Presentation is loading. Please wait.

Presentation is loading. Please wait.

Yevgeny Petrilin Shay Dan Shadi Ibrahim. GUI : Graphical User Interface DAQ :Data Acquisition Data Acquisition device  a self-powered system that communicated.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Yevgeny Petrilin Shay Dan Shadi Ibrahim. GUI : Graphical User Interface DAQ :Data Acquisition Data Acquisition device  a self-powered system that communicated."— Presentation transcript:

1 Yevgeny Petrilin Shay Dan Shadi Ibrahim

2 GUI : Graphical User Interface DAQ :Data Acquisition Data Acquisition device  a self-powered system that communicated with a computer through a standard or proprietary interface GPIB  General Purpose Interface Bus. Sweep  A continuous change of a parameter in an electronic system. Most often it refers to a frequency sweep or the sweep of a voltage. Difference measurements

3  The main goal was to write a program that can performs Mega sweep using limited types of devices  DAQ is the Main device and it is also able to read other devices input  It can generate voltage in a limited range  Devices can be configured either manually or via measurement tool  Devices can be connected to each other in a single experiment.  The program should enable :  Configuring each device output in the range of [-10:10][V]  Controlling the devices while doing the experiment, hence changing output values.  Saving the experiment data into database in a convent format

4  Programming language: C.  OOP principals (ADT).  Device Array – pointers to functions.  Read/Write settings.  Synchronization.

5 Project Requirements And results

6 The user should be able to set sweep details: source device, limits, rate (up/down), increment, number of sweeps, details of the participating devices, and units for viewing results. The user should be able to store/load sweep configuration for anytime reuse. The user should be able to change the manner of the data graphical presentation at sweep run time. The user should be able to change sweep rate or direction at run time. The user should be able to pause/ resume sweep. The user should be able to stop and reset the sweep.

7 The application should be able to read input from the DAQ buffer. The application should support any size of sweep. The application should synchronize both reading and writing tasks in order to associate data accordingly. The application can read up to 16 channel's input in regular mode and up to 8 channels in DIFF mode at the same time. All the experiment ’ s data should be gathered without any lost, regardless of the size. Data gathered from the DAQ buffer should be stored in a file using parallel thread.

8 The application should identify all the connected devices to the pc at run time. The application should enable to choose the devices participating in the experiment and configure their values. The application should be able to communicate with the devices listed below; the application should be able to forward write-tasks to these devices. Application should be able to pause/resume/stop or change the devices state while doing the experiment.

9 Device Array DAQ Dev1...... write read close pause goto ___________ Read state Write state write read close pause goto ___________ Read state Write state Device Interface Device Interface Create Destroy Set read state Set write state Create Destroy Set read state Set write state ADT Interface Device specific Methods: write read close Device specific Methods: write read close Device Specific Interface Device Specific Interface The process of adding a device

10 The Interface for developer usage Device Array DAQ Dev1...... write read close pause goto ___________ Read state Write state write read close pause goto ___________ Read state Write state Device Interface Device Interface Device specific Methods: write read close Device specific Methods: write read close Device 1 Specific Interface Device 1 Specific Interface Device specific Methods: write read close Device specific Methods: write read close Device 2 Specific Interface Device 2 Specific Interface

11  DAQ as sweep Source device  Source write function instructs main device to write an array of sequential values in an appropriate range at a given rate  Asynchronous call  Runs in main thread  Calls a DONE interrupt when the device when DAQ finishes given write task  Done interrupt calls a method that waits until operation of read and handling its results is done (Plot mainly)  Sets the flags for the next iteration in sweep  Sets the parameter for read/write in the next iteration  Executes the next iteration/ ends sweep

12  Yokogawa as sweep Source device  Source write function instructs main device to write an array of sequential values in an appropriate range in a given time  Asynchronous call  Runs in main thread  DONE interrupt is implemented via thread which waits during given execution time  Done interrupt calls a method that waits until operation of read and handling its results is done (Plot mainly)  Sets the flags for the next iteration in sweep  Sets the parameter for read/write in the next iteration  Executes the next iteration/ ends sweep

13 DAQ as sweep Source device  Read function initiates DAQ with the parameters pulled from GUI  Read operation is triggered by DAQ write function  Read clock is synchronized with output clock  It executes an interrupt function after every N samples it read from input, each interrupt performs  Plotting results into GUI  Calling a thread which writes results into a specified file READ IS ALWAYS CALLED BEFORE WRITE

14 DAQ is Not the sweep Source device  Read function initiates DAQ with the parameters pulled from GUI  Read operation is not triggered, it starts when it is called  Read clock is synchronized with DAQ onboard clock  It executes an interrupt function after every N samples it read from input, each interrupt performs  Plotting results into GUI  Calling a thread which writes results into a specified file READ IS ALWAYS CALLED BEFORE WRITE

15 Main interfaceDAQ interface Read() Write() Main Thread Thread Pool Database Read Interrupt Done Interrupt Register Done Worker Thread Every N samples Plot graph/save results Write next iter. Write Write is Done, Wait until read + plot is done 1 2 *

16 Yokogawa interface Write () Main interfaceDAQ interface Read() Main Thread Thread Pool Database Read Interrupt Register EveryN Worker Thread Every N samples Plot graph/save results Write next iter. Write Write is Done, Wait until read + plot is done 1 2 * Worker Thread Sleep duration

17  Data structure  Devices array  Additional outputs array (subset of device array)  Sweep configuration Values taken from GUI Values set by device interface Runtime configuration  In order to perform operations during a sweep, participating devices data will be pulled from settings database  Runtime flags Sweep direction Display mode …

18  Initiating measurement tool Main Physical Device* Collect info Identity info Device Create device[info] Specific Device Retrieve pointers

19  Running a sweep with DAQ as source Main Device write ok DeviceDAQ DAQ write DAQ readDevice read DAQ done write Settings Retrieve Next configurations Retrieve Sweep configurations

20  DAQ  Handling device as source  Retrieving read results from channels  Yokogawa  Device as main source  Device as additional output  HP Agilent 363xx  Device as additional output

21

22 Configuring the main sweep source. Here we set the limits, the rate and the number of iterations Configuring the main sweep source. Here we set the limits, the rate and the number of iterations Adding Additional output. Here we define the other devices that participates the experiment. The devices are selected from the GPIB device list. Adding Additional output. Here we define the other devices that participates the experiment. The devices are selected from the GPIB device list. Setting the DAQ inputs. We need to Add the data manually according to the channels we connected. Setting the DAQ inputs. We need to Add the data manually according to the channels we connected. Load / save configurations. Apply settings will send the configurations instructions to the devices through the GPIB Load / save configurations. Apply settings will send the configurations instructions to the devices through the GPIB

23

24 Sweep controls. Start/stop/pause/resume. Enables changing the rate or the output value of the main device. Sweep controls. Start/stop/pause/resume. Enables changing the rate or the output value of the main device. Examining sweep online results: 1.Viewing results 2.Manipulating graph Examining sweep online results: 1.Viewing results 2.Manipulating graph

25

26  Physical devices  Throughput (Device capabilities VS. PC)  Output range (Yoko VS. DAQ)  Software related  Programming language restrictions  Synchronization overhead  Workspace related  Various kinds of platforms : uniform interface?

Download ppt "Yevgeny Petrilin Shay Dan Shadi Ibrahim. GUI : Graphical User Interface DAQ :Data Acquisition Data Acquisition device  a self-powered system that communicated."

Similar presentations

Network II.5 simulator ..

Network II.5 simulator ..
CSC 360- Instructor: K. Wu Overview of Operating Systems.

CSC 360- Instructor: K. Wu Overview of Operating Systems.
Operating System.

Operating System.
Fetch Execute Cycle – In Detail -

Fetch Execute Cycle – In Detail -
Dr. Rabie A. Ramadan Al-Azhar University Lecture 3

Dr. Rabie A. Ramadan Al-Azhar University Lecture 3
1 (Review of Prerequisite Material). Processes are an abstraction of the operation of computers. So, to understand operating systems, one must have a.

1 (Review of Prerequisite Material). Processes are an abstraction of the operation of computers. So, to understand operating systems, one must have a.
Yaron Doweck Yael Einziger Supervisor: Mike Sumszyk Spring 2011 Semester Project.

Yaron Doweck Yael Einziger Supervisor: Mike Sumszyk Spring 2011 Semester Project.
Input and Output CS 215 Lecture #20.

Input and Output CS 215 Lecture #20.
Microprocessor and Microcontroller

Microprocessor and Microcontroller
Processor System Architecture

Processor System Architecture
Using an FPGA to Control the Protection of National Security and Sailor Lives at Sea Brenda G. Martinez, Undergraduate Student K.L. Butler-Purry, Ph.D.,

Using an FPGA to Control the Protection of National Security and Sailor Lives at Sea Brenda G. Martinez, Undergraduate Student K.L. Butler-Purry, Ph.D.,
Silberschatz, Galvin and Gagne  2002 2.1 Operating System Concepts Chapter 2: Computer-System Structures Computer System Operation I/O Structure Storage.

Silberschatz, Galvin and Gagne  Operating System Concepts Chapter 2: Computer-System Structures Computer System Operation I/O Structure Storage.
Architectural Support for Operating Systems. Announcements Most office hours are finalized Assignments up every Wednesday, due next week CS 415 section.

Architectural Support for Operating Systems. Announcements Most office hours are finalized Assignments up every Wednesday, due next week CS 415 section.
A Brief Overview of LabVIEW Data Acquisition (DAQ)

A Brief Overview of LabVIEW Data Acquisition (DAQ)
Midterm Tuesday October 23 Covers Chapters 3 through 6 - Buses, Clocks, Timing, Edge Triggering, Level Triggering - Cache Memory Systems - Internal Memory.

Midterm Tuesday October 23 Covers Chapters 3 through 6 - Buses, Clocks, Timing, Edge Triggering, Level Triggering - Cache Memory Systems - Internal Memory.
Operating Systems CS208. What is Operating System? It is a program. It is the first piece of software to run after the system boots. It coordinates the.

Operating Systems CS208. What is Operating System? It is a program. It is the first piece of software to run after the system boots. It coordinates the.
1 Operating Systems Ch. 14 - An Overview. Architecture of Computer Hardware and Systems Software Irv Englander, John Wiley, 2000 2 Bare Bones Computer.

1 Operating Systems Ch An Overview. Architecture of Computer Hardware and Systems Software Irv Englander, John Wiley, Bare Bones Computer.
Pipelining By Toan Nguyen.

Pipelining By Toan Nguyen.
Monitoring systems COMET types MS55 & MS6 MS55/MS6 Configuration.

Monitoring systems COMET types MS55 & MS6 MS55/MS6 Configuration.
ISO Task Controller Lecture 9 Task Controller – Part I

ISO Task Controller Lecture 9 Task Controller – Part I

Similar presentations

Ads by Google