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I'm new to programming but have created using my ardunio a program to upload temperatures, humidity and soil resistance to xively. It works fine when I send less than six data streams up to xively but any more than that at it hangs and the ardunio keeps on resetting. Is there a maximum size of the feed you can upload? Do I have to split up the feed as it's to big? I have shown my code below.

Thanks CJ

#include <SPI.h>
#include <Counti ngStream.h>
#include <Xively.h>
#include <XivelyClient.h>
#include <XivelyDatastream.h>
#include <XivelyFeed.h>
#include <OneWire.h>
#include <DallasTemperature.h>
#include <Ethernet.h>
#include <HttpClient.h>
#include "DHT.h"

#define DHTPIN 8     // what pin DHT is connected to

// Uncomment whatever type you're using!
#define DHTTYPE DHT11   // DHT 11 
//#define DHTTYPE DHT22   // DHT 22  (AM2302)
//#define DHTTYPE DHT21   // DHT 21 (AM2301)




//Dallas temp Data wire is plugged into port 2 on the Arduino
#define ONE_WIRE_BUS 2
#define TEMPERATURE_PRECISION 9

// Setup a oneWire instance to communicate with any OneWire devices (not just     Maxim/Dallas temperature ICs)
OneWire oneWire(ONE_WIRE_BUS);

// Pass our oneWire reference to Dallas Temperature. 
DallasTemperature sensors(&oneWire);



// MAC address for your Ethernet shield
byte mac[] = { };

// Your Xively key to let you upload data
char xivelyKey[] = ""; // enter the key, under API Keys
unsigned long feedId = 1860742399; // enter your feed ID 


DHT dht(DHTPIN, DHTTYPE);
DeviceAddress insideThermometer = { 0x28, 0x22, 0x9C, 0xB3, 0x05, 0x00, 0x00, 0x7C };
DeviceAddress  outsideThermometer   = { 0x28, 0x93, 0x20, 0xB4, 0x05, 0x00, 0x00, 0xA4  };
// Analog input pin that the soil moisture sensor is attached to
const int analogInPin0 = A0;  
const int analogInPin1 = A1;  
const int analogInPin2 = A2;  

int sol;
int sensorValue1; 
int sensorValue2;
int sensorValue3; 
int timer;
int sensorAverage1;
//int outtemp1;

// Define the strings for our datastream IDs
char soilsensor1[] = "SOIL_SENSOR1_CHANNEL";
char soilsensor2[] = "SOIL_SENSOR2_CHANNEL";
char soilsensor3[] = "SOIL_SENSOR3_CHANNEL";
char sensorAverage[] = "SOIL_AVERAGE_CHANNEL";
char polytemp[] = "POLYTUNNEL_TEMPERATURE";
char outtemp[] = "OUTSIDE_TEMPERATURE";
char solenoid[] = "SOLENOID_CHANNEL";
char time[] = "TIME_CHANNEL";



XivelyDatastream datastreams[] = {
XivelyDatastream(soilsensor1, strlen(soilsensor1), DATASTREAM_FLOAT),
XivelyDatastream(soilsensor2, strlen(soilsensor2), DATASTREAM_FLOAT),
XivelyDatastream(soilsensor3, strlen(soilsensor3), DATASTREAM_FLOAT),   
XivelyDatastream(sensorAverage, strlen(sensorAverage), DATASTREAM_FLOAT),
XivelyDatastream(outtemp, strlen(outtemp), DATASTREAM_FLOAT),
XivelyDatastream(polytemp, strlen(polytemp), DATASTREAM_FLOAT),
XivelyDatastream(time, strlen(time), DATASTREAM_FLOAT),
XivelyDatastream(solenoid, strlen(solenoid), DATASTREAM_FLOAT),
};




// Finally, wrap the datastreams into a feed
XivelyFeed feed(feedId, datastreams, 8  /* number of datastreams */);


EthernetClient client;
XivelyClient xivelyclient(client);


// if the readings from the soil sensor drop below this number, then turn on the pump
int dryValue = 700;   


void setup(void)
{
// start serial port
Serial.begin(9600);


// Start up the library
sensors.begin();
pinMode(12, OUTPUT); //solenoid output
pinMode(3, OUTPUT); //moisture sensor 1 power
pinMode(4, OUTPUT); //moisture sensor 2 power
pinMode(5, OUTPUT); //moisture sensor 3 power
pinMode(6, INPUT);           // set pin to input for timer
digitalWrite(6, HIGH);       // turn on pullup resistors


// locate devices on the bus
Serial.println("Starting datastream upload to Xively...");
Serial.println();

while (Ethernet.begin(mac) != 1)
{
Serial.println("Error getting IP address via DHCP, trying again...");
delay(5000);
}
Serial.print("IP address: ");
for (byte thisByte = 0; thisByte < 4; thisByte++)
{
// print the value of each byte of the IP address:
Serial.print(Ethernet.localIP()[thisByte], DEC);
Serial.print(".");
}
Serial.println();



Serial.print(sensors.getDeviceCount(), DEC);

// assign address manually.  the addresses below will beed to be changed
// to valid device addresses on your bus.  device address can be retrieved
// by using either oneWire.search(deviceAddress) or individually via
// sensors.getAddress(deviceAddress, index)


// search for devices on the bus and assign based on an index.  ideally,
// you would do this to initially discover addresses on the bus and then 
// use those addresses and manually assign them (see above) once you know 
// the devices on your bus (and assuming they don't change).
// 
// method 1: by index
if (!sensors.getAddress(insideThermometer, 0)) Serial.println("Unable to find address    for Device 0"); 
if (!sensors.getAddress(outsideThermometer, 1)) Serial.println("Unable to find address for Device 1"); 

// method 2: search()
// search() looks for the next device. Returns 1 if a new address has been
// returned. A zero might mean that the bus is shorted, there are no devices, 
// or you have already retrieved all of them.  It might be a good idea to 
// check the CRC to make sure you didn't get garbage.  The order is 
// deterministic. You will always get the same devices in the same order
//
// Must be called before search()
//oneWire.reset_search();
// assigns the first address found to insideThermometer
//if (!oneWire.search(insideThermometer)) Serial.println("Unable to find address for  insideThermometer");
// assigns the seconds address found to outsideThermometer
//if (!oneWire.search(outsideThermometer)) Serial.println("Unable to find address for outsideThermometer");

// show the addresses we found on the bus


// set the resolution to 9 bit
sensors.setResolution(insideThermometer, TEMPERATURE_PRECISION);
sensors.setResolution(outsideThermometer, TEMPERATURE_PRECISION);


}


// function to print the temperature for a device
void printTemperature(DeviceAddress deviceAddress)
{
float tempC = sensors.getTempC(deviceAddress);
Serial.print("Temp C: ");
Serial.print(tempC);
//read sensor values

dht.begin();  

}


// main function to print information about a device
void printData(DeviceAddress deviceAddress)
{
printTemperature(deviceAddress);
Serial.println();
}



void loop(void)
{ 



digitalWrite(3, HIGH);
delay(100);

int sensorValue1 = analogRead(analogInPin0);
datastreams[0].setFloat(sensorValue1);
Serial.print("moisture sensor1 = " );                       
Serial.println(datastreams[0].getFloat());

digitalWrite(3, LOW);




digitalWrite(4, HIGH);
delay(100);
int sensorValue2 = analogRead(analogInPin1);
datastreams[1].setFloat(sensorValue2);
Serial.print("moisture sensor2 = " );                       
Serial.println(datastreams[1].getFloat());

digitalWrite(4, LOW);  

digitalWrite(5, HIGH);
delay(100);
int sensorValue3 = analogRead(analogInPin2);
datastreams[2].setFloat(sensorValue3);
Serial.print("moisture sensor3 = " );                       
Serial.println(datastreams[2].getFloat());

digitalWrite(5, LOW);
int sensorAverage1 = {((sensorValue1 + sensorValue2 + sensorValue3)/3)};  
datastreams[3].setFloat(sensorAverage1);
Serial.print("moisture average = " );   
Serial.println(sensorAverage1); 

// call sensors.requestTemperatures() to issue a global temperature 
// request to all devices on the bus

sensors.requestTemperatures();




 Serial.print("inside ");
 printData(insideThermometer);

 Serial.print("outside ");
 printData(outsideThermometer);



float tempC1 = sensors.getTempC(outsideThermometer);
datastreams[4].setFloat(tempC1);

float tempC2 = sensors.getTempC(insideThermometer);
datastreams[5].setFloat(tempC2);

timer = digitalRead(6);
delay(100);

Serial.print("timer = " );
Serial.println(timer);
//int tim = digitalRead(6);
datastreams[6].setFloat(timer);
delay(100);


float h = dht.readHumidity();
float t = dht.readTemperature();

// check if returns are valid, if they are NaN (not a number) then something went wrong!
if (isnan(t) || isnan(h)) {
Serial.println("Failed to read from DHT");
} else {
Serial.print("Humidity: "); 
Serial.print(h);
Serial.print(" %\t ");
Serial.print("Temperature: "); 
Serial.print(t);
Serial.println(" *C");
}

if  (timer==0 && sensorAverage1 < dryValue){


digitalWrite(11, HIGH);
sol = digitalRead(11);

Serial.println("solenoid on");
delay(10000);
digitalWrite(11, LOW); 
}
datastreams[7].setFloat(sol);
sol = 0;
//send value to xively
Serial.println("Uploading it to Xively");
int ret = xivelyclient.put(feed, xivelyKey); Serial.print("xivelyclient.put returned ");
Serial.println(ret);
}  
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