor.src/smartsense-motion-sensor.groovy

@@ -173,27 +173,11 @@ private Map getBatteryResult(rawValue) {
 		} else {
 			def minVolts = 2.4
 			def maxVolts = 2.7
-			// Get the current battery percentage as a multiplier 0 - 1
-			def curValVolts = Integer.parseInt(device.currentState("battery")?.value ?: "100") / 100.0
-			// Find the corresponding voltage from our range
-			curValVolts = curValVolts * (maxVolts - minVolts) + minVolts
-			// Round to the nearest 10th of a volt
-			curValVolts = Math.round(10 * curValVolts) / 10.0
-			// Only update the battery reading if we don't have a last reading,
-			// OR we have received the same reading twice in a row
-			// OR we don't currently have a battery reading
-			// OR the value we just received is at least 2 steps off from the last reported value
-			if(state?.lastVolts == null || state?.lastVolts == volts || device.currentState("battery")?.value == null || Math.abs(curValVolts - volts) > 0.1) {
-				def pct = (volts - minVolts) / (maxVolts - minVolts)
-				def roundedPct = Math.round(pct * 100)
-				if (roundedPct <= 0)
-					roundedPct = 1
-				result.value = Math.min(100, roundedPct)
-			} else {
-				// Don't update as we want to smooth the battery values
-				result = null
-			}
-			state.lastVolts = volts
+			def pct = (volts - minVolts) / (maxVolts - minVolts)
+			def roundedPct = Math.round(pct * 100)
+			if (roundedPct <= 0)
+				roundedPct = 1
+			result.value = Math.min(100, roundedPct)
 		}
 	}
 

devicetypes/smartthings/smartsense-multi-sensor.src/smartsense-multi-sensor.groovy

@@ -275,27 +275,11 @@ private Map getBatteryResult(rawValue) {
 		} else {
 			def minVolts = 2.1
 			def maxVolts = 2.7
-			// Get the current battery percentage as a multiplier 0 - 1
-			def curValVolts = Integer.parseInt(device.currentState("battery")?.value ?: "100") / 100.0
-			// Find the corresponding voltage from our range
-			curValVolts = curValVolts * (maxVolts - minVolts) + minVolts
-			// Round to the nearest 10th of a volt
-			curValVolts = Math.round(10 * curValVolts) / 10.0
-			// Only update the battery reading if we don't have a last reading,
-			// OR we have received the same reading twice in a row
-			// OR we don't currently have a battery reading
-			// OR the value we just received is at least 2 steps off from the last reported value
-			if(state?.lastVolts == null || state?.lastVolts == volts || device.currentState("battery")?.value == null || Math.abs(curValVolts - volts) > 0.1) {
-				def pct = (volts - minVolts) / (maxVolts - minVolts)
-				def roundedPct = Math.round(pct * 100)
-				if (roundedPct <= 0)
-					roundedPct = 1
-				result.value = Math.min(100, roundedPct)
-			} else {
-				// Don't update as we want to smooth the battery values
-				result = null
-			}
-			state.lastVolts = volts
+			def pct = (volts - minVolts) / (maxVolts - minVolts)
+			def roundedPct = Math.round(pct * 100)
+			if (roundedPct <= 0)
+				roundedPct = 1
+			result.value = Math.min(100, roundedPct)
 		}
 	}
 

devicetypes/smartthings/zwave-basic-smoke-alarm.src/.st-ignore

@@ -1,2 +0,0 @@
-.st-ignore
-README.md

devicetypes/smartthings/zwave-basic-smoke-alarm.src/README.md

@@ -1,39 +0,0 @@
-# Z-wave Basic Smoke Alarm
-
-Cloud Execution
-
-Works with: 
-
-* [First Alert Smoke Detector (ZSMOKE)](https://www.smartthings.com/products/first-alert-smoke-detector)
-
-## Table of contents
-
-* [Capabilities](#capabilities)
-* [Health](#device-health)
-* [Battery](#battery-specification)
-* [Troubleshooting](#troubleshooting)
-
-## Capabilities
-
-* **Smoke Detector** - measure smoke and optionally carbon monoxide levels
-* **Sensor** - detects sensor events
-* **Battery** - defines device uses a battery
-* **Health Check** - indicates ability to get device health notifications
-
-## Device Health
-
-First Alert Smoke Detector (ZSMOKE) is a Z-wave sleepy device and checks in every 1 hour.
-Device-Watch allows 2 check-in misses from device plus some lag time. So Check-in interval = (2*60 + 2)mins = 122 mins.
-
-* __122min__ checkInterval
-
-## Battery Specification
-
-Two AA 1.5V batteries are required.
-
-## Troubleshooting
-
-If the device doesn't pair when trying from the SmartThings mobile app, it is possible that the device is out of range.
-Pairing needs to be tried again by placing the device closer to the hub.
-Instructions related to pairing, resetting and removing the device from SmartThings can be found in the following link:
-* [First Alert Smoke Detector (ZSMOKE) Troubleshooting Tips](https://support.smartthings.com/hc/en-us/articles/207150556-First-Alert-Smoke-Detector-ZSMOKE-)

devicetypes/smartthings/zwave-basic-smoke-alarm.src/zwave-basic-smoke-alarm.groovy

@@ -1,181 +0,0 @@
-/**
- *  Copyright 2015 SmartThings
- *
- *  Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
- *  in compliance with the License. You may obtain a copy of the License at:
- *
- *      http://www.apache.org/licenses/LICENSE-2.0
- *
- *  Unless required by applicable law or agreed to in writing, software distributed under the License is distributed
- *  on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
- *  for the specific language governing permissions and limitations under the License.
- *
- */
-metadata {
-	definition (name: "Z-Wave Basic Smoke Alarm", namespace: "smartthings", author: "SmartThings") {
-		capability "Smoke Detector"
-		capability "Sensor"
-		capability "Battery"
-		capability "Health Check"
-
-		fingerprint deviceId: "0xA100", inClusters: "0x20,0x80,0x70,0x85,0x71,0x72,0x86"
-		fingerprint mfr:"0138", prod:"0001", model:"0001", deviceJoinName: "First Alert Smoke Detector"
-	}
-
-	simulator {
-		status "smoke": "command: 7105, payload: 01 FF"
-		status "clear": "command: 7105, payload: 01 00"
-		status "test": "command: 7105, payload: 0C FF"
-		status "battery 100%": "command: 8003, payload: 64"
-		status "battery 5%": "command: 8003, payload: 05"
-	}
-
-	tiles (scale: 2){
-		multiAttributeTile(name:"smoke", type: "lighting", width: 6, height: 4){
-			tileAttribute ("device.smoke", key: "PRIMARY_CONTROL") {
-				attributeState("clear", label:"clear", icon:"st.alarm.smoke.clear", backgroundColor:"#ffffff")
-				attributeState("detected", label:"SMOKE", icon:"st.alarm.smoke.smoke", backgroundColor:"#e86d13")
-				attributeState("tested", label:"TEST", icon:"st.alarm.smoke.test", backgroundColor:"#e86d13")
-			}
-		}
-		valueTile("battery", "device.battery", inactiveLabel: false, decoration: "flat", width: 2, height: 2) {
-			state "battery", label:'${currentValue}% battery', unit:""
-		}
-
-		main "smoke"
-		details(["smoke", "battery"])
-	}
-}
-
-def installed() {
-// Device checks in every hour, this interval allows us to miss one check-in notification before marking offline
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
-
-	def cmds = []
-	createSmokeEvents("smokeClear", cmds)
-	cmds.each { cmd -> sendEvent(cmd) }
-}
-
-def updated() {
-// Device checks in every hour, this interval allows us to miss one check-in notification before marking offline
-	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
-}
-
-def parse(String description) {
-	def results = []
-	if (description.startsWith("Err")) {
-	    results << createEvent(descriptionText:description, displayed:true)
-	} else {
-		def cmd = zwave.parse(description, [ 0x80: 1, 0x84: 1, 0x71: 2, 0x72: 1 ])
-		if (cmd) {
-			zwaveEvent(cmd, results)
-		}
-	}
-	log.debug "'$description' parsed to ${results.inspect()}"
-	return results
-}
-
-def createSmokeEvents(name, results) {
-	def text = null
-	switch (name) {
-		case "smoke":
-			text = "$device.displayName smoke was detected!"
-			// these are displayed:false because the composite event is the one we want to see in the app
-			results << createEvent(name: "smoke",          value: "detected", descriptionText: text)
-			break
-		case "tested":
-			text = "$device.displayName was tested"
-			results << createEvent(name: "smoke",          value: "tested", descriptionText: text)
-			break
-		case "smokeClear":
-			text = "$device.displayName smoke is clear"
-			results << createEvent(name: "smoke",          value: "clear", descriptionText: text)
-			name = "clear"
-			break
-		case "testClear":
-			text = "$device.displayName test cleared"
-			results << createEvent(name: "smoke",          value: "clear", descriptionText: text)
-			name = "clear"
-			break
-	}
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.alarmv2.AlarmReport cmd, results) {
-	if (cmd.zwaveAlarmType == physicalgraph.zwave.commands.alarmv2.AlarmReport.ZWAVE_ALARM_TYPE_SMOKE) {
-		if (cmd.zwaveAlarmEvent == 3) {
-			createSmokeEvents("tested", results)
-		} else {
-			createSmokeEvents((cmd.zwaveAlarmEvent == 1 || cmd.zwaveAlarmEvent == 2) ? "smoke" : "smokeClear", results)
-		}
-	} else switch(cmd.alarmType) {
-		case 1:
-			createSmokeEvents(cmd.alarmLevel ? "smoke" : "smokeClear", results)
-			break
-		case 12:  // test button pressed
-			createSmokeEvents(cmd.alarmLevel ? "tested" : "testClear", results)
-			break
-		case 13:  // sent every hour -- not sure what this means, just a wake up notification?
-			if (cmd.alarmLevel == 255) {
-				results << createEvent(descriptionText: "$device.displayName checked in", isStateChange: false)
-			} else {
-				results << createEvent(descriptionText: "$device.displayName code 13 is $cmd.alarmLevel", isStateChange:true, displayed:false)
-			}
-			
-			// Clear smoke in case they pulled batteries and we missed the clear msg
-			if(device.currentValue("smoke") != "clear") {
-				createSmokeEvents("smokeClear", results)
-			}
-			
-			// Check battery if we don't have a recent battery event
-			if (!state.lastbatt || (now() - state.lastbatt) >= 48*60*60*1000) {
-				results << response(zwave.batteryV1.batteryGet())
-			}
-			break
-		default:
-			results << createEvent(displayed: true, descriptionText: "Alarm $cmd.alarmType ${cmd.alarmLevel == 255 ? 'activated' : cmd.alarmLevel ?: 'deactivated'}".toString())
-			break
-	}
-}
-
-// SensorBinary and SensorAlarm aren't tested, but included to preemptively support future smoke alarms
-//
-def zwaveEvent(physicalgraph.zwave.commands.sensorbinaryv2.SensorBinaryReport cmd, results) {
-	if (cmd.sensorType == physicalgraph.zwave.commandclasses.SensorBinaryV2.SENSOR_TYPE_SMOKE) {
-		createSmokeEvents(cmd.sensorValue ? "smoke" : "smokeClear", results)
-	}
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.sensoralarmv1.SensorAlarmReport cmd, results) {
-	if (cmd.sensorType == 1) {
-		createSmokeEvents(cmd.sensorState ? "smoke" : "smokeClear", results)
-	}
-	
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.wakeupv1.WakeUpNotification cmd, results) {
-	results << createEvent(descriptionText: "$device.displayName woke up", isStateChange: false)
-	if (!state.lastbatt || (now() - state.lastbatt) >= 56*60*60*1000) {
-		results << response(zwave.batteryV1.batteryGet(), "delay 2000", zwave.wakeUpV1.wakeUpNoMoreInformation())
-	} else {
-		results << response(zwave.wakeUpV1.wakeUpNoMoreInformation())
-	}
-}
-
-def zwaveEvent(physicalgraph.zwave.commands.batteryv1.BatteryReport cmd, results) {
-	def map = [ name: "battery", unit: "%", isStateChange: true ]
-	state.lastbatt = now()
-	if (cmd.batteryLevel == 0xFF) {
-		map.value = 1
-		map.descriptionText = "$device.displayName battery is low!"
-	} else {
-		map.value = cmd.batteryLevel
-	}
-	results << createEvent(map)
-}
-
-def zwaveEvent(physicalgraph.zwave.Command cmd, results) {
-	def event = [ displayed: false ]
-	event.linkText = device.label ?: device.name
-	event.descriptionText = "$event.linkText: $cmd"
-	results << createEvent(event)
-}

devicetypes/smartthings/zwave-lock.src/zwave-lock.groovy

@@ -88,21 +88,19 @@ import physicalgraph.zwave.commands.usercodev1.*
 def installed() {
 	// Device-Watch pings if no device events received for 1 hour (checkInterval)
 	sendEvent(name: "checkInterval", value: 1 * 60 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
-
-	try {
-		if (!state.init) {
-			state.init = true
-			// Wait long enough for behind-the-scenes z-wave magic to finish, but be quick enough before hub goes back into inclusion and blocks us
-			response(["delay 2000"] + secureSequence([zwave.doorLockV1.doorLockOperationGet(), zwave.batteryV1.batteryGet()], 2200))
-		}
-	} catch (e) {
-		log.warn "installed() threw $e"
-	}
 }
 
 def updated() {
 	// Device-Watch pings if no device events received for 1 hour (checkInterval)
 	sendEvent(name: "checkInterval", value: 1 * 60 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
+	try {
+		if (!state.init) {
+			state.init = true
+			response(secureSequence([zwave.doorLockV1.doorLockOperationGet(), zwave.batteryV1.batteryGet()]))
+		}
+	} catch (e) {
+		log.warn "updated() threw $e"
+	}
 }
 
 def parse(String description) {

devicetypes/smartthings/zwave-siren.src/zwave-siren.groovy

@@ -72,7 +72,7 @@ def createEvents(physicalgraph.zwave.commands.batteryv1.BatteryReport cmd) {
 
 def poll() {
 	if (secondsPast(state.lastbatt, 36*60*60)) {
-		return zwave.batteryV1.batteryGet().format()
+		return zwave.batteryV1.batteryGet().format
 	} else {
 		return null
 	}

devicetypes/smartthings/zwave-smoke-alarm.src/zwave-smoke-alarm.groovy

@@ -21,6 +21,8 @@ metadata {
 
 		attribute "alarmState", "string"
 
+		fingerprint deviceId: "0xA100", inClusters: "0x20,0x80,0x70,0x85,0x71,0x72,0x86"
+		fingerprint mfr:"0138", prod:"0001", model:"0001", deviceJoinName: "First Alert Smoke Detector"
 		fingerprint mfr:"0138", prod:"0001", model:"0002", deviceJoinName: "First Alert Smoke Detector and Carbon Monoxide Alarm (ZCOMBO)"
 	}
 
@@ -55,10 +57,6 @@ metadata {
 def installed() {
 // Device checks in every hour, this interval allows us to miss one check-in notification before marking offline
 	sendEvent(name: "checkInterval", value: 2 * 60 * 60 + 2 * 60, displayed: false, data: [protocol: "zwave", hubHardwareId: device.hub.hardwareID])
-
-	def cmds = []
-	createSmokeOrCOEvents("allClear", cmds) // allClear to set inital states for smoke and CO
-	cmds.each { cmd -> sendEvent(cmd) }
 }
 
 def updated() {
@@ -107,12 +105,6 @@ def createSmokeOrCOEvents(name, results) {
 			results << createEvent(name: "carbonMonoxide", value: "clear", descriptionText: text, displayed: false)
 			name = "clear"
 			break
-		case "allClear":
-			text = "$device.displayName all clear"
-			results << createEvent(name: "smoke",          value: "clear", descriptionText: text, displayed: false)
-			results << createEvent(name: "carbonMonoxide", value: "clear", displayed: false)
-			name = "clear"
-			break
 		case "testClear":
 			text = "$device.displayName test cleared"
 			results << createEvent(name: "smoke",          value: "clear", descriptionText: text, displayed: false)

smartapps/opent2t/opent2t-smartapp-test.src/opent2t-smartapp-test.groovy

@@ -2,11 +2,26 @@ import javax.crypto.Mac;
 import javax.crypto.spec.SecretKeySpec;
 import java.security.InvalidKeyException;
 
+/**
+ *  OpenT2T SmartApp Test
+ *
+ *  Copyright 2016 OpenT2T
+ *
+ *  Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
+ *  in compliance with the License. You may obtain a copy of the License at:
+ *
+ *      http://www.apache.org/licenses/LICENSE-2.0
+ *
+ *  Unless required by applicable law or agreed to in writing, software distributed under the License is distributed
+ *  on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
+ *  for the specific language governing permissions and limitations under the License.
+ *
+ */
 definition(
 		name: "OpenT2T SmartApp Test",
 		namespace: "opent2t",
-		author: "Microsoft",
-		description: "SmartApp for end to end SmartThings scenarios via OpenT2T",
+		author: "OpenT2T",
+		description: "Test app to test end to end SmartThings scenarios via OpenT2T",
 		category: "SmartThings Labs",
 		iconUrl: "https://s3.amazonaws.com/smartapp-icons/Convenience/Cat-Convenience.png",
 		iconX2Url: "https://s3.amazonaws.com/smartapp-icons/Convenience/Cat-Convenience@2x.png",
@@ -40,16 +55,16 @@ definition(
 
 //Device Inputs
 preferences {
-	section("Allow Microsoft to control these things...") {
-//		input "contactSensors", "capability.contactSensor", title: "Which Contact Sensors", multiple: true, required: false, hideWhenEmpty: true
-//		input "garageDoors", "capability.garageDoorControl", title: "Which Garage Doors?", multiple: true, required: false, hideWhenEmpty: true
-//		input "locks", "capability.lock", title: "Which Locks?", multiple: true, required: false, hideWhenEmpty: true
-//		input "cameras", "capability.videoCapture", title: "Which Cameras?",  multiple: true, required: false, hideWhenEmpty: true
-//		input "motionSensors", "capability.motionSensor", title: "Which Motion Sensors?", multiple: true, required: false, hideWhenEmpty: true
-//		input "presenceSensors", "capability.presenceSensor", title: "Which Presence Sensors", multiple: true, required: false, hideWhenEmpty: true
+	section("Allow OpenT2T to control these things...") {
+		input "contactSensors", "capability.contactSensor", title: "Which Contact Sensors", multiple: true, required: false, hideWhenEmpty: true
+		input "garageDoors", "capability.garageDoorControl", title: "Which Garage Doors?", multiple: true, required: false, hideWhenEmpty: true
+		input "locks", "capability.lock", title: "Which Locks?", multiple: true, required: false, hideWhenEmpty: true
+		input "cameras", "capability.videoCapture", title: "Which Cameras?", multiple: true, required: false, hideWhenEmpty: true
+		input "motionSensors", "capability.motionSensor", title: "Which Motion Sensors?", multiple: true, required: false, hideWhenEmpty: true
+		input "presenceSensors", "capability.presenceSensor", title: "Which Presence Sensors", multiple: true, required: false, hideWhenEmpty: true
 		input "switches", "capability.switch", title: "Which Switches and Lights?", multiple: true, required: false, hideWhenEmpty: true
 		input "thermostats", "capability.thermostat", title: "Which Thermostat?", multiple: true, required: false, hideWhenEmpty: true
-//		input "waterSensors", "capability.waterSensor", title: "Which Water Leak Sensors?", multiple: true, required: false, hideWhenEmpty: true
+		input "waterSensors", "capability.waterSensor", title: "Which Water Leak Sensors?", multiple: true, required: false, hideWhenEmpty: true
 	}
 }
 
@@ -67,32 +82,36 @@ def getInputs() {
 	return inputList
 }
 
-
 //API external Endpoints
 mappings {
 	path("/devices") {
-		action: [
+		action:
+		[
 				GET: "getDevices"
 		]
 	}
 	path("/devices/:id") {
-		action: [
+		action:
+		[
 				GET: "getDevice"
 		]
 	}
 	path("/update/:id") {
-		action: [
+		action:
+		[
 				PUT: "updateDevice"
 		]
 	}
 	path("/deviceSubscription") {
-		action: [
+		action:
+		[
 				POST  : "registerDeviceChange",
 				DELETE: "unregisterDeviceChange"
 		]
 	}
 	path("/locationSubscription") {
-		action: [
+		action:
+		[
 				POST  : "registerDeviceGraph",
 				DELETE: "unregisterDeviceGraph"
 		]
@@ -177,7 +196,7 @@ def registerDeviceChange() {
 				log.info "Added subscription URL: ${subscriptionEndpt} for ${myDevice.displayName}"
 			} else if (!state.deviceSubscriptionMap[deviceId].contains(subscriptionEndpt)) {
 				// state.deviceSubscriptionMap[deviceId] << subscriptionEndpt
-                // For now, we will only have one subscription endpoint per device
+				// For now, we will only have one subscription endpoint per device
 				state.deviceSubscriptionMap.remove(deviceId)
 				state.deviceSubscriptionMap.put(deviceId, [subscriptionEndpt])
 				log.info "Added subscription URL: ${subscriptionEndpt} for ${myDevice.displayName}"
@@ -292,16 +311,16 @@ def deviceEventHandler(evt) {
 	def evtDeviceType = getDeviceType(evtDevice)
 	def deviceData = [];
 
+	if (evt.data != null) {
+		def evtData = parseJson(evt.data)
+		log.info "Received event for ${evtDevice.displayName}, data: ${evtData},  description: ${evt.descriptionText}"
+	}
+
 	if (evtDeviceType == "thermostat") {
 		deviceData = [name: evtDevice.displayName, id: evtDevice.id, status: evtDevice.status, deviceType: evtDeviceType, manufacturer: evtDevice.manufacturerName, model: evtDevice.modelName, attributes: deviceAttributeList(evtDevice, evtDeviceType), locationMode: getLocationModeInfo(), locationId: location.id]
 	} else {
 		deviceData = [name: evtDevice.displayName, id: evtDevice.id, status: evtDevice.status, deviceType: evtDeviceType, manufacturer: evtDevice.manufacturerName, model: evtDevice.modelName, attributes: deviceAttributeList(evtDevice, evtDeviceType), locationId: location.id]
 	}
-    
-    if(evt.data != null){
-		def evtData = parseJson(evt.data)
-		log.info "Received event for ${evtDevice.displayName}, data: ${evtData},  description: ${evt.descriptionText}"
-	}
 
 	def params = [body: deviceData]
 
@@ -311,10 +330,10 @@ def deviceEventHandler(evt) {
 		params.uri = "${it}"
 		if (state.verificationKeyMap[it] != null) {
 			def key = state.verificationKeyMap[it]
-            params.headers = [Signature: ComputHMACValue(key, groovy.json.JsonOutput.toJson(params.body))]
+			params.header = [Signature: ComputHMACValue(key, groovy.json.JsonOutput.toJson(params.body))]
 		}
 		log.trace "POST URI: ${params.uri}"
-        log.trace "Headers: ${params.headers}"
+		log.trace "Header: ${params.header}"
 		log.trace "Payload: ${params.body}"
 		try {
 			httpPostJson(params) { resp ->
@@ -344,10 +363,10 @@ def locationEventHandler(evt) {
 				params.uri = "${it}"
 				if (state.verificationKeyMap[it] != null) {
 					def key = state.verificationKeyMap[it]
-                    params.headers = [Signature: ComputHMACValue(key, groovy.json.JsonOutput.toJson(params.body))]
+					params.header = [Signature: ComputHMACValue(key, groovy.json.JsonOutput.toJson(params.body))]
 				}
 				log.trace "POST URI: ${params.uri}"
-				log.trace "Headers: ${params.headers}"
+				log.trace "Header: ${params.header}"
 				log.trace "Payload: ${params.body}"
 				try {
 					httpPostJson(params) { resp ->
@@ -366,7 +385,6 @@ def locationEventHandler(evt) {
 
 private ComputHMACValue(key, data) {
 	try {
-    	log.debug "data hased: ${data}"
 		SecretKeySpec secretKeySpec = new SecretKeySpec(key.getBytes("UTF-8"), "HmacSHA1")
 		Mac mac = Mac.getInstance("HmacSHA1")
 		mac.init(secretKeySpec)
@@ -489,8 +507,7 @@ private getDeviceType(device) {
 
 	//Loop through the device capability list to determine the device type.
 	capabilities.each { capability ->
-		switch(capability.name.toLowerCase())
-		{
+		switch (capability.name.toLowerCase()) {
 			case "switch":
 				deviceType = "switch"
 
@@ -635,8 +652,7 @@ private mapDeviceCommands(command, value) {
 			if (value == 1 || value == "1" || value == "lock") {
 				resultCommand = "lock"
 				resultValue = ""
-			}
-			else if (value == 0 || value == "0" || value == "unlock") {
+			} else if (value == 0 || value == "0" || value == "unlock") {
 				resultCommand = "unlock"
 				resultValue = ""
 			}