Problem with transmitting IMU/GPS/Ultrasonic data over Nrf24L01

having problems geting my sensors to refresh. now i know in the StuffStructBuff function the data is being pulled and sent to the individual elements of the struct StructBuff because i can parse them out to the term from the function so i know there geting filled with constant fresh data streams.
but the main "formatted" buffer seems to stop at 3 strings ( should be 1 but the GPS data is missing for some reason). so it seems strlcat is working and is making a full formatted string and it is making it into the SenBuffersAll array just fine? or not or seems to stop refreshing it. do i need to "flush it?" or some other trick?

here is the output then i will post the code base so far ( might take a couple posts it's kinda big)

<<<||0.00,0.01,0.00|0|>>><<<||-0.78,-0.69,-0.00|1|>>><<<||-0.75,-0.24,-0.00|2|>>><<<||-0.18,0.33,-0.01|3|>>><<<||-0.44,0.87,0.0
<<<||0.00,0.01,0.00|0|>>><<<||-0.78,-0.69,-0.00|1|>>><<<||-0.75,-0.24,-0.00|2|>>><<<||-0.18,0.33,-0.01|3|>>><<<||-0.44,0.87,0.0
<<<||0.00,0.01,0.00|0|>>><<<||-0.78,-0.69,-0.00|1|>>><<<||-0.75,-0.24,-0.00|2|>>><<<||-0.18,0.33,-0.01|3|>>><<<||-0.44,0.87,0.0
<<<||0.00,0.01,0.00|0|>>><<<||-0.78,-0.69,-0.00|1|>>><<<||-0.75,-0.24,-0.00|2|>>><<<||-0.18,0.33,-0.01|3|>>><<<||-0.44,0.87,0.0

now it is correct is size to the array but since the GPS is not parsing in it's bot full to the 128 chars so it fill with the new strings etc.
"SHOULD" look like this IF the GPS was making it in.

<<<|$GPRMC,XXXXXX.00,A,4454.1740,N,XXXXX.0143,W,000.0,128.7,300508,001.1,E,A*2E|-3.87,34.01,0.13|33|>>>

ill post the complete code next.

Part (1)of(2)

#include <NewPing.h>
#include <Arduino.h>
#include <Wire.h>
#include <stdio.h>
#include <nRF24L01.h>
#include <SPI.h>
#include "nRF24L01.h"
#include "RF24.h"
#include "printf.h"
#include <nmea.h>
#include <PString.h>
#include <string.h>
//-+-+-+>>>> START Ultrasonic Sensor section<<<<<<-+-+-+
#define TRIGGER_PIN  23  // Arduino pin tied to trigger pin on the ultrasonic sensor.
#define ECHO_PIN     22  // Arduino pin tied to echo pin on the ultrasonic sensor.
#define MAX_DISTANCE 200 // Maximum distance we want to ping for (in centimeters). Maximum sensor distance is rated at 400-500cm.
//-+-+-+>>>> END Ultrasonic Sensor section<<<<<<-+-+-+
//-+-+-+>>>> START GPS Vars section<<<<<<-+-+-+
#define WPT_IN_RANGE_M 1
//-+-+-+>>>> END GPS Vars section<<<<<<-+-+-+
//-+-+-+>>>> SRTART POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
// LSM303 accelerometer: 8 g sensitivity
// 3.8 mg/digit; 1 g = 256
#define GRAVITY 256  //this equivalent to 1G in the raw data coming from the accelerometer 
#define ToRad(x) ((x)*0.01745329252)  // *pi/180
#define ToDeg(x) ((x)*57.2957795131)  // *180/pi
// L3G4200D gyro: 2000 dps full scale
// 70 mdps/digit; 1 dps = 0.07
#define Gyro_Gain_X 0.07 //X axis Gyro gain
#define Gyro_Gain_Y 0.07 //Y axis Gyro gain
#define Gyro_Gain_Z 0.07 //Z axis Gyro gain
#define Gyro_Scaled_X(x) ((x)*ToRad(Gyro_Gain_X)) //Return the scaled ADC raw data of the gyro in radians for second
#define Gyro_Scaled_Y(x) ((x)*ToRad(Gyro_Gain_Y)) //Return the scaled ADC raw data of the gyro in radians for second
#define Gyro_Scaled_Z(x) ((x)*ToRad(Gyro_Gain_Z)) //Return the scaled ADC raw data of the gyro in radians for second
// LSM303 magnetometer calibration constants; use the Calibrate example from
// the Pololu LSM303 library to find the right values for your board
#define M_X_MIN -602
#define M_Y_MIN -668
#define M_Z_MIN -592
#define M_X_MAX 391
#define M_Y_MAX 422
#define M_Z_MAX 524
#define Kp_ROLLPITCH 0.02
#define Ki_ROLLPITCH 0.00002
#define Kp_YAW 1.2
#define Ki_YAW 0.00002
//OUTPUTMODE=1 will print the corrected data, 
//OUTPUTMODE=0 will print uncorrected data of the gyros (with drift)
#define OUTPUTMODE 1
//#define PRINT_DCM 0     //Will print the whole direction cosine matrix
#define PRINT_ANALOGS 0 //Will print the analog raw data
#define PRINT_EULER 1   //Will print the Euler angles Roll, Pitch and Yaw
#define STATUS_LED 13 
//-+-+-+>>>> END POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
//-+-+-+>>>> SRTART POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
int SENSOR_SIGN[9] = {
  1,1,1,-1,-1,-1,1,1,1}; //Correct directions x,y,z - gyro, accelerometer, magnetometer
float G_Dt=0.02;    // Integration time (DCM algorithm)  We will run the integration loop at 50Hz if possible
long timer=0;   //general purpuse timer
long timer_old;
long timer24=0; //Second timer used to print values 
int AN[6]; //array that stores the gyro and accelerometer data
int AN_OFFSET[6]={
  0,0,0,0,0,0}; //Array that stores the Offset of the sensors
int gyro_x;
int gyro_y;
int gyro_z;
int accel_x;
int accel_y;
int accel_z;
int magnetom_x;
int magnetom_y;
int magnetom_z;
float c_magnetom_x;
float c_magnetom_y;
float c_magnetom_z;
float MAG_Heading;
float Accel_Vector[3]= {
  0,0,0}; //Store the acceleration in a vector
float Gyro_Vector[3]= {
  0,0,0};//Store the gyros turn rate in a vector
float Omega_Vector[3]= {
  0,0,0}; //Corrected Gyro_Vector data
float Omega_P[3]= {
  0,0,0};//Omega Proportional correction
float Omega_I[3]= {
  0,0,0};//Omega Integrator
float Omega[3]= {
  0,0,0};
// Euler angles
float roll;
float pitch;
float yaw;
float errorRollPitch[3]= {
  0,0,0}; 
float errorYaw[3]= {
  0,0,0};
unsigned int counter=0;
byte gyro_sat=0;
float DCM_Matrix[3][3]= {
  {
    1,0,0                                  }
  ,{
    0,1,0                                  }
  ,{
    0,0,1                                  }
}; 
float Update_Matrix[3][3]={
  {
    0,1,2                                }
  ,{
    3,4,5                                }
  ,{
    6,7,8                                }
}; //Gyros here
float Temporary_Matrix[3][3]={
  {
    0,0,0                                  }
  ,{
    0,0,0                                  }
  ,{
    0,0,0                                  }
};
//-+-+-+>>>> END POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
//-+-+-+>>>> START Ultrasonic Sensor section<<<<<<-+-+-+
NewPing sonar(TRIGGER_PIN, ECHO_PIN, MAX_DISTANCE); // NewPing setup of pins and maximum distance.
const int dangerThresh = 10; //threshold for obstacles (in cm)
int leftDistance, rightDistance, centerDistance; //distances on either side
//-+-+-+>>>> END Ultrasonic Sensor section<<<<<<-+-+-+
//-+-+-+>>>> Start US PING averaging section<<<<<<-+-+-+
//------------------Avrageing-----------------------------------
const int numReadings = 5;
int readings[numReadings];      // the readings from the analog input
int index = 0;                  // the index of the current reading
int total = 0;                  // the running total
int average = 0;                // the average
//------------------Avrageing-----------------------------------
//-+-+-+>>>> END US PING averaging section<<<<<<-+-+-+
//-+-+-+>>>> START GPS INIT section<<<<<<-+-+-+
NMEA gps(ALL);    // GPS data connection to all sentence types
//-+-+-+>>>> END GPS INIT section<<<<<<-+-+-+
//-+-+-+>>>> Start VT100 INIT section<<<<<<-+-+-+
String OFF = "\033[0m";
String BOLD = "\033[1m";
String CLR = "\e[2J";  
String CLRl = "\e[2K";
String BYB = "\e[1;33;40m";
//-+-+-+>>>> END VT100 INIT section<<<<<<-+-+-+

RF24 radio(48,49);
void setup()
{
  Serial.begin(57600); 
  Serial2.begin(57600); //GPS INPUT (LocoSYS LS20031)
  //**************Start Transiever (NRF24L01) config**************
  printf_begin();
  printf("\n\rRadio Setup\n\r");
  radio.begin();
  radio.setDataRate(RF24_2MBPS);
  radio.setCRCLength(RF24_CRC_16);
  radio.setPayloadSize(12 * sizeof(byte));
  radio.setChannel(2);
  radio.setAutoAck(true);
  radio.openReadingPipe(1,0xF0F0F0F0E1LL);
  radio.openWritingPipe(0xF0F0F0F0D2LL);
  radio.startListening();
  radio.printDetails();
  //**************End Transiever (NRF24L01) config**************
  //-+-+-+>>>> Start US PING averaging section<<<<<<-+-+-+
  for (int thisReading = 0; thisReading < numReadings; thisReading++)
    readings[thisReading] = 0;        
  //-+-+-+>>>> END US PING averaging section<<<<<<-+-+-+
  //-+-+-+>>>> Start VT100 INIT section<<<<<<-+-+-+  
  // Serial.print(BYB);
  //  Serial.println(CLR);   
  //-+-+-+>>>> END VT100 INIT section<<<<<<-+-+-+
  //-+-+-+>>>> START POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+ 
  Serial.println("IMU INIT ... "); // Print some stuff to serial
  I2C_Init();
  delay(1500);
  Accel_Init();
  Compass_Init();
  Gyro_Init();
  delay(20);
  for(int i=0;i<32;i++)    // We take some readings...
  {
    Read_Gyro();
    Read_Accel();
    for(int y=0; y<6; y++)   // Cumulate values
      AN_OFFSET[y] += AN[y];
    delay(20);
  }
  for(int y=0; y<6; y++)
    AN_OFFSET[y] = AN_OFFSET[y]/32;
  AN_OFFSET[5]-=GRAVITY*SENSOR_SIGN[5];
  for(int y=0; y<6; y++)
    delay(2000);  
  timer=millis();
  delay(20);
  counter=0;
  Serial.println("IMU Stream active ... "); // Print some stuff to serial
  //-+-+-+>>>> END POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
}

struct StructBuff_t {
  char GPS[100];  
  char imuRoll[6];
  char imuPitch[6];
  char imuYaw[6];
  char AP[3];
  char SenBuffersAll[128];
}
StructBuff;
//**************************************************
//**************************************************
//************* Start Main Loop section ************
//**************************************************
//**************************************************

Part(2) of (2)

void loop()
{
  MinImu9();
  StuffStructBuff(ToDeg(roll),ToDeg(pitch),ToDeg(yaw),averagePing(),*gps.sentence());  
  BuildTransBuffer();
  //  TransSenBuffers();
}
//**************************************************
//**************************************************
//************* END Main Loop section***************
//**************************************************
//**************************************************
//-+-+-+>>>> Start Buffer Transmit section<<<<<<-+-+-+
/*
void DisplayGPSBuffer(){
 for (int i=0; i < sizeof(StructBuff.GPS);i++){
 Serial.print(StructBuff.GPS[i]);
 }  
 Serial.println("GPS buffer"); 
 }
 */
void StuffStructBuff(float inRoll, float inPitch, float inYaw, unsigned int inAP, char inGPS){//**Working**
  //////////////////////////////////////////////////////////////////////////////////////////////////
  //**Working**Collect data and fill StructBuff elements                                                     // 
  // Struct your Buffers here                                                         //+1 for \0 //
  PString(StructBuff.GPS, sizeof(StructBuff.GPS), inGPS);                 //+100 Buff //   
  //----------------------Delimitor------------------------------------------                     //
  PString(StructBuff.imuRoll, sizeof(StructBuff.imuRoll), inRoll);            //+6   Buff //
  //----------------------Seperator------------------------------------------                     //
  PString(StructBuff.imuPitch, sizeof(StructBuff.imuPitch), inPitch);
  //----------------------Seperator------------------------------------------                     //
  PString(StructBuff.imuYaw, sizeof(StructBuff.imuYaw), inYaw);               //+6   Buff //
  //----------------------Delimitor------------------------------------------                     //
  PString(StructBuff.AP, sizeof(StructBuff.AP), inAP);
  //----------------------Delimitor------------------------------------------         //+12  PrSu //
  //////////////////////////////////////////////////////////////////////////////////////Buffer = 134  
  ///Spew to local serial
  //for (int i = 0; i < sizeof(StructBuff.imuRoll); i++){
  //        Serial.print(StructBuff.imuRoll[i]);
  //      }  
  //      Serial.println();
  //////////////////////////////////////////////////////////////////////////////////////  
}
void BuildTransBuffer(){   //***NOT WORKING?***
  ////////////////////////////////////////////////////////////////////////////////////
  //***NOT WORKING?*** format the string for transmit array.
  //<<<|$GPRMC,XXXXXX.00,A,4454.1740,N,XXXXX.0143,W,000.0,128.7,300508,001.1,E,A*2E|-3.87^34.01^0.13|33|>>>  
  //Start string append
  strlcat(StructBuff.SenBuffersAll,"<<<|",sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,StructBuff.GPS,sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,"|",sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,StructBuff.imuRoll,sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,",",sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,StructBuff.imuPitch,sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,",",sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,StructBuff.imuYaw,sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,"|",sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,StructBuff.AP,sizeof(StructBuff.SenBuffersAll));
  strlcat(StructBuff.SenBuffersAll,"|>>>",sizeof(StructBuff.SenBuffersAll));
  //End string append
  //Formatting done.
  /////////////////////////////////////////////////////////////////////////////////////////////////////////
  ///Spew StructBuff.SenBuffersAll to local serial
  for (int i = 0; i < sizeof(StructBuff.SenBuffersAll); i++){
    Serial.print(StructBuff.SenBuffersAll[i]);
  }  
  Serial.println();
  ///////////////////////////////////
}
void TransSenBuffers(){
  radio.stopListening();
  bool ok = radio.write(StructBuff.SenBuffersAll,sizeof(StructBuff.SenBuffersAll));
  if (ok) 
    printf("ok...Tflow2byte12\n\r"); 
  else  
    printf("failed.Tflow2byte12\n\r");
  delay(10);
}
//-+-+-+>>>> END Buffer Transmit section<<<<<<-+-+-+


//-+-+-+>>>> Start Type conversion section<<<<<<-+-+-+
void Tflo2byteIMU(float inRoll, float inPitch, float inYaw){

  union inRoll2byte_t {
    byte  inRollout[4];
    float inRollin;
  }
  inRoll2byte;
  inRoll2byte.inRollin = inRoll;

  union inPitch2byte_t {
    byte  inPitchout[4];
    float inPitchin;
  }
  inPitch2byte;
  inPitch2byte.inPitchin = inPitch;

  union inYaw2byte_t {
    byte  inYawout[4];
    float inYawin;
  }
  inYaw2byte;
  inYaw2byte.inYawin = inYaw;

  byte output[12];
  output[0] = inRoll2byte.inRollout[0];
  output[1] = inRoll2byte.inRollout[1];  
  output[2] = inRoll2byte.inRollout[2];
  output[3] = inRoll2byte.inRollout[3]; 

  output[4] = inPitch2byte.inPitchout[0];
  output[5] = inPitch2byte.inPitchout[1];  
  output[6] = inPitch2byte.inPitchout[2];
  output[7] = inPitch2byte.inPitchout[3]; 

  output[8] = inYaw2byte.inYawout[0];
  output[9] = inYaw2byte.inYawout[1];  
  output[10] = inYaw2byte.inYawout[2];
  output[11] = inYaw2byte.inYawout[3]; 
  radio.stopListening();
  bool ok = radio.write(output,sizeof(output));
  if (ok) 
    printf("ok...Tflow2byteIMU\n\r"); 
  else  
    printf("failed.Tflow2byteIMU\n\r");
  delay(10);
}
//-+-+-+>>>> End Type conversion section<<<<<<-+-+-+
//-+-+-+>>>> START Sensor readings section<<<<<<-+-+-+
void PrnGpsNmea() {
  if (Serial2.available() > 0 ) {
    // read incoming character from GPS and feed it to NMEA type object
    if (gps.decode(Serial2.read())) {
      Serial.println (gps.sentence());
    }
  }
}
unsigned int  ping(){
  delay(50);                      // Wait 50ms between pings (about 20 pings/sec). 29ms should be the shortest delay between pings.
  unsigned int uS = sonar.ping(); // Send ping, get ping time in microseconds (uS).
  return uS / US_ROUNDTRIP_CM;
}
unsigned int averagePing(){
  total= total - readings[index]; // subtract the last reading:
  readings[index] = ping();   // read from the sensor:  
  total= total + readings[index];   // add the reading to the total:
  index = index + 1;  // advance to the next position in the array:  
  if (index >= numReadings)  // if we're at the end of the array...
    index = 0;   // ...wrap around to the beginning:                           
  average = total / numReadings;   // calculate the average:
  delay(1);        // delay in between reads for stability            
  return average;   // send it as ASCII digits
}
unsigned int PingScan(unsigned int Fwddist){
}  
//-+-+-+>>>>START POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
void MinImu9() //PoloLU MINIMU -9DOF
{
  if((millis()-timer)>=20)  // Main loop runs at 50Hz
  {
    counter++;
    timer_old = timer;
    timer=millis();
    if (timer>timer_old)
      G_Dt = (timer-timer_old)/1000.0;    // Real time of loop run. We use this on the DCM algorithm (gyro integration time)
    else
      G_Dt = 0;
    // *** DCM algorithm
    // Data adquisition
    Read_Gyro();   // This read gyro data
    Read_Accel();     // Read I2C accelerometer
    if (counter > 5)  // Read compass data at 10Hz... (5 loop runs)
    {
      counter=0;
      Read_Compass();    // Read I2C magnetometer
      Compass_Heading(); // Calculate magnetic heading  
    }
    // Calculations...
    Matrix_update(); 
    Normalize();
    Drift_correction();
    Euler_angles();
    // ***
    //   VTprintdata();
    // printdata();
  }
}
//-+-+-+>>>> END POLOLU MINIMU - 9DOF Sensor section<<<<<<-+-+-+
//-+-+-+>>>> END Sensor readings section<<<<<<-+-+-+
struct StructBuff_t {
  char GPS[100];  
  char imuRoll[6];
  char imuPitch[6];
  char imuYaw[6];
  char AP[3];
  char SenBuffersAll[128];
}
StructBuff;

This is STILL wrong. Until you fix it, I can't help you.

You either store the GPS data as character data and the other stuff as floats (or strings) in the struct, OR you store all the data in and array.

What you have now is a box of stuff to send. Then, you make a copy of the stuff to send, and put the copy in an envelope. Then, you throw the envelope in the box, and send the box. That hardly makes sense.

PaulS:

struct StructBuff_t {

char GPS[100]; 
  char imuRoll[6];
  char imuPitch[6];
  char imuYaw[6];
  char AP[3];
  char SenBuffersAll[128];
}
StructBuff;



This is STILL wrong. Until you fix it, I can't help you.

You either store the GPS data as character data and the other stuff as floats (or strings) in the struct, OR you store all the data in and array. 

What you have now is a box of stuff to send. Then, you make a copy of the stuff to send, and put the copy in an envelope. Then, you throw the envelope in the box, and send the box. That hardly makes sense.

Ok my understanding was collect all the data in each of there native types chars/floats use PStrings to convert and stuff them into there char type arrays so they can now be use and referenced as char strings collect the char strings up into one and offload it. your saying i have extra steps in there ?

struct StructBuff_t { // Global struct
  char GPS[100];   // being filled with PString(StructBuff.GPS, sizeof(StructBuff.GPS), inGPS);
  char imuRoll[6];  // being filled with PString(StructBuff.imuRoll, sizeof(StructBuff.imuRoll), inRoll); // Was a float now a char stings in a char array yes no? 
  char imuPitch[6]; // being filled with PString(StructBuff.imuPitch, sizeof(StructBuff.imuPitch), inPitch); "                                                                              "
  char imuYaw[6];  // being filled with   PString(StructBuff.imuYaw, sizeof(StructBuff.imuYaw), inYaw); "                                                                                    "
  char AP[3];  // being filled with   PString(StructBuff.AP, sizeof(StructBuff.AP), inAP);  was an int now a char yes no?     
  char SenBuffersAll[128]; // being filled with strlcat after pulling the newly filled char arrays with sensor data in .GPS .imuRoll etc?
}
StructBuff;

use radio.write StructBuff.SenBuffersAll with completed formatted string?
if not show me where i am going wrong. because that looks like 1234 rinse and repeat to me. (1).get data bits (2).store data bits (3).combine each data bit into data string (4).send datastring

Ok my understanding was collect all the data in each of there native types chars/floats

Correct.

use PStrings to convert and stuff them into there char type arrays so they can now be use

Not necessary, but, if you have the resources, it's not the end of the world.

and referenced as char strings collect the char strings up into one and offload it. your saying i have extra steps in there ?

You are copying data from each of the small(er) arrays into one larger array, and storing the larger array in the same box with the smaller arrays.

If you are then going to send only what is in the envelope (the larger array), rather than what is in the box (the struct), there is no reason to have a box or to store the envelope in the box.

A more straight-forward setup would have the box (the struct) containing the floats and char array (the GPS data), and send the box, with no PString or String manipulation (copy into envelope) required.

ok i see what your sing about the struct and the box bit but why is it even odd much less apparently not correct to store the large array with the smaller arrays?
on the send the box note with out converting them im assuming something along the following?

struct StructBuff_t {
  char GPS[100];  
  float imuRoll[4];
  float imuPitch[4];
  float imuYaw[4];
  unsigned int AP[?];
}
StructBuff;

and then by some programing voodoo send that across radio.write and receive it and know what it is? ( what stumps me is how you send that stuct in one shot) and what baffels me is after it is crammed into radio.write how do i even know what it is or what var goes in what slot.. ( another assumption, another struct made the same on the other side to store them in i get that or i think i do) but radio.read is gunna spew out some stuff ( another assumption, in the order it was received in the "type" it was sent).
so something like..

radio.write( voodooS) ---------->{some packet that has like char gps float imuRoll etc.}-------> radio read(voodooR) ----->(then what radio.read is starting to spew into voodooR i some how parse voodooR and just take like say the first 100 chars (put GPS) next float (put imuRoll) and next float (put etc.). because they come out the same order they were received?.
if above is correct then how do you send the box i through you accessed each element through the stuct not the stuct it self.
now that i have swapped out to RF24 i can send raw data and not in bytes so i get why i do not need to convert them.
so to wrap out i love the make box collect data in native form in box send box idea a lot seems the most efficient way to me. so maby a link to a resorce that shows how to use structs or some other "box" your thinking of that can alow me to radio.write it across and an idea how to "parse" it back into the box there ( or did i just stick a box in a box?)

BTW THANK YOU PaulS. for "dealing with me" through this. i am enjoying learning programing from you. 3 weeks ago i could not even get a for loop going right lol. so thank you seriously.

You don't have an array of roll, pitch, and yaw values, do you? I thought you had one of each. Yes, they are 4 bytes, but that is the size of the float, not the number of floats.

radio.write( voodooS)

That "voodoo" is the address of the struct and the size of the struct.

radio.write((byte *)&StructBuff, sizeof(StructBuff);

Both ends need to know how that struct is defined, so the sender packs the data in it correctly, and the receiver gets the data out correctly.

Like the box and envelope analogy, the post office doesn't need to know what is in the box to deliver it. The recipient needs to, though

OHHH so accessing StructBuff with no .*** will access the full stuct? and therefore transmit it? did not realize you can just call the structure it self like that. so somthing like this.
TX

#include <SPI.h>
#include "nRF24L01.h"
#include "RF24.h"
#include "printf.h"
#include <PString.h>
RF24 radio(48,49);
void setup(){
  Serial.begin(57600); 
  //**************Start Transiever (NRF24L01) config**************
  printf_begin();
  printf("\n\rRadio Setup\n\r");
  radio.begin();
  radio.setDataRate(RF24_2MBPS);
  radio.setCRCLength(RF24_CRC_16);
  radio.setPayloadSize(12 * sizeof(byte));
  radio.setChannel(2);
  radio.setAutoAck(true);
  radio.openReadingPipe(1,0xF0F0F0F0E1LL);
  radio.openWritingPipe(0xF0F0F0F0D2LL);
  radio.startListening();
  radio.printDetails();
  //**************End Transiever (NRF24L01) config**************
}  
struct StructBuff_t {
  char GPS[10];  
  float imuRoll;
  float imuPitch;
  float imuYaw;
  unsigned int AP;
}
StructBuff;

//**************************************************
//************* Start Main Loop section ************
//**************************************************
void loop()
{
  /////////////////////////////////////////////////////////  
  char myChar = 'A';                                     //
  PString(StructBuff.GPS, sizeof(StructBuff.GPS),myChar);//
  StructBuff.imuRoll  = -13.42;                          //
  StructBuff.imuPitch =   6.98;                          //Temp Values
  StructBuff.imuYaw   =   0.42;                          //
  StructBuff.AP       =  55;                             //
  /////////////////////////////////////////////////////////

   TransStruct();
}
//**************************************************
//************* END Main Loop section***************
//**************************************************
//-+-+-+>>>> Start Struct Transmit section<<<<<<-+-+-+
void TransStruct(){

  radio.stopListening();
  bool ok = radio.write((byte *)&StructBuff, sizeof(StructBuff));
  if (ok) 
    printf("ok...\n\r"); 
  else  
    printf("failed.\n\r");
  delay(10);

}
//-+-+-+>>>> END Struct Transmit section<<<<<<-+-+-+

RX

#include <SPI.h>
#include "nRF24L01.h"
#include "RF24.h"
#include "printf.h"
#include <PString.h>
RF24 radio(8,9);
void setup(){
  Serial.begin(57600); 
  //**************Start Transiever (NRF24L01) config**************
  printf_begin();
  printf("\n\rRadio Setup\n\r");
  radio.begin();
  radio.setDataRate(RF24_2MBPS);
  radio.setCRCLength(RF24_CRC_16);
  radio.setPayloadSize(12 * sizeof(byte));
  radio.setChannel(2);
  radio.setAutoAck(true);
  radio.openReadingPipe(1,0xF0F0F0F0D2LL);
  radio.openWritingPipe(0xF0F0F0F0E1LL);
  radio.startListening();
  radio.printDetails();
  //**************End Transiever (NRF24L01) config**************
}  
struct StructBuff_t {
  char GPS[10];  
  float imuRoll;
  float imuPitch;
  float imuYaw;
  unsigned int AP;
}
StructBuff;

//**************************************************
//************* Start Main Loop section ************
//**************************************************
void loop()
{
 
   RecStruct();
  Serial.println(StructBuff.GPS);
  Serial.println(StructBuff.imuRoll);
  Serial.println(StructBuff.imuPitch);
  Serial.println(StructBuff.imuYaw);
  Serial.println(StructBuff.AP);
}
//**************************************************
//************* END Main Loop section***************
//**************************************************
//-+-+-+>>>> Start Struct Transmit section<<<<<<-+-+-+
void RecStruct(){

  radio.startListening();
  bool ok = radio.read((byte *)&StructBuff, sizeof(StructBuff));
  if (ok) 
    printf("ok...\n\r"); 
  else  
    printf("failed.\n\r");
  delay(10);

}
//-+-+-+>>>> END Struct Transmit section<<<<<<-+-+-+

TX = b,-13.42,6.98,0.42,55
RX = bbbbbbbbbbbb,0.00,0.00,0.00,0
rx char buffer is 10 so just getting stuffed with b's but why no floats or ints get through?

Cyric:
TX = b,-13.42,6.98,0.42,55
RX = bbbbbbbbbbbb,0.00,0.00,0.00,0
rx char buffer is 10 so just getting stuffed with b's but why no floats or ints get through?

TX= f,-13.42,6.98,0.42,55
RX =f,0.00,0.00,0.00,0
had to change them to 1* sizeof(byte) in Payload(); dont know why realy. but the floats and ints still are not coming throuhg?
and what exactly does the (byte *) part do. i know the &StructBuff is & refrence to the pointer for the struct yes?

struct StructBuff_t {
  char GPS[10];  
  float imuRoll;
  float imuPitch;
  float imuYaw;
  unsigned int AP;
}
...
radio.setPayloadSize(12 * sizeof(byte));
...
radio.write((byte *)&StructBuff, sizeof(StructBuff));

I think you'll find that sizeof(StructBuff) is a lot bigger than 12 * sizeof(byte). Your payload size needs to be at least as big as your actual message size. If I were you I'd leave it at the default, which is the maximum supported size (32).

Also suggest you zero out the receive buffer before the receive, so you know that what you're looking at came over the radio link and you aren't being misled by uninitialised or historical data.

am i not pointing to StructBuff correctly from radio.read?

#include <SPI.h>
#include "nRF24L01.h"
#include "RF24.h"
#include "printf.h"
RF24 radio(8,9);
//---------------------

struct StructBuff_t {
  char GPS[100];  
  float imuRoll;
  float imuPitch;
  float imuYaw;
  unsigned int AP;
  //  char SenBuffersAll[28];
}
StructBuff;
//---------------------
void setup(void){
  Serial.begin(57600);
  printf_begin();
  printf("\n\rRadio Setup\n\r");
  radio.begin();
  radio.setDataRate(RF24_2MBPS);
  radio.setCRCLength(RF24_CRC_16);
  radio.setPayloadSize(32);
  radio.setChannel(2);
  radio.setAutoAck(true);
  radio.openReadingPipe(1,0xF0F0F0F0D2LL);
  radio.openWritingPipe(0xF0F0F0F0E1LL);
  radio.startListening();
  radio.printDetails();
}
void loop(void){
  if ( radio.available() )
  {
    radio.startListening();
    bool ok = radio.read(&StructBuff,sizeof(StructBuff));
    if (ok) 
      displayStructBuff();  
    else  
      printf("failed.\n\r");
    delay(10);
  }
}



void displayStructBuff(){
  //  Serial.print("!");  
  //  Serial.print("ANG:");  
  Serial.print(StructBuff.imuRoll);
  Serial.print(",");
  Serial.print(StructBuff.imuPitch);
  Serial.print(",");
  Serial.print(StructBuff.imuYaw);
  Serial.print(",");
  Serial.print(StructBuff.AP);
  Serial.println();
  Serial.println(StructBuff.GPS);
}

output is

0.00,0.00,0.00,0

I removed the GPS and AP out and just tied to trans a smaller struct. befor it was all 0.00 stuff but now i have some stuff coming across. it's it a packet size issue?
i stopped pre defining a packet size and do it with sizeof in the write/read call

 printf_begin();
  printf("\n\rRadio Setup\n\r");
  radio.begin();
  radio.setDataRate(RF24_2MBPS);
  radio.setCRCLength(RF24_CRC_16);
 // radio.setPayloadSize(32);
  radio.setChannel(2);
  radio.setAutoAck(true);
  radio.openReadingPipe(1,0xF0F0F0F0E1LL);
  radio.openWritingPipe(0xF0F0F0F0D2LL);
  radio.startListening();
  radio.printDetails();
radio.write((byte *)&StructBuff, sizeof(StructBuff)); TX side
radio.read((byte *)&StructBuff, sizeof(StructBuff)); RX side
typedef struct {
  float imuRoll;
  float imuPitch;
  float imuYaw;
}strbuff_t;
strbuff_t StructBuff;

now my output is like this
TX

Ok..
-0.00,-0.00,0.01,
Ok..
-0.25,-0.00,0.00,
Ok..
-0.10,-0.03,0.00,
Ok..
-0.24,0.13,0.00,
Ok..
-0.18,0.18,-0.00,
Ok..
-0.17,0.30,-0.00,
Ok..
-0.14,0.33,-1.96,
Ok..
-0.06,0.23,-3.70,
Ok..
-0.11,0.23,-5.43,

RX Side

0.00,0.00,0.00,
0.00,0.00,0.00,
0.00,0.00,0.00,
-1.50,-1.50,-1.50,
0.00,0.00,0.00,
0.19,0.19,0.19,
0.00,0.00,0.00,
0.00,0.00,0.00,
-0.00,-0.00,-0.00,

this is prob a silly question but what is (byte *) doing for the function readio.----?

it's it a packet size issue?

Quite likely.

this is prob a silly question but what is (byte *) doing for the function readio.----?

The radio.write() and radio.read() methods expect the first argument to be of type byte array. You struct instance is a collection of bytes, but it is not an array of bytes. So, you need to lie to the function, and tell it that what you have is an array of bytes. That is done with a cast - the (byte *) part.

Of course, a cast only works when it is reasonable to interpret data of one type (struct) as though it was another type (array of bytes).

that makes sense thanks.
i also made a new thread because i sense this RF part of my project is going take a few more posts and felt the struct/transmit part should be a separate issue.
still do not know why it does not want to work for me sending a struct i even eliminated all but the floats to send just to keep it simple

hey PaulS how can i (if at all) clean up the code some. As in say cut everything from below #include ( keep those in) and above void Setup and put them in an external file? this code is getting so long 504 line 16k ino file lol and i just gutted any extra code out of it.

Have you confirmed that you receive one message for each message sent, and that the number of bytes sent and received is the same? What is your actual payload size now?