Multi-experiment Single Board Telecoms Trainer for the popular NI ELVIS™ platform
Designed specifically for 1st & 2nd Year University and Community College courses
- Emona Telecoms-Trainer 202, known as DATEx, plugs into the NI ELVIS™ platform, operating in local mode and under LabVIEW™
- An excellent “hands-on” experiment system, implementing the well established “block diagram approach” to building
- Supported by a comprehensive Lab Manual written for younger students in introductory classes
- Unrivalled with a wide range of modern communications topics in one compact trainer
- Local control and also remote control via the ETT-202 SFP virtual instrument on LabVIEW™
In order to help students use the ETT-101, so they spend their time learning about the experiment rather than learning how to use the lab equipment, the front panel of the ETT-101 has been laid out following a series of front panel conventions. All ETT-101 modules conform to the following mechanical and electrical conventions. Emona 101 Lab Manual Experiment 8 - s2.kora.com Laboratory Manuals Emona 101 Ilbu The ETT-101 Lab Manual The ETT-101 Lab Manual Volume One, is written specifically for students enrolled in a first course in telecommunications at unviersity or a specilaist course at a vocational.
ETT-202 SFP virtual instrument on LabVIEW
DESIGNED FOR NI ELVIS™ The Emona Telecoms-Trainer 202 extends the functionality of your NI ELVIS™ platform and LabVIEW™ software with a plug and play telecommunications board to teach the fundamentals of modern communications theory.
Waveform displays and measurements are on-screen using LabVIEW™. Control is either via the front panel knobs and switches, or through the PC via the ETT-202 Soft Front Panel (SFP) instrument.
BLOCK DIAGRAM APPROACH
Using the ETT-202, students learn fundamental concepts by actually building telecommunications experiments at the block diagram level. Theory comes to life as they build the modulation and coding schemes in carefully guided steps.
Students are free to learn by trying “what-if” scenarios to investigate the telecommunications theory they learn in class. With the ETT-202, your students will learn more, and remember more.
COMPACT and EASY FOR TEACHERS
The system is completely self-contained: all that is required is the ETT-202, NI ELVIS™ and LabVIEW™ running on a PC.
The ETT-202 accessories kit includes:
20 x stackable patch cords, User Manual, Digital and Analog Basic Telecommunications Experiments Manual Volume-1 and the ETT-202 SFP CD-ROM.
ADDITIONAL EXPERIMENT CAPABILITIES
Given that the ETT-202 provides a wide array of fundamental electronic building blocks, controllable using LabVIEW™ , the ETT-202 can also be used as a general purpose applications board to investigate topics such as systems control and integration of LabVIEW applications with electronic hardware.
TELECOMMUNICATIONS TOPICS
- Basic Analog Communications AM, FM, DSB, SSB, PM, PAM, TDM, PWM, Superheterodyne, Speech in Comms, PLL, QAM, SNR Concepts and more
- Digital Communications PCM, PCM-TDM, ASK, BPSK, FSK, GFSK, Eye Patterns, DPSK, QPSK, Spread Spectrum, Line Coding, Noise Generation, SNR Concepts and more
- LabVIEW™ APPLICATIONS
- Familiarity with LabVIEW™ VI’s; Controlling real telecommunications signals and experiment set-ups via the DATEx Soft Front Panel; Utilising a suite of LabVIEW™ VI’s to generate, view and record real signals;
- System Control & Design Skills; Integrate hardware and software signal processing; Create ‘hardware in the loop’ systems; Data acquisition of real electrical signals; Writing new LabVIEW™ applications using DATEx function block VI’s
TELECOMMUNICATIONS TOPICS
- Basic Analog Communications AM, FM, DSB, SSB, PM, PAM, TDM, PWM, Superheterodyne, Speech in Comms, PLL, QAM, SNR Concepts and more
- Digital Communications PCM, PCM-TDM, ASK, BPSK, FSK, GFSK, Eye Patterns, DPSK, QPSK, Spread Spectrum, Line Coding, Noise Generation, SNR Concepts and more
- LabVIEW™ APPLICATIONS
- Familiarity with LabVIEW™ VI’s; Controlling real telecommunications signals and experiment set-ups via the DATEx Soft Front Panel; Utilising a suite of LabVIEW™ VI’s to generate, view and record real signals;
- System Control & Design Skills; Integrate hardware and software signal processing; Create ‘hardware in the loop’ systems; Data acquisition of real electrical signals; Writing new LabVIEW™ applications using DATEx function block VI’s
View a brief
7 minutes video presentation
ABOUT Datex
.
LABORATORY MANUAL
The ETT-202 Laboratory Manual set (Vol.1, 2 & 3) provides a turn-key solution for the teacher and student alike.
ETT-202 Laboratory Manual
Huniepop free download pc. It is specially written to guide students through hands-on experiments and help them grasp the fundamental concepts of telecommunications.
Each chapter includes background information which relates the experiment content to real-world applications. Since telecommunications text books represent the math and concepts of telecommunications theory as “block diagrams” this Lab Manual makes extensive use of block diagrams throughout.
Associated with each block diagram are detailed, step-by-step patching diagrams. Each chapter is carefully paced and constant use is made of questions to verify the student’s understanding and provide feedback to the teacher.
LAB MANUAL TOPICS – VOLUME 1 (300 pages) ETT-202 Experiment Phase
- Setting-up an Oscilloscope display
- An Introduction to the ETT-202
- Modelling Equations
- Amplitude Modulation AM
- Double Sideband DSB Mod
- AM Demodulation
- DSB Demodulation
- SSB Modulation & Demod
- FM Modulation
- FM Demodulation
- Sampling & Reconstruction
- PCM Encoding
- PCM Decoding
- BW Limiting & Restoring Digital Signals
- ASK Mod & Demodulation
- FSK Mod & Demodulation
- BPSK Mod & Demodulation
- QPSK Mod & Demodulation
- Introduction to Spread Spectrum – CDMA modulation
- Introduction to Undersampling in Software Defined Radio
LAB MANUAL TOPICS – VOLUME 2
- AM (method 2) and product detection of AM signals
- Noise in AM communications
- PCM and time division multiplexing (TDM)
- An introduction to Armstrong’s modulator
- Phase division modulation and demodulation
- Pulse width modulation and demodulation (PWM)
- Message translation and inversion
- Carrier acquisition using the phase locked loop (PLL)
- Signal to noise ratio and eye diagrams
- Pulse code modulation and signal to noise distortion ratio (SNDR)
- ASK demodulation using product detection
- FSK generation (switching method) and demodulation
- Principles of Gaussian FSK (GFSK)
- PN sequence spectra and noise generation
- Line coding and bit clock regeneration
LAB MANUALS TOPICS-VOLUME 3
- LabVIEW Control of DATEx Hardware Overview
- Using Prewired Backgrounds on the DATEx MAIN SFP
- Saving Screen Space with the DATEx ‘Toolbar’ SFP
- Low Level DATEx VIs
- Programming Amplitude Control Blocks
- Programming Frequency Control Blocks
- Programming Phase Control Blocks
- Programming Timing Control Blocks
- Programming Mode Control Blocks
- Sequencing and Combining the DATEx Blocks
- Using NI ELVIS Instruments on the DATEx
- Building LabVIEW Controlled DATEx Experiments
- Viewing filter responses using FFTs
- Introducing complex I/Q modulation using LV Modulation Toolkit
- Armstrong’s phase modulator using the LV Modulation Toolkit
- MSK modulation using the LV Modulation Toolkit
- FM generation using the LV Modulation Toolkit
- Further LabVIEW Programming Tasks
- Controlling DATEx remotely across the Internet
ANALOG BASICS
1. Amplitude Modulation (AM)
- modulation: 2 methods
- envelope detection
- product detection (coherent)
- AM in a noisy channel
2. Double Side Band (DSB)
- suppressed carrier
- product detection (coherent)
- DSB in a noisy channel
3. Single Sideband (SSB)
- generation only (upper & lower)
4. Phase Modulation (PM)
- Armstrong’s Phase modulator
5. Phase Division Modulation (PDM)
- Phase division demodulation
6. Frequency Modulation (FM)
- Generation by VCO (wideband)
- demodulation by PLL
- demodulation by zero crossing method
7. Pulse Amplitude Modulation (PAM)
- sampling theorem / Nyquist
- aliasing
- reconstruction
- time division multiplexing (TDM)
8. Pulse Width Modulation (PWM)
9. Speech and Audio messages
- message inversion
- message translation
10. Superheterodyne principles
DIGITAL BASICS
14. Pulse Code Modulation (PCM)
- encoding
- decoding & reconstruction
- sampling rate
- aliasing, undersampling and oversampling
- synchronization
15. Time Division Multiplexing (PCM – TDM)
16. Amplitude Shift Keying (ASK)
- modulation
- envelope recovery
- synchronous recovery
17. Binary Phase Shift Keying (BPSK)
- modulation/demodulation
18. Frequency Shift Keying (FSK)
- modulation
- envelope recovery
19. Introduction to GFSK
20. Pulse shaping
21. Data recovery in a noisy channel
22. Intersymbol Interference (ISI)
- eye patterns/diagrams
INTRO TO ADVANCED ANALOG
11. Carrier Acquisition using PLL
12. Signal to Noise Ratio (SNR) – Introduction to SNR
13. Quadrature Amplitude Modulation (QAM)
- modulation
- demodulation
INTRO TO ADVANCED DIGITAL
23. Differential Phase Shift Keying (DPSK)
- modulation/demodulation
24. Quadrature Phase Shift Keying (QPSK)
- modulation/demodulation
25. Spread Spectrum (SS)
- introduction to direct sequence spread spectrum (DSSS)
26. Line coding
- NRZ – L
- Alternate Mark Inversion (AMI)
- Manchester (Bi – phase)
- Differential encoding (NRZ – M)
27. Frequency Synthesis with PLL
28. PN sequence spectrum display
29. Noise generation
30. Introduction to Undersampling in Software Defined Radio
Additional Experiment Capabilities
- Introduction to Control Systems
- Using LabVIEW™ to control external electronic circuits
BiSKIT-101
Using the expertise from many years of manufacturing telecommunications teaching equipment, Emona is now offering the Emona Telecoms-Trainer “ETT101”. The ETT-101 is designed for introductory university courses and technical college labs where telecommunication is first introduced. The ETT-101 is a low cost unit to cater to large student numbers who need to gain a ‘hands-on’ appreciation of telecoms theory at a simple, introductory level.
Building Student Knowledge in Technology is what our equipment is all about, and so the ETT- 101 is also known as ‘BISKIT’, easy to say and easy to use.
The Emona Telecoms-Trainer 101 (ETT101) is a single board trainer that makes teaching telecommunications much easier for professors in introductory university and technical college courses.
Completely self contained within a single, low-profile case, the ETT-101 requires only a standard 12V DC plug-pack. Waveforms can be displayed on whatever equipment is available to the student, such as: a standard lab oscilloscope, or a PC-based scope. This dynamic visual approach helps students to see the relationship between modern telecoms methods and the math. The ‘hands-on’ approach builds student confidence and makes the experiment satisfying as the students are free to explore and learn by making mistakes. When they explore more, they learn more.
View a brief
3 minutes video presentation
ETT 101
Basic Analog Communications:
AM, FM, DSB, SSB, PAM, TDM, PWM, Superheterodyne, Speech in comms, PLL, QAM, SNR CONCEPTS
Digital Communications: Driver audio macbook a1181 windows 7.
PCM, PCM-TDM, ASK, BPSK, FSK, GFSK, Eye Patterns, DPSK, QPSK, Spread Spectrum, Line Coding, Delta Modulation, Noise Generation, SNR Concepts, and more
All experiments are fully documented, with questions and answer sections fully integrated into the text. Now you have a turn-key solution to teaching your communications program, with the capacity for expansion into the future. Download and print a comprehensive 4 page info sheet about the Emona Telecoms-Trainer 101.
The ETT-101 will build the student’s confidence and appreciation for math & theory
The ETT-101 Laboratory Manuals (Volumes 1 and 2) provide a turn-key solution for the teacher and student alike.The manuals are specially written to guide students through hands-on experiments and help them grasp the fundamental concepts of telecommunications. Each chapter includes background information which relates the experiment content to real-world applications.
Since telecommunications text books represent the math and concepts of telecommunications theory as ‘block diagrams’, the ‘101’ Lab Manuals make extensive use of block diagrams throughout. Associated with each block diagram are detailed, step-by-step patching diagrams. Each chapter is carefully paced and constant use is made of questions to verify the student’s understanding and provide feedback to the teacher.
The ETT-101 User Manual contains brief descriptions of each block function on the unit, its specifications and operating instructions. Students only need refer to this manual upon beginning a course, after which time using the system becomes easy and intuitive.
ETT-101 LAB MANUAL – Volume 1
(20 Chapters, 310 pages)
- Setting-up an Oscilloscope
- An Introduction to the ETT-101
- Modelling Equations
- Amplitude Modulation AM
- Double Sideband DSB Modulation
- AM Demodulation
- DSB Demodulation
- SSB Modulation & Demodulation
- FM Modulation
- FM Demodulation
- Sampling & Reconstruction
- PCM Encoding
- PCM Decoding
- BW Limiting & Restoring Signals
- ASK Modulation & Demodulation
- FSK Modulation & Demodulation
- BPSK Modulation & Demodulation
- QPSK Modulation & Demodulation
- Introduction to Spread Spectrum – DSSS modulation
- Undersampling in Software Defined Radio
ETT-101 LAB MANUAL – Volume 2
(22 Chapters, 456 pages)
- AM Method 2 & Product Detection
- Noise in AM Communications
- PCM and TDM
- Armstrongs’ Phase Modulator
- Phase Division Multiplex
- Pulse-Width Modulation &Demod
- Carrier Acquisition using the PLL
- SNR and Eye Diagrams
- PCM and SNDR
- ASK Demod using Product Detect
- FSK (switching method) &Demod
- Principles of GFSK
- PN Spectra and Noise Generation
- Line Coding and Bit Clock Regen
- Delta Modulation & Demodulation
- Delta-Sigma Mod &Demod
- Observations of AM & DSBSC in the Frequency Domain
- Principles of superheterodyne
- Frequency synthesis with digital PLL
- Differential phase shift keying (DPSK)
- PAM-time division multiplexing (TDM
- Full (IQ branch) Demodulation of a QPSK Signal
- Line Code Decoding and Hard Decision Making
- DPSK Modulation and Demod with a Noisy Channel
- FM Demodulation using the Phase-Locked Loop
- Signal constellation Diagrams
Vol.3 experiments require the ETT-101-20 or ETT-101-21 add-on boards
ETT-101 FIBER OPTICS LAB MANUAL – Volume 4
(11 Chapters, 184 pages)
- An Introduction to Fiber Optic Signal Transmission and Reception
- Guiding Light Using Total Internal Reflection*
- Losses in Fiber Optic Networks*
- Polarization*
- Bending Losses in Fiber Optic Systems *
- Connectors*
- PCM-TDM ‘T1’ Implementation
- Optical Signal Filtering, Splitting & Combining**
- Fiber Optic Bi-directional Communication**
- Wave Division Multiplexing (WDM)**
- Optical Losses**
* Experiments require the ETT-101-32 Physics of Fibers Accessory Kit.
** Experiments require the ETT-101-31 Coupler and Filters board.
ETT-101-10 ELECTRONIC CIRCUITS PROJECTS MANUAL
(14 Projects, 50 pages total)
- An Introduction to Fiber Optic Signal Transmission and Reception
- RC Circuits
- RL Circuits
- RC & RL Low-Pass Filters
- RC High -Pass Filters
- RC & RL Filters, Cut-off Frequency
- Measuring Filter Roll-off
- Measuring Filter Phase Response
- Series & Parallel RLC B-P Filters
- RLC Band-Stop Filters
- Effect of Components on Centre Freq. of Band-Pass & Band-Stop Filters
- Effect of Component Values on Bandwidth of Band-Pass Filters
- The Hartley Oscillator
- The Colpitts Oscillator
- The Clapp Oscillator
Many Experiments in a Compact System
Completely self contained within a single, low-profile case, the ETT-101 requires only a standard 12V DC plug-pack.
Emona 101 Trainer Sample Lab Manual Pdf
The ETT-101 accessories kit includes: 20 x stackable patch cords, User Manual, Digital and Analog Basic Telecommunications Experiments Manuals Volumes-1 & 2, and a 12V plug pack.
Emona 101 Trainer Sample Lab Manual 6th Edition
The ETT101 is unrivalled in offering a wide range of over 42 modern communications topics that can be studied with one compact trainer. The key to the ETT101’s versatility is it’s unique block diagram approach for building experiments. By working at the block diagram level, we are able to achieve many experiments in one system.