antenna training lab ats04 - tecnos · 3d software compatibility matlab 3d plot compliance ieee...

ANTENNA TRAINING LAB ATS04

Disclaimer: Images shown are Indicative only. Color or Model may differ from the picture shown (Features will remain same or More). Specifications are subject to change without notice.

Mfd by: Amitec Electronics Ltd. Regd. Off: 504, Nilgiri, 9 Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.amitec.co +91-11-41505510, +91-120-4371276

Features:

• 270MHz-3.8 GHz Antenna Training Lab with 20 antennas

• Fully Software controlled RF Transceiver with customizable frequency and power

• Software-controlled 3D positioner along 3D plotting and measurement software

• Transmit and receive any waveform, any modulation, any frequency, any protocol using any antenna

• Calibrated Signal Generator with precise power, frequency

• Calibrated Spectrum Analyser with precise power, frequency

• Directional Coupler & Coaxial Slotted line for Return loss, VSWR plotting

• -10dBm Transmit power & -100dBm Sensitivity Receiver

• All SMA connector antennas with RG316 cables

• Works seamlessly with Linux GNURadio, MATLAB, C++ and Python

• Open-licensing of experimentation and study material with No recurring cost!

• Latest generation of ASIC architecture with integrated LNA, PA, RX/TX Mixers, PLL, Synthesizers, RX/TX Filters, RX Gain control, TX power control

• Support for TDD and FDD configuration

• Highly stable 1 ppm TCXO.

Description:

ATS04 is the world’s most advanced Antenna Communication Training and Measurement Lab. It is the world’s first Complete 3D measurement training system providing True 3D pattern of an antenna. ATS04 complies with IEEE Std 149-1979, “Test Procedure for Antennas”. The complete setup requires minimum space and can be used as a benchtop system. The complete setup consists of: ➢ USB powered calibrated software-controlled Vector

Signal Generator and a calibrated software-controlled Vector Signal Analyzer

➢ Software-controlled 3D positioner with very low RCS ➢ Linux based Data Visualization and Management

Software ➢ More than 20 different antennas consisting of

narrowband, broadband, directional, Omni-directional and different polarizations

Broadband calibrated reference antenna for gain measurement and broadband directional coupler for return loss measurement. The setup works as spectrum analyzer, vector signal source and vector signal analyzer. It Covers broadcast television, satellite TV communication. Future ready from simple FM to QPSK, QAM standard to whatever future may hold.




Hardware Technical Specifications:

Transmit Receive Frequency Range 270MHz to 3.8GHz

3D Positioner RCS <-20dBsm

3D Software Compatibility MATLAB

3D Plot Compliance IEEE Standard 149-1979

Frequency Resolution 100Hz

Transmit/receiver Modulation Bandwidth 160MHz analog interface, 96 MHz Digital SISO

Compatibility Works with Linux GnuRadio, MATLAB, Simulink

Accessibility OSI layers for signal processing and development

Wireless transmission and reception Over the air transmission reception through antenna

Modulations supported Any, Custom Modulations possible

Mode Full Duplex, TDD, FDD

Maximum RF Output Power -10dBm at 1GHz Typical

Maximum Receiver Sensitivity -120 dBm at 1GHz Typical

TX/RX SMA Impedance 50 Ohm

TX/RX Gain Control Range & Step >60dB & 1dB Typical

Minimum Rx Noise Figure < 6dB at 1GHz Nominal

IQ Amplitude Error 0.5dB/-70dBc Image Typical

PLL Settling time <20us Typical

ADC/DAC Resolution & SFDR 12 bits & >60dBc SFDR Typical

Power USB Powered

THETA Start/ Stop Angle & Resolution 0 to 360 degrees in 0.1 degree

PHI Start/ Stop Angle 0 to 180 degrees in 0.1 degree

Power 24 V

Positioner Control Software control via USB Cable

Loading Capacity 0.5 kg

Shipping List Deliverable ATS04 Transceiver Unit, 3D Positioner, 20 Antennas and Accessories

RF Cable RG316 SMA-SMA X 4

Frequency Band Upgradable Other 5G bands 3.8-12.4 GHz optional, 18-26GHz optional, 26-40GHz Optional

Reference Antennas

Planar Reference Horn 0.8GHz – 4 GHz X 2




1. Microstrip Yagi 6. Endfire Phased array

Fc : 3.8 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 3dBi Feed : Microstrip balun Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

S11: >10dB Bandwidth: 3.6 + 0.1GHz Gain: 3dBi Beamwidth : E plane 600 Beamwidth : H Plane 1200 Polarisation : Linear Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold

2. Folded Dipole 7. Broadside phased array



3. Microstrip Dipole 8. Coplanar waveguide CPW Bow tie slot Antenna

Fc : 3.6 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear X Pol discrimination : 20dB Gain : 2dBi Feed: Microstrip balun Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

Fc : 3.6 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

4. Microstrip Slot 9.Wideband Bow tie Dipole Antenna

Fc : 3.8 + 0.1 GHz S11: >10dB Gain: 2dBi Beamwidth : E plane 600 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold

Fc : 3.8 + 2 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Substrate: Glass Epoxy Masking: Selective Plating: Selective Gold

5. Loop 10.Reference Logperiodic


S11: >10dB Bandwidth: 1 to 6GHz Gain: 4dBi Beamwidth : E plane 600 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio: 10dB Connector : SMA




11. Left Circularly Polarized Patch 16. Vivaldi (Planar Horn: Aperture Antenna)

Fc : 3.8 + 0.1 GHz S11 : 10 + 2dB Polarisation : LHCP Gain : 3dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

S11 : >6dB Bandwidth : 3 + 2 GHz Gain : 1dBi Beamwidth : E plane 800 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio : 0dB Connector : SMA

12. Right Circularly Polarized Patch 8. Microstrip Circular Patch Array 2 X 2

Fc : 3.8 + 0.1 GHz S11 : 10 + 2dB Polarisation : RHCP Gain : 3dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

Fc :2.4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Circular Gain : 7dBi Impedance : 50 Ohms Connector : SMA

21. Spiral Slot 18. Patch Array 2X2

Fc : 3 + 1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold


22. Log Spiral 19. Dual Rectangular Patch

Fc : 3 + 1 GHz S11: >10dB Gain: 2dBi Beamwidth : E plane 800 Beamwidth : H Plane 1200 Polarisation : Circular Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold


15. Monopole 20. Series fed patch array


S11 : >6dB Bandwidth : 3.6 + 0.3GHz Gain : 4dBi Beamwidth : E plane 400 Beamwidth : H Plane 400 Polarisation : Linear Front to Back Ratio : >8dB Connector : SMA




21. Directional Coupler 24. Coaxial Slotted Line & OSL

Bandwidth: 1 - 6 GHz Insertion S12 : 1.5 + 0.5 dB Coupling S13 : 20 + 2dB Isolation S14: 20 + 2dB Directivity S23: 15 + 3dB Impedance : 50 Ohms Connector : SMA Usage: Antenna forward & reverse power & VSWR measurements.

S11: >15dB, S12: <1.5dB Resolution: 0.05mm/ 0.15degree at 1.5GHz Coupling factor:-20dB Connector : SMA Residual VSWR : <1.2 Velocity propagation : 1.818X108m/s Wavelength/3600 phase : 121mm at 1.5GHz Total Length : 200mm 50Ohms, Short & Open

22. H & E probe 25. Antenna Plotting Software

H probe Type: Loop Rejection E/H: 40dB Frequency: upto 800MHz Sensitivity: High Diameter: 6cm E probe Type: Narrow Rejection H/E: 30dB Frequency: upto 3GHz Sensitivity: Low Size: 0.6cm

USB interface with 3D plotting software along with cartesian and polar plots, 3dB/10dB beam-width, Gain, Front to back, Side lobe level and position, Plot rotate, File- edit, save, get.

23. Transceiver 26. 3D Positioner

Transmit & Receive Frequency Range: 270MHz to 3.8GHz Frequency Resolution: 100Hz Maximum RF Output Power: -10dBm at 1GHz Typical Maximum Receiver Sensitivity: -120 dBm at 1GHz Typical

Software Compatibility: MATLAB Compliance IEEE Standard 149-1979 THETA Start/ Stop Angle & Resolution: 0 to 360 degrees in 0.1 degree PHI Start/ Stop Angle: 0 to 180 degrees in 0.1 degree

Scope of Experimentation

• Establishing a complete RF link with point-to-point connectivity

• RF Link budgeting and calculations

• 3D Antenna Radiation Pattern measurement with Data Visualization and Management Software

• Measurement of Antenna Gain parameter and other characteristics

• Experimentation with more than 20 different types of antennas

• Experiments covering practical impairments such as Doppler shift

• Simultaneous visualization in time and frequency domain of received signal for practical approach

• Custom waveform transmission with 28 MHz of instantaneous bandwidth for advanced experimentation and research such as LTE

• Completely configurable frequency range from 270 MHz to 3.8 GHz can be used for RF path loss and other practical measurements

• VSWR and Return Loss measurement of antennas with broadband directional coupler

• Vertical, Horizontal and Circularly polarized antenna

• Polarization discrimination of Linear and Circular antennas

• Resonant and non-resonant antenna

• Reciprocity of antenna

• Current distribution of an antennas and comparative study of antennas

• EM simulation results of all the antennas included for practical verification

• Practical Verification of antennas working in Quad-band GSM, 20 bands of 3G, 40 bands of LTE, GPS, GNSS, Wi-Fi, CDMA and applications such as IoT

• Can be upgraded and daisy-chained for MIMO antenna measurement




Features:

• 100KHz-12.4 GHz Antenna Training Lab with 30 antennas

• Fully Software controlled RF Transceiver with customizable frequency and power

• Software-controlled 3D positioner along 3D plotting and measurement software

• Transmit and receive any waveform, any modulation, any frequency, any protocol using any antenna

• Calibrated Signal Generator with precise power, frequency

• Calibrated Spectrum Analyser with precise power, frequency

• Directional Coupler & Coaxial Slotted line for Return loss, VSWR plotting

• -10dBm Transmit power & -100dBm Sensitivity Receiver

• All SMA connector antennas with RG316 cables

• Works seamlessly with Linux GNURadio, MATLAB, C++ and Python

• Open-licensing of experimentation and study material with No recurring cost!

• Latest generation of ASIC architecture with integrated LNA, PA, RX/TX Mixers, PLL, Synthesizers, RX/TX Filters, RX Gain control, TX power control

• Support for TDD and FDD configuration

• Highly stable 1 ppm TCXO.

Description:

ATS12 is the world’s most advanced Antenna Communication Training and Measurement Lab. It is the world’s first Complete 3D measurement training system providing True 3D pattern of an antenna. ATS12 complies with IEEE Std 149-1979, “Test Procedure for Antennas”. The complete setup requires minimum space and can be used as a benchtop system. The complete setup consists of: ➢ USB powered calibrated software-controlled Vector

Signal Generator and a calibrated software-controlled Vector Signal Analyzer

➢ Software-controlled 3D positioner with very low RCS ➢ Linux based Data Visualization and Management

Software ➢ More than 30 different antennas consisting of

narrowband, broadband, directional, Omni-directional and different polarizations

Broadband calibrated reference antenna for gain measurement and broadband directional coupler for return loss measurement. The setup works as spectrum analyzer, vector signal source and vector signal analyzer. It Covers broadcast television, satellite TV communication. Future ready from simple FM to QPSK, QAM standard to whatever future may hold.





Transmit Receive Frequency Range 100KHz to 12.4GHz

3D Positioner RCS <-20dBsm

3D Software Compatibility MATLAB

3D Plot Compliance IEEE Standard 149-1979

Frequency Resolution 100Hz

Transmit/receiver Modulation Bandwidth 160MHz analog interface, 96 MHz Digital SISO

Compatibility Works with Linux GnuRadio, MATLAB, Simulink

Accessibility OSI layers for signal processing and development

Wireless transmission and reception Over the air transmission reception through antenna

Modulations supported Any, Custom Modulations possible


Maximum RF Output Power -10dBm at 1GHz Typical

Maximum Receiver Sensitivity -120 dBm at 1GHz Typical

TX/RX SMA Impedance 50 Ohm

TX/RX Gain Control Range & Step >60dB & 1dB Typical

Minimum Rx Noise Figure < 6dB at 1GHz Nominal

IQ Amplitude Error 0.5dB/-70dBc Image Typical

PLL Settling time <20us Typical

ADC/DAC Resolution & SFDR 12 bits & >60dBc SFDR Typical

Power USB Powered

THETA Start/ Stop Angle & Resolution 0 to 360 degrees in 0.1 degree

PHI Start/ Stop Angle 0 to 180 degrees in 0.1 degree

Power 24 V

Positioner Control Software control via USB Cable

Loading Capacity 0.5 kg

Shipping List Deliverable ATS12 Transceiver Unit, 3D Positioner, 30 Antennas and Accessories

RF Cable RG316 SMA-SMA X 4

Frequency Band Upgradable Other 5G bands 18-26GHz optional, 26-40GHz Optional

Reference Antennas

Planar Reference Horn 0.8GHz – 12.4 GHz X 2




1. Microstrip Yagi 6. Endfire Phased array

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 3dBi Feed : Microstrip balun Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

S11: >10dB Bandwidth: 4 + 0.1GHz Gain: 3dBi Beamwidth : E plane 600 Beamwidth : H Plane 1200 Polarisation : Linear Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold

2. Folded Dipole 7. Broadside phased array



3. Microstrip Dipole 8. Coplanar waveguide CPW Bow tie slot Antenna

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear X Pol discrimination : 20dB Gain : 2dBi Feed: Microstrip balun Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

4. Microstrip Slot 9.Wideband Bow tie Dipole Antenna

Fc : 4 + 0.1 GHz S11: >10dB Gain: 2dBi Beamwidth : E plane 600 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold

Fc : 4 + 2 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Substrate: Glass Epoxy Masking: Selective Plating: Selective Gold

5. Loop 10.Reference Logperiodic


S11: >10dB Bandwidth: 1 to 6GHz Gain: 4dBi Beamwidth : E plane 600 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio: 10dB Connector : SMA




11. Left Circularly Polarized Patch 16. Vivaldi (Planar Horn: Aperture Antenna)

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : LHCP Gain : 3dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

S11 : >6dB Bandwidth : 3 + 2 GHz Gain : 1dBi Beamwidth : E plane 800 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio : 0dB Connector : SMA

12. Right Circularly Polarized Patch 8. Microstrip Circular Patch Array 2 X 2

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : RHCP Gain : 3dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

Fc :2.4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Circular Gain : 7dBi Impedance : 50 Ohms Connector : SMA

21. Spiral Slot 18. Patch Array 2X2

Fc : 4 + 1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 2dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold


22. Log Spiral 19. Dual Rectangular Patch

Fc : 4 + 1 GHz S11: >10dB Gain: 2dBi Beamwidth : E plane 800 Beamwidth : H Plane 1200 Polarisation : Circular Front to Back Ratio: 0dB Connector : SMA Masking: Selective Plating: Gold

Fc : 4 + 0.1 GHz S11 : 10 + 2dB Polarisation : Linear Gain : 5dBi Impedance : 50 Ohms Connector : SMA Masking: Selective Plating: Gold

15. Monopole 20. Series fed patch array


S11 : >6dB Bandwidth : 4 + 0.3GHz Gain : 4dBi Beamwidth : E plane 400 Beamwidth : H Plane 400 Polarisation : Linear Front to Back Ratio : >8dB Connector : SMA




21. Leaky wave antenna 26. Patch Microstrip circularly polarized

S11 : >6dB Bandwidth : 4 + 0.3GHz Gain : 2dBi Beamwidth : E plane 400 Beamwidth : H Plane 400 Polarisation : Linear Front to Back Ratio : >8dB Connector : SMA

S11 : >10dB Bandwidth : 10.3 + 0.1GHz Gain : 4dB Beamwidth : E plane 1200 Beamwidth : H Plane 1200 Polarisation : Circular Front to Back Ratio : >10dB Substrate : Ceramic based Connector : SMA

22. Dipole 27. Patch Microstrip

S11 : >6dB Bandwidth : 10.3 + 0.5GHz Gain : 1dB Beamwidth : E plane 800 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio : 0dB Substrate : Ceramic based Connector : SMA

S11 : >10dB Bandwidth : 10.3 + 0.1GHz Gain : 6dB Beamwidth : E plane 1800 Beamwidth : H Plane 800 Polarisation : Linear Front to Back Ratio : >10dB Substrate : Ceramic based Connector : SMA

23. Yagi 4 element 28. Patch Microstrip Array 2x1



24. Yagi 3 element 29. Patch Microstrip Array 2x2

S11 : >10dB Bandwidth : 10.3 + 0.1GHz Gain : 5dB Beamwidth : E plane 800 Beamwidth : H Plane 1000 Polarisation : Linear Front to Back Ratio : >10dB Substrate : Ceramic Connector : SMA


25. Monopole 30. Patch Microstrip Array 4x4

S11 : >6dB Bandwidth : 10.3 + 0.5GHz Gain : 1dB Beamwidth : E plane 800 Beamwidth : H Plane 1800 Polarisation : Linear Front to Back Ratio : 0dB Substrate : Ceramic based Connector : SMA





31. Directional Coupler 34. Coaxial Slotted Line & OSL

Bandwidth: 1 - 6 GHz Insertion S12 : 1.5 + 0.5 dB Coupling S13 : 20 + 2dB Isolation S14: 20 + 2dB Directivity S23: 15 + 3dB Impedance : 50 Ohms Connector : SMA Usage: Antenna forward & reverse power & VSWR measurements.

S11: >15dB, S12: <1.5dB Resolution: 0.05mm/ 0.15degree at 1.5GHz Coupling factor:-20dB Connector : SMA Residual VSWR : <1.2 Velocity propagation : 1.818X108m/s Wavelength/3600 phase : 121mm at 1.5GHz Total Length : 200mm 50Ohms, Short & Open

32. H & E probe 35. Antenna Plotting Software

H probe Type: Loop Rejection E/H: 40dB Frequency: upto 800MHz Sensitivity: High Diameter: 6cm E probe Type: Narrow Rejection H/E: 30dB Frequency: upto 3GHz Sensitivity: Low Size: 0.6cm

USB interface with 3D plotting software along with cartesian and polar plots, 3dB/10dB beam-width, Gain, Front to back, Side lobe level and position, Plot rotate, File- edit, save, get.

33. Transceiver 36. 3D Positioner

Transmit & Receive Frequency Range: 100KHz to 12.4GHz Frequency Resolution: 100Hz Maximum RF Output Power: -10dBm at 1GHz Typical Maximum Receiver Sensitivity: -120 dBm at 1GHz Typical

Software Compatibility: MATLAB Compliance IEEE Standard 149-1979 THETA Start/ Stop Angle & Resolution: 0 to 360 degrees in 0.1 degree PHI Start/ Stop Angle: 0 to 180 degrees in 0.1 degree


• Establishing a complete RF link with point-to-point connectivity

• RF Link budgeting and calculations

• 3D Antenna Radiation Pattern measurement with Data Visualization and Management Software

• Measurement of Antenna Gain parameter and other characteristics

• Experimentation with more than 20 different types of antennas

• Experiments covering practical impairments such as Doppler shift

• Simultaneous visualization in time and frequency domain of received signal for practical approach

• Custom waveform transmission with 28 MHz of instantaneous bandwidth for advanced experimentation and research such as LTE

• Completely configurable frequency range from 30 MHz to 12 GHz can be used for RF path loss and other practical measurements

• VSWR and Return Loss measurement of antennas with broadband directional coupler

• Vertical, Horizontal and Circularly polarized antenna

• Polarization discrimination of Linear and Circular antennas

• Resonant and non-resonant antenna

• Reciprocity of antenna

• Current distribution of an antennas and comparative study of antennas

• EM simulation results of all the antennas included for practical verification

• Practical Verification of antennas working in Quad-band GSM, 20 bands of 3G, 40 bands of LTE, GPS, GNSS, Wi-Fi, CDMA and applications such as IoT

• Can be upgraded and daisy-chained for MIMO antenna measurement

COGNITIVE RADIO WIRELESS COMMUNICATION LAB CRL04

Description:

A cognitive radio is an intelligent radio that can be programmed and configured dynamically. Its transceiver is designed to use the best wireless channels in its vicinity. Such a radio automatically detects available channels in wireless spectrum, then accordingly changes its transmission or reception parameters to allow more concurrent wireless communications in a given spectrum band at one location. This process is a form of dynamic spectrum management. The burden on faculty is lowered by using courseware designed at IITD. Lab technicians are eased by integrated hardware and software from same source for trouble free performance.

The system is ideally suited for applications requiring high RF performance and great bandwidth such as physical layer prototyping, dynamic spectrum access and cognitive radio, spectrum monitoring and even networked sensor deployment.

The Superspeed USB 3.0 interface at 5Gbps serves as the connection between the transceivers and the mobile workstation. This enables the user to realize 40 MS/s of real-time bandwidth in the receive and transmit directions, simultaneously (full duplex). FPGA is autoloading so hardware is plug and play as a pen drive! No need to program the FPGA for most cases!

Features:

• Courseware designed at Indian Institute of Technology Delhi• Define Number of Primary users• Define Number of Secondary users• Learn Spectrum Sensing Techniques: Co-operative, Non- cooperative, Interference based• Learn Primary transmitter detection: Energy based detection, Covariance based detection, Waveform based detection, any proprietary algorithm implementation Co-operative detection: Central server, Distributed• Create Adaptive Power Allocation• Create Adaptive Coding• Enable Frequency Hopping• Create Adaptive Waveform• Works with Linux GnuRadio, Compatible to LabVIEW™, MATLAB Simulink™ but does not need one!• ASIC Architecture: 0.4-4 GHz combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain control, TX power control • +5dBm Transmit power & -120dBm Sensitivity Receiver• FPGA program transmit & receive for high performance• Modulation Bandwidth Programmable upto 30 MHZ• Supports both TDD &FDD Full Duplex upto 30MHz• Calibrated +1ppm TCXO• Dual 40 MS/s, 12-bit ADC & Dual 40 MS/s, 12-bit DAC• Up to 5GbpS/s USB 3.0 Data Streaming to Computer• Alterra Cyclone FPGA with single cycle access memory, 18X18 multipliers for dedicated DSP & programmable general logic elements.

Disclaimer: Images shown are Indicative only. Color or Model may differ from the picture shown Features will remain same or More). Specifications are subject to change without notice

IITD1

Laptops not included

Hardware Technical SpecificationsTransceiver:Number of Primary users CustomizableNumber of Secondary users CustomizableSpectrum Sensing Techniques Co-operative, Non-cooperative, Interference basedPrimary transmitter detection Energy based detection, Covariance based detection, Waveform based detection, any proprietary algorithm implementationCo-operative detection Central server, DistributedPower Allocation AdaptiveCoding AdaptiveHopping FrequencyWaveform AdaptiveTx/Rx Frequency Range 0.3-4GHzMode Full Duplex/TDD/FDDArchitecture ASIC/FPGA/Zero IFBaseband Bandwidth <1-15MHzFrequency Resolution <3HzMaximum RF Output power +5dBmReceiver Sensitivity -120dBmPLL Phase Noise -125dBc/Hz at 1MHzSpurious Output -50dBcTx/Rx Gain Control Range >50dBTx/Rx Gain Control Step 1/3 dBTx/Rx IO Impedance 50 Ohms SMARx Noise Figure <5dBIQ Phase Error 3 degreeIQ Amplitude Error 0.5dBPLL Settling time 20usADC/DAC Sample Rate upto 40 MS/sADC/DAC Resolution 12 bitsADC/DAC Wideband SFDR 60 dBcI/O Amplitude 1Vp/p /250mV p/p differentialHost Sample Rate 50/25 MS/sFrequency Accuracy 2.5 ppmSSB/LO Suppression >40 dBcFPGA Altera CycloneIntegrated Transceiver 3 GbpsLogic Elements 40,000M9K Memory Blocks >400Embedded Memory >2000 Kbits18bit X18bit Multipliers >100PLL 4Maximum User I/Os >500Maximum Channels >200 DifferentialCurrent Consumption <500mA, USB drivenCable High Speed USB 3.0 Serial Cable, RG316 SMA-SMA X8, Antennas Directional LPDA 0.4-6 Ghz X4, Omni Directional Dipole 0.4-6 GHz X4

Upgrade 3 years auto upgrade of new experiments/training videos/ operation manuals/ firmware /support over internetShipping List Deliverable SDR X4 pcs, Antennas X8 SMA-SMA Cables X8 pcs USB3.0 Cable X4, Attenuator 20dBX4pcs

Software GUI features Boolean, Byte Operators, Channelizers, Channel Models, Coding, Control Port, Debug Tools Deprecated, Equalizers, Error Coding, File Operators, Filters, Fourier Analysis, GUI Widgets, Impairment Models, Instrumentation, Level Controllers, Math Operators, Measurement Tools, Message Tools, Misc, Modulators, Networking Tools, OFDM, Packet Operators, Pager, Peak Detectors, Resamplers, Sinks, Sources, Stream Operators, Stream Tag Tools, Symbol Coding, Synchronizers, Trellis Coding, Type Converters, Variables, Waveform Generators,


* Introduction to CRL04 Hardware and Software environment

* Define Number of Primary users

* Define Number of Secondary users

* Learn Spectrum Sensing Techniques: Co-operative, Non-cooperative, Interference based

* Learn Primary transmitter detection: Energy based detection, Covariance based detection, Waveform based detection, any proprietary algorithm implementationCo-operative detection: Central server, Distributed

* Create Adaptive Power Allocation

* Create Adaptive Coding

* Enable Frequency Hopping

* Create Adaptive Waveform

* On air transmission & reception using Digital Modulation & Demodulation techniques like ASK, FSK, BPSK, DBPSK, MSK, GMSK, DQPSK, QPSK, OQPSK, pi/4QPSK, 8PSK,16QAM, 64QAM, 256QAM, CPFSK, GFSK, and other variants,

* Spread spectrum techniques like CSS, DSSS, FHSS, THSS

* Multiplexing techniques like TDM, FDM/WDM,SDM, Polarization, Spatial, Packet Switching, MC-SS, OFDM etc

* Analog Channel Models like Noise (Uniform, Linear, Laplacian, Gaussian, Phase noise), Interference (Cross talk, Co-channel, Inter symbol), Distortion (Inter modulation), Frequency response (Attenuation & phase shift), Group delay, Propagation Doppler shift, Fading modeling slow, fast, selective/dispersive, Multipath, Rayleigh, Rician),

Disclaimer: Images shown are Indicative only. Color or Model may differ from the picture shown Features will remain same or More). Specifications are subject to change without notice

Mfd by: Amitec Electronics Ltd.Regd. Off: 504, Nilgiri, Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.sdr-lab.com, www.amitec.co+91-120-4371276, +91-9971-663434, 98101-93153, 98118-39949,

2

Scope of Experimentation Contd.

*Channel Coding & decoding-Convolutional, Viterbi,Trellis,

* Channel performance measurements (spectral bandwidth, Symbol Rate, Bit Rate, Channel Capacity, Channel Utilization, Signal to noise ratio, Bit Error Rate BER, Latency, Jitter, Eye Diagram, Constellation diagram, Oscilloscope, Spectrum Analyser, Waterfall display

*Coginitive Radio Experiments in Power Control, Spectrum Sensing, Transmitter Detection, Matched Filter Detection, Energy Detection, Cyclostationary feature detection, Single Cycle detector, Multi Cycle detector, Moment based detectorWideband Spectrum Sensing,

* Line Coding & Decoding Digital Baseband

* Filters-IIR, FIR, Pulse Shaping-RRC root raised cosine, High pass, Low pass, Bandpass, Band stop, FFT, frequency translating filter,

* Equalizer adaptive-CMA , Kurtotic, LMS DD

* Synchronizers-Costas Loop, Clock Recovery, Frequency locked loop, phase locked loop, correlate and sync, carrier acquisition,

* Modeling mathematical equations

* Networking- TCP, UDP, Socket, Broadcasting,

* Encoding decoding for data, voice & video-PSK31, MPEG, CVSD and more

* On air link for Voice, Data, Video,

Student projects Research And more.....

Cognitive Radio Block Diagram

Cognitive Radio Architecture

Transceiver Architecture

IITD

Cognitive Radio Benefits

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Mfd by: Amitec Electronics Ltd.Regd. Off: 504, Nilgiri, Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.amitec.co+91-11-41505510, 9810193153, 9971663434, 9811839949

Graphical Programming Environment OFDM Signal Captured on air at 1GHz

IITD

QAM 256 Received Signal Spectral Display at 1GHz GMSK FFT

QPSK Scope QAM 256 on air capture at 1GHz

QPSK combined windows on MATLAB OFDM Time Domain captured on air at 1GHz

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Disclaimer: Images shown are Indicative only. Color or Model may differ from the picture shown (Features will remain same or More). Specifications are subject to change without notice due to continuous improvement of product.

DUAL RIDGE HORN ANTENNA DRH20

Amitec Dual Ridge Horn Antenna DRH20Useful for antenna gain, bandwidth pattern testing, immunity and emission testing, EMI measurements and also for EW. Aluminum and fibre glass construction for long life. Technical Specifications:Frequency Range : 0.8-18GHzGain(Typ.) : 5dBi to 14dBiPolarization : LinearPolarization decoupling : >25dBVSWR (Typ.) : <2.03dB Beam width : 52-24 degreeNet Weight : 1.1KgsConnector : N type FemaleMounting Bracket : Aluminum right angled plates with screws

Dimensions: 56X41X18 cms. Weight: 2 kg.

Mfd by: Amitec Electronics Ltd.Regd. Off: 504, Nilgiri, 9 Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.amitec.co+91-11-41505510, +91-120-4371276


DIGITAL RADAR TRAINING LAB DRT04



Laptops not included Features: • Courseware designed at Indian Institute of Technology Delhi * Learn next generation Radar technologies • Works with Linux GnuRadio, Compatible to LabVIEW™, MATLAB Simulink™ but does not need one! • No recurring cost of software. Ever ! • ASIC Architecture: 0.4-4 GHz combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain control, TX power control – 2 Radios • +5dBm Transmit power & -120dBm Sensitivity Receiver • FPGA program transmit & receive for high performance • Differential Baseband Signals • Modulation Bandwidth Programmable upto 30 MHz • Supports both TDD &FDD Full Duplex upto 30MHz • Calibrated +0.04 ppm TCXO (Almost no need for GPSDO!) • Dual 40 MS/s, 12-bit ADC & Dual 40 MS/s, 12-bit DAC • Up to 5GbpS/s USB 3.0 Data Streaming to Computer • MIMO Capability – 2X2 and 4X4 • 200MHz ARM9 with 512KB embedded SRAM • Alterra Cyclone FPGA with single cycle access memory, 18X18 multipliers for dedicated DSP & programmable general logic elements • Works as spectrum analyzer, vector signal generator & vector signal analyzer • Covers white spaces, broadcast television, public safety, land-mobile communications, low-power unlicensed devices, wireless sensor networks, cell phones, amateur radio bands. • Future ready from simple doppler to phased array radars to whatever future may hold • Hundreds of experiments and growing.....

Description:

The Amitec DRT04 is a software defined radio radar. Instead of classical microwave radars which use hardware blocks for signal processing, this uses software signal processing to implement a variety of radars. Thus a single hardware transceiver allows limitless radar laboratory experiments to be performed on a single device. The entry barrier is lowered to include the under graduate students by providing a graphical programming environment. The burden on faculty is lowered by using courseware designed at IITD from simple doppler to most complex MIMO OFDM radars. Lab technicians are eased by integrated hardware and software from same source for trouble free performance. The system is ideally suited for applications requiring high RF performance and great bandwidth such as physical layer prototyping, dynamic spectrum access and cognitive radio, spectrum monitoring and even networked sensor deployment. The Superspeed USB 3.0 interface at 5Gbps serves as the connection between the DRT04 and the mobile workstation. This enables the user to realize 40 MS/s of real-time bandwidth in the receive and transmit directions, simultaneously (full duplex). FPGA is autoloading so hardware is plug and play as a pen drive! No need to program the FPGA for most cases! The systems offers MIMO capability with high bandwidth and dynamic range. Two units may be connected to realize a complete 2x2 MIMO configuration. External PPS and reference inputs can also be used to create larger multi-channel systems. ASIC houses complete RF and DAQ subsystems on a single board. Coupled with these benefits it hosts onboard RF Transceiver subsystems capable of tuning frequencies from 400MHz to 4GHz.




Hardware Technical Specifications DRT04: Transmit Frequency Range 0.4-4GHz Receive Frequency Range 0.4-4GHz Mode Full Duplex/TDD/FDD Architecture ASIC/FPGA/Zero IF Baseband Bandwidth <1-15MHz Frequency Resolution <3Hz Maximum RF Output power +5dBm Receiver Sensitivity -120dBm Tx Output Impedance 50 Ohms SMA PLL Phase Noise -125dBc/Hz at 1MHz Spurious Output -50dBc Transmit Gain Control Range >50dB Transmit Gain Control Step 1dB Rx Input Impedance 50 Ohms SMA Rx Noise Figure <5dB Rx Gain Control Range >50dB Rx Gain Control Step 3dB IQ Phase Error 3 degree IQ Amplitude Error 0.5dB PLL Settling time 20us ADC Sample Rate upto 40 MS/s ADC Resolution 12 bits ADC Wideband SFDR 60 dBc Input Amplitude 1Vp/p differential DAC Sample Rate upto 40 MS/s DAC Resolution 12 bits DAC Wideband SFDR 60 dBc Output Amplitude 250mV p/p differential Host Sample Rate 50/25 MS/s Frequency Accuracy 2.5 ppm SSB/LO Suppression >40 dBc FPGA Altera Cyclone Integrated Transceiver 3 Gbps Logic Elements 40,000 M9K Memory Blocks >400 Embedded Memory >2000 Kbits 18bit X18bit Multipliers >100 PLL 4 Maximum User I/Os >500 Maximum Channels >200 Differential Current Consumption <500mA, USB driven Cable High Speed USB 3.0 Serial Cable, RG316 SMA-SMA Antennas Directional LPDA 0.4-6 GHz, Omni Directional Dipole 0.4-6 GHz

Upgrade 1 year auto upgrade of new experiments/training videos/ operation manuals/ firmware /support over internet Shipping List Deliverable SDR X 2 pcs, Antennas X 4 SMA-SMA Cables X 4 pcs USB3.0 Cable X 2 Attenuator 20dB X 2pcs Software GUI features Audio, Boolean, Byte Operators, Channelizers, Channel Models, Coding, Control Port, Debug Tools Deprecated, Equalizers, Error Coding, File Operators, Filters, Fourier Analysis, GUI Widgets, Impairment Models, Instrumentation, Level Controllers, Math Operators, Measurement Tools, Message Tools, Misc, Modulators, Networking Tools, NOAA, OFDM, Packet Operators, Pager, Peak Detectors, Resamplers, Sinks, Sources, Stream Operators, Stream Tag Tools, Symbol Coding, Synchronizers, Trellis Coding, Type Converters, Variables, Waveform Generators. Scope of Experimentation * Introduction to Radar Hardware and Software environment * Learn about CW radar Hardware and Simulation * Learn about FSK Radar Hardware and Simulation * Learn about Dual CW Radar * Learn about FMCW radar Simulation * Learn About OFDM radar simulation * Learn about peak detection algorithms & CFAR * Learn about time plot, spectrogram, scatter plot * Learn about Processing blocks: Crop matrix, Transpose matrix OFDM cyclic prefix remover, OFDM matrix division with zero padding and discarding carriers, Split packages for FMCW and FSK, FFT for tagged streams, Message manipulator and gate for target property messages

Amitec GigaHertz Transverse Electromagnetic Cell (GTEM) GTE10

Features* Radiated Immunity and Radiated emissions testing * Broadband TEM Cell up to 10 GHz* Small size, Small footprint for Indoor application * High effective shielding to 80dB* Specifically designed for all types of Mobile Phones/Biological Samples * N Socket RF Connector* Highly uniform vertical Electric field <6dB* Impedance 50Ohms* Broadband from DC-10GHz so no antenna changes * Far Field free space condition emulation

The Amitec- GTE10 Gigahertz Transverse Electromagnetic (GTEM) Cell is a precision electromagnetic compatibility (EMC) test instrument primarily intended for use as an EMC radiated immunity and radiated emissions test facility. It is intended for installation in a corporate, laboratory, or industrial environment, where its unique characteristics allow for the performance of fast and efficient EMC radiated tests at a convenient location, without interference from the ambient electromagnetic environment.The GTE10 is a pyramidal tapered, dual-terminated section of 50-ohm transmission line. The cell is flared to create a test volume within which the Equipment Under Test (EUT) is placed. At the input, a normal 50-ohm coaxial line is physically transformed to a rectangular cross section with an aspect ratio of 3:2 horizontal to vertical. The center conductor, known as the septum, is a flat, wide conductor which, when driven by a signal generator, produces a reasonably sized region of a nominally uniform electric field distribution beneath it. This region of nominally uniform field is the test volume for radiated immunity (susceptibility) testing. By the theory of reciprocity, radiated emissions testing is also conducted in the test volume. To increase the usable test volume, the septum is located well above the horizontal centerline of the cross section, while maintaining constant characteristic impedance

and uniform field distribution. The septum is terminated in a resistive array having a total value of 50 ohms for matching the impedance of the source. Test volume fields, either applied to an immunity test item or produced by the EUT during emissions testing, are terminated in RF absorber. The shape of the test volume is a tapered wedge. The fields generated by application of an RF voltage to the input of the GTE10 propagate with a spherical wave front from the apex of the GTE10 to the termination.

Amitec GTE10 Technical Specifications:Outer Cell Dimension: L: 220cm X B:120cm X H:80cmApprox. Cell Weight: 70kgsDoor Dimension: 30cm X 25cmMax Septum Height: 40cmUniform Field area: W=200mm H=200mmFrequency Range: 9KHz-5GHz RE Test where OATS correlation demonstrated DC-10GHz RI Test Low VSWR to f < 20 GHz; performance dependent on field uniformity toleranceInput Impedance: 50 OhmsConnector: N type SocketVSWR Max typical: <1.75:1 <1.5:1 on resistor absorber crossover characteristic frequencyField Uniformity : 0-6dB 75% of pointsMax CW Input Power : 10WShielding Effectiveness: >80dB from internal E fields 10KHz-1GHzOptions: * Custom Electrical Filters* Custom Feedthrough Panels* EUT XYZ Axis Positioning Device* EUT Illumination* Forced Ventilation* High Power ConfigurationE-Manual: Installation Video for ease of LearningDim: 240X140X100cm

GIGAHERTZ TRANSVERSE ELECTROMAGNETIC CELL GTE10

Keywords: GTEM, GigaHertz Transverse Electromagnetic Cell, RI, RE, EMC, TEM, Microwave, Absorber,



2G MOBILE COMMUNICATION LAB MCL02


Mfd by: Amitec Electronics Ltd. Regd. Off: 504, Nilgiri, 9 Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.amitec.co

+91-11-41505510, +91-120-4371276

Features: • 2.5G GSM Voice, SMS & GPRS BTS + UE + Backhaul replication in Lab

• 400MHz to 3400MHz Software Configurable Radio Transceiver for Quad band GSM operation • Low power for FCC compliant license free safe operation

• No recurring cost of software or licenses • ASIC Architecture: combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain control, TX power control

• +5dBm Transmit power & -120dBm Sensitivity Receiver • FPGA programmable transmission and reception for low latency • Supports both TDD & FDD Full Duplex as per 3GPP standards

• Calibrated +0.1ppm TCXO frequency reference Description:

The Amitec MCL02 is intended for lab use and ideal for universities, testing labs. It allows to replicate small 2.5G GSM (Voice + GPRS) cellular network and start making calls in less than an hour. It allows you

to connect a standard GSM mobile phone directly with VOIP networks as SIP endpoint to call PSTN landline or mobile phone on other networks in other locations using a software based GSM BTS . The lab is complete

with base transceiver station, multiband cellular phones, backhaul radio. Base station controller (BSC) functions and operations/maintenance (O&M) and network management system (NMS) functions for controlling

the base stations with software provided for exceptional value & performance.

A multiband software configurable radio performs the function of BTS which facilitates wireless communication between User Equipment UE or GSM cellular phones in this case. Users can bring their own devices or

the android phones provided with special apps that allow calculation of ARFCN, measurement of RF signal level of BTS for call handover handoff study and various other experiments. Users can roam about in lab environment while connected on a voice call inside and outside the

cell radius of BTS. The system is based on a reconfigurable RF/FPGA/ARM hardware

platform as Um air interface and a BTS software which implements the lower three layers of GSM protocol stack.

The system replaces the conventional GSM operator core infrastructure with inbuilt BSC and radio resource management function. Multiple systems can share a common VOIP soft switch or PBX to form larger

networks. ASIC houses complete RF and DAQ subsystems on a single board. It

hosts onboard RF Transceiver subsystems capable of tuning frequencies from 400MHz to 3.4GHz.

Area & scope of Experiments: 1. Introduction of mobile communication equipment BTS, BSC & UE. 2. To measure the spectral distribution of GSM frequencies at given

location and find a free channel. 3. To configure the BTS software to set Mobile country code, Network operator code, GSM band and ARFCN channel.

4. To configure the BTS Software to enable open/limited registration. 5. To assign a phone number to each registered phone. 6. To enable call logging of subscribers on BTS.

7. To get and set your IMSI. 8. To configure the asterisk communication server for IP PBX and VOIP gateway.

9. To register phone to the BTS network. 10. To transmit and receive an SMS using BTS. 11. To list the TMSI of the phones registered on network.

12. To establish a voice phone call as echo on mobile phone using BTS. 13. To establish a voice phone call to another cellular phone using BTS. 14. To establish a voice phone call to another cellular phone using

14. To establish a voice phone call to another cellular phone on different network/country using BTS and VOIP gateway. 15. To establish roaming between BTS and UE.

16. To capture GSM packets using Wireshark. 17. To establish a data communication link using GPRS. 18. To study hard & soft call handoff.

And many more.




+91-11-41505510, +91-120-4371276

Hardware Technical Specifications ASIC Architecture Combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain Control and TX Power Control Interfaces For operation, Administration and Maintenance Centre Supports Remote s/w upgrade and power system monitoring with easy CLI Frequency band 400-3400 MHz includes GSM Quad Band Channel Center Freq. Conforms to GSM Specifications Channel 200 KHz No of RF Carriers 124/374 Carrier spacing 200 KHz Duplex spacing (TX-RX Separation) 45 MHz / 95 MHz Access ch. per carrier Conforms to 3GPP TS 45.002 Frame structure Conforms to 3GPP TS 45.001 Time slot per RF carrier 8 Modulation GMSK, 8- PSK Demodulation Coherent Transmission bit rate 270.83 Kbps Data Transmission rate > GPRS, Channel Coding Rate Rate 1/2 convolution code with interleaving pulse Error detection Delay Equalization 20 micro sec Interference Specification - (a)Co-Channel interference f0 C/Ic (b)Interference on first adjacent channel (f0 ± 200 KHz) C/Ia1 (c)Interference on second adjacent channel (f0 ± 400 KHz) C/Ia2 (d)Interference on the third adjacent channel (f0 ± 600 KHz) C/Ia3 (e)Where Ia1 = adjacent channel interference la/lc = adjacent channel interference C/Ia1 = threshold from C/Ic (Ic: co-channel interference) Adjacent channel power -69 dBc or -36 dBm whichever is higher Combiner Inter-modulation -70 dBc or 250 nW whichever is higher Inter-modulation atten. 70 dB Idle Channel Noise Conforms to 3GPP TS51.010-1. Quantization Distortion Conforms to GSM Specs Spurious and Harmonics Conforms to radio regulations of ITU-R (a) 250nW (-36 dBm) in band 9 KHz to 1 GHz (b) 1-uW (-30 dBm) in band 1 to 12.75 GHz Frequency stability better than 0.05 PPM Interleaving scheme Conforms to GSM TS 45.003 Access Technology TDMA Duplex techniques FDD Speech CODECs support FR (Full Rate) Speech CODEC Bit Rate 13Kb/s BER at input level of -85 dBm of non-protected bits for - (a) Static < 10 -4 (b) Mobile Channel < 3% Clock Extraction Adaptive or GPS

One way transmission delay on Abis , except for A-bis on Satellite < 60 ms Output power at antenna 1mW Base Station Receiver Conforms to 3GPP 45 and 3GPP 51.021. Frequency hopping support in non BCCH TRX Power control in non-BCCH TRX Data Streaming Upto 400MS/s Backhaul Support (a) Radio (b) Satellite (c) Leased line (d) IP Network over Fast/Gigabit Electrical / Optical Fiber (e) E1 NetworkIs Compliance & Proof EMI/EMC Mount On the mast or inside the vehicle Overall weight < 3Kg Cooling The BTS is designed for self cooling and not require any forced cooling Interface USB 3.0 Super Speed between Host controller & BTS Transceiver BTS software Supports unlimited TRX. GPRS Supports functionality PDCH Supported GSM Antenna Specification (a) Operating Frequency 700- 2700 MHZ (b) Type of Antenna Omni & Directional (c) Minimum Gain 6 dBi for Directional Antenna 1 dBi for Omni Antenna (d) VSWR better than 1.5 (e) Nominal impedance 50 ohm Antenna mount All the fixtures required for mounting are provided Beam width 90 Degree for Directional 360 Degree for Omni Lightening Protection DC grounded Weight <1Kg Antennae Tilt Easily adjustable Processor CPU 64 bit >2GHz Onboard Graphics Intel HD RAM 4GB [email protected] R/W Speed >100MBps Ports Gigabit LAN Mobile User Equipment Quad Band GSM + 3G + 4G + WiFi OS + CPU + GPU Android 4.4, Snapdragon + Adreno Backhaul Radio 6GHz, 100Mbps, Ptp/PtMp, 802.11a/n, 16dBi antenna Modulations Backhaul OFDM: BPSK, QPSK, 16 QAM, 64QAM DSSS: DBPSK, DQPSK, CCK Deliverables BTS X1pc, UE X1pc, Antenna Directional & Omni X2pcs, Mast X1pc, Blank SIM X1pcs, SIM Programmer X1pc, Backhaul X1pcs Options GSM Power Amplifier 100mW to 10W for increased range to 64 sq. km for licenced users




+91-11-41505510, +91-120-4371276

The figure shows a full-scale amitec MCL02 network with complete integration into the internet, PSTN (Public Switched

Telephone Network) and legacy PLMN (Public Land-Mobile Network). All of these components are deployed in single

Network in Box provided!!!




+91-11-41505510, +91-120-4371276

Overview

Amitec MCL02 is a new breed of network equipment. It is meeting the demand for low cost, easy to install GSM cellular networks for remote rural

service, rapid deployment and private industrial networks on ships, oil rigs or in mines.

The main feature of amitec systems is the replacement the conventional 2G/3G network's SS7-MAP structure (Signaling System #7 is a protocol

that has dominated telephone system core networks since the 1980's. It is the basis for ISDN and Intelligent Network technologies. The Mobile

Application Part (MAP) is an extension added to SS7 in the 1990's to support functions required by cellular networks.) and all of its various

components (MSCs, BSCs, TRAUs, SGSNs, etc.) with a more modern SIP network, but without any changes to the handsets.

This approach offers the following advantages:

• much lower deployment costs (CAPEX), especially for small operators

• much lower operating costs (OPEX), for carriers of all sizes

• plug-in compatibility with existing SIP-based core networks

• plug-in compatibility with future IMS core networks

The key ingredient that makes this change possible is a software defined radio SDR implementation of the GSM radio access network that presents

normal GSM handsets as virtual SIP endpoints. In other words, through SDR BTS, any GSM handset appears as a SIP device, without the need for

any special software on the phone.

Significant cost savings from this approach are due to several factors:

• For small networks, the core network hardware can be reduced to a single commodity server, or core network applications can even be run on

excess resources in the base stations themselves.

• For larger networks, the core network hardware is based on commodity servers and IP routing equipment, making it possible for the provided to

have one shared IP network for both data and voice.

• Because all of the cellular network software runs on Linux and connects with commonly used TCP/IP and UDP/IP protocols, the core network can

even be virtualized and run in a “cloud” service, like Amazon's Ec2.

• All of the proprietary software found in a conventional GSM network can replaced with open-source applications like open-source applications

like SIP Express Router (SER), Yate, Apache web server and MySQL database server, eliminating recurring licensing fees.

• Because the new core network is based on IETF internet-age protocols, newly graduated engineers and software developers do not require

additional training to deal with archaic SS7 technologies.

Beyond cost savings, the conversion of the network from legacy telco protocols to internet protocols gives the operator new opportunities to

implement custom speech, text and USSD applications, using web service technologies like Apache and Ruby, or through cloud-based application

platforms like Tropo or Twillio. These applications can even be installed in individual cell sites to provide locally-tailored service.

The components of the network are RAN Nodes, Subscriber Registry SR, PSTN Gateway, Messaging Server MS, Internet Gateway implemented in

MCL02.

The system allows network to be integrated to PSTN, Legacy PLMN for SMS and Roaming support, 4G IMS Networks, Small Network for rapid

deployment, Satellite backed small sites and Mixed 2G/3G/4G networks.

Features

1. Microwave Network Analyser VNA04

* 0.04-4.4 GHz PLL Microwave Signal Generator.* 1KHz Frequency Step size and Accuracy. * 1 MHz-4.4 GHz RF Power meter with -70dBm sensitivity.* Win7/XP PC control, display and analysis in real time.* 0.5-4.4 GHz Directional Coupler with 35dB directivity.* 0.5-4.4 GHz Slotted Line with 1.1 VSWR.* 25 different MIC modules provided. * Gold SMA connectors on low loss ceramic substrate.* Wide power range +20dBm to -70dBm.* High measure speed at all power levels.* Measurement in dBm & dB relative.* Teflon cables are provided for low loss interconnects.

Technical Specifications:

Start Frequency : 40.000MHzStop Frequency : 4400.000MHzStep Size : 1KHz to 4GHz adjust in 1KHz stepStep Time : 10ms to 1s adjustableFrequency Control : Virtual Keypad & Rotary KnobFrequency Jitter : <1psPhase Noise : -80dBc/Hz at 10KHz OffsetRF Level : +20 dBm typicalAttenuator : 0-31.5dB adjustable in 0.5dB stepsOutput Z : 50 ohmsConnector : Gold plated SMATimebase : Internal TCXO/ External for SyncFrequency range : 1MHz to 4.4 GHz Power range : -70dBm to 0dBmResolution : 0.01 dB Measurement : dBm, dBr With Digital DisplayRelative Offset : +20.0 to -70.0dBmImpedance : 50 OhmsNetwork AnalyserDisplay : Frequency vs Power level PlotFunction : Automatic Calibration with Display Normalisation, Marker, PAN, Zoom, AutoscalingCalibration Data : Stored in EEPROM

2. Coaxial Slotted Line

S11: S12: >15dB, <1.5dBResolution: 0.05mm/ 0.15degree at 1.5GHz) using vernierCoupling factor:-20dBConnector : SMAResidual VSWR : <1.2Velocity propagation 8 : 1.818X10 m/s

0Wavelength/360 phase : 121mm at 1.5GHzTotal Length : 200mm

3. Directional Coupler

Bandwidth: 1 - 6 GHzInsertion S 12 : 1.5 + 0.5 dBCoupling S13 : 20 + 2dB

Isolation S14: 20 + 2dB Directivity S23: 15 + 3dBUsage: Antenna forward & reverse power & VSWR measurements.Substrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

MICROWAVE INTEGRATED CIRCUIT TRAINING LAB MIC04


8. Microstrip Couplers : Coupled Line Directional CCD30

7. Microstrip Couplers : Hybrid Ring Rat Race HRR30

Fc :3.0 + 0.2 GHz

Insertion S 21 : 1.5 + 0.5 dBCoupling S31: 14 + 2dB Isolation S41: 30 + 2dB Directivity S34: 16 + 2dBImpedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc :3.0 + 0.2 GHz

Insertion S21 : 3 dBCoupling S31: 3.5 + 1dBIsolation S41 : 20dBPhase Shift 0: 180

Impedance : 50 OhmsConnector : SMASubstrate : Ceramic Finish : Gold Plated with selective MaskingCover : Scratch resistant

12. Modulator : PIN Diode Variable Attenuator PVA30

13. Microstrip PIN Diode Switchable Attenuator PSA30

11. Microstrip Switch : PIN Diode SPST Switch PSS30

9. Microstrip Filter : Band Stop Open Stub BFO30

10. Microstrip Filter : High Pass Short Stub HPS30

Fc = 3.0 + 1 GHzInsertion Loss : 3 dBIsolation : 20dBReturn Loss : 10 dBAttenuation : 0-20dBControl Voltage : 0.2-9VImpedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 1 GHz

Insertion Loss : 1.5dBIsolation : 20dBAttenuation : 20dBImpedance : 50 OhmsConnector : SMAOperating Current : 35mAOperating Voltage : 12V DCSubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc = 3.0 + 0.5 GHz

Insertion Loss: 3.5 dBReturn Loss : 15 dBIsolation : 25dBImpedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Type : Open StubOrder : 3Fc : 3.0 + 0.1 GHzInsertion Loss S 21 : 2.5dBReturn Loss S11 : 10 dBStop Band S21: 20dB

Impedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Type : Short StubOrder : 3Fc : 3.0 + 0.1 GHzInsertion Loss S 21 : 3dBReturn Loss S11 : 10 dBStop Band S21: 20dB


4. Microstrip Couplers : Unfolded Lange Coupler ULC30

5. Microstrip Couplers : Folded Lange Coupler FLC30

6. Couplers : Branch Line Quadrature Hybrid BQH30

Fc : 3.0 + 0.2 GHz

Insertion S 21 : 2.5 + 1dBCoupling S31: 4.5 + 1dB Isolation S41: 20 + 2dB Directivity S32: 16 + 2dBImpedance : 50 OhmsConnector : SMASubstrate : Ceramic Finish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 0.2 GHzInsertion S21 : 5 dBIsolation S41 : 16dBCoupling S31: 5 + 1dB Phase Shift 0: 90 Impedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 0.2 GHz

Insertion S21 : 3.5 + 1 dB Coupling S31: 3.5 + 1dB Isolation S41: 20 + 2dB Directivity S23: 16 + 2dBImpedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant



14. Amplifier : PHEMT Low Noise Amplifier FET30

15. Amplifier : MMIC InGaP HBT Amplifier HBT30

16. Mixer: Double Balanced MIX40

18. Microstrip Resonator : Ring resonator RRR30

17. Microstrip Circulator CIR30

Device : InGaP HBTFc : 3.0 + 1 GHz

Gain : >15dB1dB Compression : 10dBmNoise Figure : 3.5dBImpedance : 50 OhmsConnector : SMAOperating Current : 35mASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Freq Lo/RF : 1.6 - 6 GHz

Freq IF : DC-2GHzConversion Loss : 8dBLO Drive Level : +7dBmLO/RF S :11 -20 + 2dBLO/RF S :11 -15 + 2dBConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Ring ResonatorFc : 3.0 + 0.1 GHz

S11 : -2 + 1dB

S21 : -20 + 2dB

Q : 100 typicalConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 0.1 GHz

Insertion Loss : <1dBIsolation : >20dBImpedance : 50OhmsS :11 -15 + 2dBConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Device : PHEMTFc : 3.0 + 1 GHz

Gain : >15dB1dB Compression : 10dBmNoise Figure : 0.5dBImpedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective Masking

23. Microstrip Wilkinson Equal Power Divider WEP30

24. Microstrip Wilkinson Unequal Power Divider WUP30

21. Loads : Mis-matched/matched Loads MMM30

19. Microstrip Half Wave Resonator HWR30

20. Microstrip Tapered Line Transformer TLT30

Fc : 3.0 + 0.2 GHz

Isolation : 15 + 2dB

Insertion Loss : 3.5 + 0.5dBAmplitude Unbalance : 0.5dBPhase Unbalance : <5 degreesConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc = 3.0 + 0.2 GHz

Isolation = 15 + 2dB

Insertion Loss = 3.5 dB + 0.5dBAmplitude Unbalance: 3dBPhase Unbalance : <10 degreesConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 0.2 GHz

Return Loss : 20/6/0/0 dBLoad : Quarter wave matched, VSWR 3, Open & Short StubsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc :3.0 + 0.1 GHz

S11 : -2 + 1dB

S21 : -20 + 2dB

Q : 100 typicalConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 3.0 + 0.5 GHz

Return Loss : 10 dB at 3GHzVSWR = 3 at DCLoad : 150 Ohms Connector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant



25. Microstrip VCO : Voltage Control Oscillator VCO40

26. Microstrip Schottky Diode Detector SDD30

27. Microstrip Bandpass Filter Tapped Hairpin BFT30

29. Microstrip Filter : Low Pass Stepped Impedance

28. Microstrip Low Pass Filter Open Stub LFO30

Fc = 3.0 + 2 GHz

Return Loss : 10 dB at 3GHzDynamic Range: -30dBm to +20dBmConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Order: 7Fc: 3.0 + 0.1 Ghz

Bandwidth : 500MHzPassband S21 : 2.5dBReturn Loss S11 : 15 dBStop Band S21: 20dB Impedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Type : Stepped ImpedanceOrder : 7F c : 3.0 + 0.1 GHzPass Band S 21 : 1.5dBReturn Loss S11 : 15 dBStop Band S21: 20dB


Order: 7Fc : 3.0 + 0.1 GHzPass Band S21 : 2dBReturn Loss S11 : 15 dBStop Band S21: 30dB Impedance : 50 OhmsConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

Fc : 2.9 + 0.9 GHz

Output Power : +5dBmPhase Noise : -130dBm @ 1MHzHarmonics : -20dBcTuning Voltage : 0.5-20VConnector : SMASubstrate : CeramicFinish : Gold Plated with selective MaskingCover : Scratch resistant

28. Standard Accessories

Scope of Experiments

50 Ohms Matched Termination SMA(M) - 4 Nos, Short termination SMA(M), Teflon based RG316 cables 4 nos SMA(M)-SMA(M), SMA(F)-SMA(F) RF Unit , Software- converter, AppCAD, E-Manual / Installation Video for ease of Learning

* Properties of Directional Coupler: Measurement of coupling factor, Directivity, return loss of a load, main line insertion loss, isolation, VSWR of ports.* Measurement of S11, S12, S21, S22 parameters of microstrip components* Properties of Branch Line Coupler: Measurement of coupling factor, return loss of a load, main line insertion loss, isolation, VSWR of ports.* Properties of Hybrid Ring Rat race Coupler: Measurement of Power division or Decoupling between Sum and Diff arms of a rat race coupler, Measurement of Insertion loss S21 & S41, Measurement of Return Loss/ impedance match at ports 1 & 4 - S11, S44, measurement of Isolation between ports 1 & 3 - S13, Measurement of Phase difference in output arms 2&4 as 180Deg.* To measure gain, isolation, VSWR of ports of mmic amplifier.* To measure Insertion loss, isolation and VSWR of port microwave SPST PIN diode switch.* To measure Insertion loss, isolation and VSWR of port microwave SPST PIN diode Modulator. Operation of PIN diode modulator. Study of square wave modulation of PIN modulator.* Measurement of power division and isolation characteristic of a microstrip 3 dB power divider.* To measure isolation, VSWR of ports of Radial stub.* To measure VSWR of ports of 50 ohms microstrip line, Matched load, open stub, Short Stub, mismatch.* Low pass filter characteristics insertion loss, pass band, port VSWR* Measurement of resonance characteristics of a microstrip ring resonator and determination of dielectric constant of the substrate.

Dimensions: 55x45x18 cmsweight: 5 Kg, Warranty: 1 yr.




MULTIPLE INPUT MULTIPLE OUTPUTMIMO DEVELOPMENT TEST BED LAB MIM04

Description:

The Amitec MIMO-LAB is a software programmable hardware transceiver which allows limitless telecommunication laboratory experiments to be performed on a single device. The entry barrier is lowered to include the under graduate students by providing a graphical programming environment. The burden on faculty is lowered by using courseware designed at IITD from simple FM to most complex MIMO. Lab technicians are eased by integrated hardware and software from same source for trouble free performance.

The system is ideally suited for applications requiring high RF performance and great bandwidth such as physical layer prototyping, dynamic spectrum access and cognitive radio, spectrum monitoring and even networked sensor deployment.

The Superspeed USB 3.0 interface at 5Gbps serves as the connection between the MIMO-LAB and the mobile workstation. This enables the user to realize 40 MS/s of real-time bandwidth in the receive and transmit directions, simultaneously (full duplex). FPGA is autoloading so hadrware is plug and play as a pen drive! No need to program the FPGA for most cases!

The systems offers MIMO capability with high bandwidth and dynamic range. 4 pcs of radios may be connected to realize a complete 2x2 or 3X1 MIMO configuration. External PPS and reference inputs can also be used to create larger multi-channel systems. ASIC houses complete RF and DAQ subsystems on a single board. Coupled with these benefits it hosts onboard RF Transceiver subsystems capable of tuning frequencies from 400MHz to 4GHz.

Features:

• 1X1, 1X2, 2X1, 2x2 MIMO and expandable to Massive MIMO 64X8• Suitable for 4G LTE Advanced protocol to 5G testing• Apply principles of diversity reception to increase bit rate while maintaining same transmitted power and bandwidth.• Study functionality of Precoding, Spatial multiplexing, Diversity coding• Works with Linux GnuRadio, Compatible to LabVIEW™, MATLAB Simulink™, C++ and Python• No recurring cost of software/licence, IP rights!• ASIC Architecture: 0.4-4 GHz combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain control, TX power control • +5dBm Transmit power & -120dBm Sensitivity Receiver• FPGA program transmit & receive for high performance• Differential Baseband Signals• Modulation Bandwidth Programmable upto 30 MHz• Supports both TDD &FDD Full Duplex upto 30MHz• Calibrated +1ppm TCXO• Dual 40 MS/s, 12-bit ADC & Dual 40 MS/s, 12-bit DAC• Up to 5GbpS/s USB 3.0 Data Streaming to Computer• MIMO Capability – 2X2, 2X1, 3X1 and (4X4(upgrade))• 200MHz ARM9 with 512KB embedded SRAM • Alterra Cyclone FPGA with single cycle access memory, 18X18 multipliers for dedicated DSP & programmable general logic elements

IITD1

Laptops not included

Hardware Technical Specifications

MIMO Capability 2X2, 2X1,1X2,3X1,1X3 and (4X4(upgradable)) Diversity Space, Polarisation, Time, Frequency, AngleFrequency synchronisation External, GPS 1PPSWall-mounted Option Should be supportedMTBF Greater than 20 yearsIngress Protection level IP40Weight Less than 1KgFrequency Band Up gradable to DC on lower side and 60 GHz on upper sideCompatibility Works with Linux GnuRadio, LabVIEW, MATLAB, Simulink Accessibility OSI layers for signal processingWireless transmission and reception over the airWireline transmission and reception through SMA cablesCapture the IQ Vectors at any part of signal chain. User can process the IQModulations supported Custom ModulationsADC/DAC IQ Sampling Rates Any proprietary sampling rate Antenna configuration SISO, Diversity, 2x2 MIMODiversity Support SFBC, STBC, STTC, Receiver Diversity, Transmitter DiversityReceiver Diversity Selection combining (SC), Maximal Ratio Combining (MRC), and Equal gain combing (EGC), Custom algorithmSupports MU-MIMO, Beamforming Transmit Frequency Range 0.4-4GHzReceive Frequency Range 0.4-4GHzMode Full Duplex/TDD/FDDArchitecture ASIC/FPGA/Zero IFBaseband Bandwidth <1-15MHzFrequency Resolution <3HzMaximum RF Output power +5dBmReceiver Sensitivity -120dBmTx/Rx IO Impedance 50 Ohms SMAPLL Phase Noise -125dBc/Hz at 1MHzSpurious Output -50dBcTx/Rx Gain Control Range >50dBTx/Rx Gain Control Step 1/3dBRx Noise Figure <5dBIQ Phase/Amplitude Error 3 degree/0.5dBPLL Settling time 20usADC/DAC Sample Rate upto 40 MS/sADC/DAC Resolution 12 bitsADC/DAC Wideband SFDR 60 dBcInput Amplitude 1Vp/p differentialOutput Amplitude 250mV p/p differentialSSB/LO Suppression >40 dBcFPGA Altera CycloneIntegrated Transceiver 3 GbpsLogic Elements 40,000M9K Memory Blocks >400Embedded Memory >2000 Kbits18bit X18bit Multipliers >100PLL 4Maximum User I/Os >500Maximum Channels >200 DifferentialCurrent Consumption <500mA, USB driven

OS Linux UbuntuPorts 3X USB 3.0, GB EthernetCable High Speed USB 3.0 Serial Cable, RG316 SMA-SMA X8, Antennas Directional LPDA 0.4-6 GHz X4, Omni Directional Dipole 0.4-6 GHz X4,Upgrade 3 years auto upgrade of new experiments/training videos/ operation manuals/ firmware /support over internet Shipping List Deliverable SDR TRX X4 pcs, Antennas X8 SMA-SMA Cables X8 pcs Power Supply Adapter X4 USB3.0 Cable X4, Attenuator 20dBX4pcsSoftware GUI features Boolean, Byte Operators, Channelizers, Channel Models, Coding, Control Port, Debug Tools Deprecated, Equalizers, Error Coding, File Operators, Filters, Fourier Analysis, GUI Widgets, Impairment Models, Instrumentation, Level Controllers, Math Operators, Measurement Tools, Message Tools, Misc, Modulators, Networking Tools, OFDM, Packet Operators, Peak Detectors, Resamplers, Sinks, Sources, Stream Operators, Stream Tag Tools, Symbol Coding, Synchronizers, Trellis Coding, Type Converters, Variables, Waveform Generators,

Scope of Experimentation* Introduction to MIMO-LAB Hardware and Software environment* On air transmission & reception using Digital Modulation & Demodulation techniques like ASK, FSK, BPSK, DBPSK, MSK, GMSK, DQPSK, QPSK, OQPSK, pi/4QPSK, 8PSK,16QAM, 64QAM, 256QAM, CPFSK, GFSK, and other variants, * Spread spectrum techniques like CSS, DSSS, FHSS, THSS* Multiplexing techniques like TDM, FDM/WDM,SDM, Polarization, Spatial, Packet Switching, MC-SS, OFDM* Analog Channel Models like Noise (Uniform, Linear, Laplacian, Gaussian, Phase noise), Interference (Cross talk, Co-channel, Inter symbol), Distortion (Inter modulation), Frequency response (Attenuation & phase shift), Group delay, Propagation Doppler shift, Fading modeling slow, fast, selective/dispersive, Multipath, Rayleigh, Rician), *Channel Coding & decoding-Convolutional, Viterbi,Trellis,* Channel performance measurements (spectral bandwidth, Symbol Rate, Bit Rate, Channel Capacity, Channel Utilization, Signal to noise ratio, Bit Error Rate BER, Latency, Jitter, Eye Diagram, Constellation diagram, Oscilloscope, Spectrum Analyser, Waterfall display* Antenna configuration SISO, Diversity, 2x2 MIMO* Diversity Support SFBC, STBC, STTC, Receiver Diversity, Transmitter Diversity, * Receiver Diversity Selection combining (SC), Maximal Ratio Combining (MRC), and Equal gain combing (EGC), Custom algorithm

Mfd by: Amitec Electronics Ltd.Regd. Off: 504, Nilgiri, Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.sdr-lab.com, www.amitec.co+91-120-4371276, +91-9971-663434, 98101-93153, 98118-39949,

2

Scope of Experimentation Contd.

* Line Coding & Decoding Digital Baseband* Filters-IIR, FIR, Pulse Shaping-RRC root raised cosine, High pass, Low pass, Bandpass, Band stop, FFT, frequency translating filter,* Equalizer adaptive-CMA , Kurtotic, LMS DD* Synchronizers-Costas Loop, Clock Recovery, Frequency locked loop, phase locked loop, correlate and sync, carrier acquisition,* Modeling mathematical equations * Networking- TCP, UDP, Socket, Broadcasting,* Encoding decoding for data, voice & video-PSK31, MPEG, CVSD and more* On air link for Voice, Data, Video,

MIMO Configuration Typical*:

Prepare Signal for Transmission:#1 Initialize Parameters(Symbol Rate, Symbols per packet, Tx Oversample Factor, RX Oversample Factor, Modulation Scheme, Filter length symbols, Filter Parameters, Training Sequence, Frequency Offset Correction, Channel length Estimate) #2 Generate Bits for Message#3 Map Bits to Symbols#4 Apply 2X2 Alamouti Block Code( C2= [c1 c2] ) [-c2* c1*]#5 Append Training Sequence(Prepend each transmit packet with zeros to cover all training sequences, then insert training sequences at offset appropriate to transmit antenna)#6 Upsample & Apply Pulse Shaping Filter(Symbol stream+ pulse shaping filter coefficients + samples per symbol+ symbol rate = transmit packets)TX & RX with Amitec Hardware#1 Initialize Hardware(Tx & Rx IP address, IQ Sampling Rate samples per second, Carrier Frequency, Start Trigger in fractional seconds ,Set Time base clock source) #2 Transmit/ Receive(Asynchronous Multichannel Transceivers)#3 Close HW References#4 Display Time Domain Received Signal(Complex input with array table output)

Process Received Signal#1 Find packet in acquisition#2 Trim Non packets#3 Apply Matching Filter and Downsample#4 Symbol Synchronization#5 Frame Sync#6 Frequency Offset Correction#7 Calculate Channel Estimate#8 2X2 Alamouti Receiver#9 Plot constellations of 2 received streams and the combined

Student projects Research And more.....

MIMO BER

Various MIMO Configuration

SDR Architecture

IITD

MIMO Implementation

3


IITD



Narrow Band FM signal captured on air 3G spectrum on Air

4Mfd by: Amitec Electronics Ltd.Regd. Off: 504, Nilgiri, 9 Barakhamba Road, New Delhi-110001, India, Works: 4/32, Site-4, Industrial Estate Sahibabad, NCR-201010, India, [email protected], www.amitec.co+91-11-41505510, +91-120-4371276


Features:* 10 MHz to 26.5GHz measurement range with USB.* Digital Display on 320X240 Pixels Touchscreen TFT with graph.* Wide range from +20dBm(100mW) to -30dBm(1uW)* 0.1dB resolution* Measurement in dBm & 22 other units* Measure Gunn and Klystron Source outputs without PIN modulator. It can effectively replace the SWR meter for most experiments and allow measurements with unprecedented accuracy. Amitec MPM26 Technical Specifications

POWER METERFrequency range : 10MHz to 26.5 GHz Display : 320X240 pixel, 3” TFTControls : Touch Screen basedPower range : -30dBm to +20dBm Measurement : dBm & 22 other unitsResolution : 0.1dBSampling : peak, average, rmsRelative Offset : +20.0 to -30.0dBm for relative measurement Level Indicator : GraphRecorder output : For CRO interfacePC interface : USB portPOWER SENSORRF Connector : SMA into 50OhmsFrequency range : 10MHz to 26.5GHzMaximum input : +20dBmReturn Loss : 20dB upto 12.4GHz : 15dB upto 26.5GHz Compensation : Temperature compensated thermistorCable : Sensor/meter cable 3mAdapter : N-SMA, X-band waveguide to coax adapterE-Manual: Installation Video for ease of LearningList of Experiments1.To learn different ways of measuring power. 2.To evaluate the accuracy of the power measurements. 3.To plot the power output of Gunn/Klystron Oscillator with V4.To plot the power output of a Gunn/Klystron Oscillator with frequency.5.Study of square law modulation and square law characteristics of a crystal detector.6.To measure PIN modulator insertion loss & mod. depth.7To measure the accuracy of SWR meter reading. 8To calculate the relationship between Q and bandwidth of resonance cavity. 9.To measure the insertion loss of the waveguide.10.To measure the insertion loss in the main line of a directional coupler.11.To measure the coupling factor of a directional coupler.12.To measure the isolation & directivity of a directional coupler.13.To measure the return loss of a unknown load.14.To measure the decoupling between H and E arms of magic Tee.15.To measure the insertion loss of the hybrid Tee.16To measure the return loss of H arm in a magic Tee.17.To measure and plot the attenuation characteristics of variable attenuator.18.To measure the attenuation of a fixed attenuator. 19To measure the input SWR of attenuator.20.To measure the gain of a pyramidal horn.21.To plot the E and H Plane polar pattern of a antenna and compute the beamwidth. 22.To measure the coupling coefficient of a waveguide E & H Plane Tee.23.To measure the isolation of a E & H plane Tee.24.To measure the input VSWR of a E & H plane Tee.25.To study the operation of ferrite circulator and measure its insertion loss. 26.To measure isolation of a ferrite circulator. 27.To measure the cross coupling of a circulator.28.To study the variation of characteristics of ferrite circulator with frequency.

MICROWAVE POWER METER MPM26



MICROWAVE TRAINING LAB MWL10



Features *Touch screen TFT 320 X 240 Pixels 0.01-26.5GHz Power meter. *Inside outside precious metal plated with diamond polish. *Corrosion/Oxidation free welded construction for long life. *100% Tested and calibrated on HP network analyser *Gunn Oscillator, detector and other components *Directional Coupler and Slotted line for VSWR/ Return Loss. Technical Specifications:

1. 10MHz - 26.5 GHz Power Meter MPM26 POWER METER& SENSOR Frequency range : 10MHz to 26.5 GHz Display : 320X240 pixel, 3” TFT Controls : Touch Screen based Power range : -30dBm to +20dBm Measurement : dBm & 22 other units Resolution : 0.1dB Sampling : peak, average, rms Relative Offset : +20.0 to -30.0dBm for relative measurement Level Indicator : Graph Recorder output : For Oscilloscope interface PC interface : USB port

Scope of Experimentation 1. Gunn oscillator i) Measurement of current vs. voltage characteristic ii) Measurement of Gunn oscillator power vs supply voltage. iii) Measurement of Gunn oscillator frequency vs supply voltage. 2. Modulator and crystal detector i) Operation of PIN diode modulator & crystal detector. ii) Study of square wave modulation of PIN modulator. iii) Measurement of square law behavior of detector. 3. Propagation modes, wavelength and phase velocity i) Measurement of frequency of source. ii) Measurement of free space & guide wavelength 4. Q and bandwidth of resonance cavity of frequency meter i) Measurement of Q using power measurement techniques. ii) Measurement of Q using Tuned amplifier & Oscilloscope. 5. Power Measurements i) Direct measurement of power ii) Power measurement using directional coupler iii) Measurement of Conjugate and Zo power. iv) Measurement of modulated signals v) Measure the tracking of dB scale with attenuator vi) Study mismatch loss and maximum power transfer 6. VSWR and Reflection Coefficient by Standing wave and Double Minimum Method i) Measurement of low, medium & high SWR using slotted line ii) Measurement of High SWR using attenuator 6. Impedance Measurement i) Measurement of unknown Impedance of load ii) To match an unknown impedance. 7. Waveguide Hybrid (Magic) Tee i) Measurement of Power division or Decoupling between H-arm and E- arm of a Magic Tee. ii) Measurement of Insertion loss of a Magic Tee. iii) Measurement of Return Loss of H arm of a Tee vi) Measurement of VSWR of ports of Hybrid Tee 8. Properties of Directional Coupler i) Measurement of coupling factor. ii) Measurement of Directivity. iii) Measurement of return loss of a load. iv) Main line insertion loss, VSWR of ports. 9. Fixed and Variable Attenuator i) Measurement of attenuation using the Power Ratio and RF substitution method ii) Measurement of low values of attenuation. iii) Measurement of S parameters of variable attenuator. 10. To study & calibrate a phase shifter. 11. To study and measure S parameters of waveguide to coax transition 12. To measure insertion loss/isolation/S parameters of isolators & circulator. 13. To measure the ANTENNA PARAMETERS (directivity, gain, beam width (Half Power/10dB), front to back ratio, plane of polarization, cross polarization discrimination, side lobe level and its angular position from polar plot, VSWR/return loss) of given antenna.




2. Micrometer tunable Broadband Gunn Oscillator 7. Precision Slotted Line with Broadband Detector Probe

Frequency: 8.2-9.7 GHz Typ Power O/P: 10 mW typical S11: >10dB Calibration chart: steps of 100 MHz Body: Solid wire cut Aluminum for thermal stability and long life Tuning: Precision Micrometer

S11: >10dB S12: <1dB Resolution: 0.05mm using vernier Sensitivity: 0.1mV/uW

3. Gunn Power Supply GVM10 8. Broadband Multihole Waveguide Directional Coupler

Gunn Bias Voltage & Current: On Touchscreen TFT Display PIN Mod. Frequency & Voltage: On Touchscreen TFT Display

S41 Coupling: 10dB Typical S34 Directivity > 15dB S21 Insertion Loss: <1.5dB Bandwidth: 8.2 -12.4 GHz

4. Broadband PIN Diode Modulator 9. Slide Screw Tuner with Precision Micrometer

S11: >10dB Typical S12 off: 10dB S12 on: <2dB Bandwidth: 8.2 -12.4 GHz Diode: Microwave SMD package

Resolution X Y: 0.05 mm Drive: Vernier on teflon bearing

5. Broadband Waveguide Detector 10. Calibrated Precision Variable Attenuator

S11: 10dB Typical Sensitivity: 0.5mV/uW Bandwidth: 9.3 -11.3 GHz

S11: >15dB S12: 1 to 20dB variable Resolution: 1dB Accuracy: +1.5dB Calibration Chart: Attenuation v/s micrometer in steps of 1 dB

6. Calibrated Frequency Meter 11. 12. Broadband Matched Termination - 2 Nos.

S11: >10dB S12: >3dB at resonance Q factor: 1000 Accuracy: 1% Calibration Chart: Frequency v/s micrometer in steps of 100 MHz

S11: >15dB Bandwidth: 8.2 -12.4 GHz




13. Solid Dielectric cell 19. Precision Movable Short

Type: Waveguide cavity Dielectric: Bakelite, Teflon, Acrylic, Nylon, Polyproylene Length: 60 degree empty

S11: >30dB Drive: Precision Micrometer Plunger: Solid Short

14. Liquid Dielectric cell 20. 21. Broadband Waveguide to Coax adapter - 2 Nos

Type: Waveguide cavity Window: Kapton Filling: Syringe Cavity Volume: 1.5cc Length: 60 degree empty

S11: 10dB S12: 1.5dB Frequency: 8.2-12.4 GHz Connector: SMA

15. Broadband Isolator 22. Waveguide Stands - 7 Nos

S11: >15dB S12: >15dB S21: <1.5dB Bandwidth: 8.2 - 12.4 GHz

Mount: E & H plane WR90

16. 17. Broadband Pyramidal Horn Antenna -2Nos 23. Broadband Circulator

Gain: 16dB S11: 15dB Beamwidth: 30 degree E & H

S11: >15dB S12: >15dB S21: <1.5dB Bandwidth: 8.2 - 12.4 GHz

18. Calibrated Phase Shifter 24. Rectangular waveguide

S11: >10dB S12: >10dB Calibration: 10.3 GHz Calibration Chart: Phase Vs. Micrometer reading

S11: >15dB S12: <1dB Bandwidth: 8.2 GHz -12.4 GHz Length: 120mm typical




25. Hybrid / Magic Tee 29. VSWR meter VSM10

S11: >10dB Typical Isolation: 15dB H & E arms Bandwidth: 9.8-10.8GHz

Frequency: 1 KHz center Display: Analog meter 85mm Attenuator: 65 dB Scale: Normal /Expand

26. Series E plane Tee 30. Accessories

S11, S22, S33: >15dB S12, S13: 3.5dB Phase: 180 degree Bandwidth: 8.2-12.4 GHz

BNC- BNC Cable - 3 pcs, M4X12 Screw - 10 pcs, M4X20 screw - 50 pcs, E manual Video + Software CD for ease of learning, SMA-SMA Coaxial RG316 Teflon low loss cable

27. Shunt H Plane Tee 31. Fixed Short

S11, S22, S33: >15dB S12, S13: 3.5dB Phase: 0 degree Bandwidth: 8.2-12.4 GHz

S11: >30dB Flange: UG39/U

28. Broadband Fixed attenuator 32. Manual Antenna Rotator

S12: 6dB S11: 15dB

Mount: E & H plane WR90

Phase Array Radar Training System PAT04 Features:* PLL transmitter and receiver 40MHz-4 GHz.* 1 KHz to 500 Mhz step size* RF Power measurement in 0.1 dB resolution* 60 dB dynamic range.* Directional Coupler for VSWR/ Return Loss.* Stepper motor antenna rotator.* 1 degree resolution stepper motor * USB interface with polar/cartesian plotting software* Microstrip Phase array antenna, Log Periodic antenna* All antenna gain, return loss and pattern plot * 1000 Frequency and level storage in receiver* + 35 degree beam steering* 2X2 array of patch antennas with individual phase addressing* Microwave Absorber panels providedDescription: Phased array antenna training system has been designed to unravel the mysterious subject of antenna beam steering in lab environment. Beam steering has been an abstract concept with theoretical formulation and computer simulation untill now. Such antennas are extensively used in high power radars, which could not presented as a model in lab for student experiments. The high power of these devices would not be safe for indoor use and exorbitant price would exclude any live practical. We offer a comprehensive system with PLL signal generator for energising the antenna and PLL receiver for testing the beam patterns. Phased array antenna is mounted on Stepper motor controlled rotator for polar plot measurement. Antenna phase controller is provided to steer the beam with any user algorithm.

Amitec PAT04 Technical Specifications:Display : 320X240 pixel TFT Touch ScreenFrequency range : 0.04-4 GHz PLL synthesizedStep size : 1KHz to 1GHzAccuracy : 1ppmRF Level : +10dBm typicalMeasurements : RF level in dBm & 22 other unitsResolution : 0.1dB with a dynamic range of 60 dBUSB interface : To PC for antenna plotting softwareConnector : Gold plated SMAMotor Rotation : 0-359 degrees in 1 degreeMotor Mode : Fully programmable start/end position, Step Size, Forward step/dwell/stop time, No of cycles Auto mode : Automatic rotation with receiver Locations : 10,000 location Frequency and Level storage

PHASE ARRAY RADAR TRAINING LAB PAT04

Phase array AntennaGain : 10 dBi Frequency : 4000MHzBeamwidth : Horizontal 40 degree typicalInput Impedance : 50 OhmsConnector : SMAArray Element : Rectangular Patch Antenna, Dipole antenna, Log Periodic Dipole ArrayPolarization : Linear X or Y rotatableArray : 2X2 (X and Y)Element Spacing : Fixed Lambda/2Amplitude Taper : Uniform amplitude X & YPhase Taper : Adjustable BroadsidePhase Resolution : 20degreePhase shift total : >360 degreeBeam Scan : >+35 degrees (X and Y)

Phase Array Antenna Beam ControllerDisplay : TFT LCDDisplay Mode : Beam Number, Position,Control : Touch ScreenMenu : Reset to broadside,Specify Beam Scan, Incremental shiftScan Mode : Manual, continuous, triggeredBeam Sequence : Incremental, Random, EvenScan Speed : SelectableResolution : 4bit

PHASE ARRAY RADAR TRAINING LAB PAT04

Antennas : typical gain & VSWR<1.51) MIC LPDA 4dBi 0.9-6GHz2) MIC LPDA 4dBi 0.9-6GHz Software: USB interface with polar plotting with log, linear cartesian and polar plots, Vi, Vr & Return loss plots, Multiple pattern overlay, Double cursor, Zoom, Colour editing, 1000 location editor, Absolute/Relative, 3dB/10dB beam-width, Gain, Front to back, Side lobe level and position, Plot rotate, File- edit, save, get.

Directional Coupler: Directional Coupler is provided with 4 GHz frequency response and 15 dB directivity for antenna forward & reverse power & VSWR measurements.

Accessories1) Transmitter antenna mounting stand.2) Stepper motor controlled mounting stand for rotation of receiving antenna. 3) All necessary connectors & Teflon cables.4) Experimental Manual 5) Software CD 6) USB-USB Lead 7) Microwave Absorber Panels E-Manual: Installation Video for ease of Learning

Areas of experimentation and scope of study * Vertical, Horizontal polarized antennas.* Resonant and non-resonant antenna, VSWR* Antenna parameters:* Radiation pattern E & H Plane - Polar & Cartesian Plots* Directive gain, beam width (Half Power/10dB), front to back ratio, plane of polarization, side lobe level & angle. * Antenna resonance, VSWR and bandwidth using directional coupler * Plus lot more.




RADAR CROSS SECTION TRAINING LAB- RCS12



Features:

➢ For testing of radar cross section of real life scaled targets in spherical coordinates.

➢ Time domain with Gating distance & trace math for high accuracy.

➢ Use of X band allows smaller wavelength for measurement, allowing smaller features to be tested for high correlation to real targets.

➢ Low radiated power combined with very high sensitivity allows large range of measurements.

➢ Direct measurement in dB with 0.1dB resolution with accurate log processing with temperature.

➢ Microwave absorber panels provided, reduce the background clutter and reflection, for detection of targets with very low reflectivity and efficient background subtraction with software.

➢ Self-Calibration using accurate reference targets.

➢ Exponential absorbers for normal/ grazing angles.

➢ Accurate table top measurement indoors.

➢ The system includes a stepper motor controlled very low RCS target support.

➢ Use of smaller antennas allow compact range with far field <1m.


Radar Transceiver

Radar Frequency 1GHz-14GHz

Measurement S11

Processing IFFT for Time domain & Gating distance

Trace Math +,-, *,/ of display & memory

Channel/Trace 4/4

Data Display format Return Loss, Phase, Smith chart, magnitude to distance

Resolution 10Hz

Configuration Monostatic

Far field >1m (Indoor operation)

Radiated Power 0 dBm EIRP typical

Sensitivity -100dBm

Capture threshold -40dBsm

Range >70 dBsm

Measurement dBm, dBr, dBsm

Resolution 0.1dBsm

Measurement Speed 200us

Demodulation Logarithmic

IF Bandwidth 100Hz

Antenna Dual Ridge 1-18GHz X Band Pyramidal Horn

Software Windows 7/8/10 for RCS measurement and polar / cartesian plotting, stepper motor control, Radar GUI




1. Low RCS Target Rotator 6. Reference Calibration Target Cylinder

Rotator RCS: <40dBsm Loading: 2Kg Azimuth: 360 degree Angular resolution:1 degree Target Size: < 500mm Rotator RCS: <40dBsm

Reference Calibration Target Cylinder

2. Dual ridge Horn 7. Low RCS Metallized Helicopter Scale Model

Frequency: 1 -18 GHz Polarization: Horizontal & Vertical

RCS: -11dBsm Type: Fighter Helicopter Surface: Metallized

3. Reference Calibration Target: Metallic Sphere 8. Low RCS Metallized Fighter Aircraft Scale Model

RCS: -17dBsm Surface: Metallized Surface Error : <0.1 Lambda

RCS: -20dBsm Type: Fighter Aircraft Surface: Metallized

4. Flat Metal Plate 9. Low RCS Metallized Fighter Aircraft Scale Model

RCS: +16dBsm/-4dBsm Surface: Metallized/Absorber

RCS: -20dBsm Type: Fighter Aircraft Surface: Metallized

5. Corner Reflector 10. Threshold Target

RCS: +11dBsm Surface: Metallized

RCS: -41dBsm Type: 3 Spheres Surface: Metallized Size : 1 Lambda




11. Microwave Absorber Sheet 14. Aircraft

Size: 60cmX60cm Equivalent RCS: -40dBsm @ K Band Absorber: EM Lossy PU Foam Exponential Cones Reflection: -40dB @K Band Fire retardancy: As Per NRL USA-8093 Standard complying Tests No.: 1,2 and 3 with zero halogen means

RCS: -10dBsm Type: Aircraft Surface: Metallized

12. X band Pyramidal Horn 15. Tank

Pyramidal Horn Gain: 16 dB Frequency: 8.2-12.4 GHz Polarization: Horizontal & Vertical Waveguide to coax adapter: X band

RCS: -10dBsm Type: Military tank Surface: Metallized

13. Polarizer 16. Ship

Adjustable Tripod: with Azimuth and Elevation

RCS: 0dBsm Type: Commercial ship Surface: Metallized


* RCS Concept, Radar Range Equation, Use of dB, Types of RCS Measurement, The Far field requirement, Measurement, The Type of Pattern Cut, RCS and Radar Frequency Bands, The RCS Test Range, Outdoor Ranges, Indoor Ranges, Data Collection, Reduction, and presentation. *RCS Reduction: The four basic methods of RCSR *RCS Measurements Classical Targets and Scattering Standards Far Field Outdoor RCS Ranges, Pylons for Mounting and Rotating Targets, Compact Ranges for Indoor Measurement RCS Measurement Systems, Imaging of RCS Data, Search Radar Range Equation. *Radar Cross Section Measurements of Magnetic and Dielectric Microwave Absorbing Thin Sheets. *Experimental Operation: Calibration, Operation Procedure, Sources of Error *Experiment #1 Radar Cross of Sphere. *Experiment #2 Radar Cross of Cylinder. *Experiment #3 Radar Cross of Flat Plate. *Experiment #4 Radar Cross of Trihedral reflector. *Experiment #5 Radar Cross of Threshold target. *Experiment #6 RCS of Type I Stealth Aircraft. *Experiment #7 RCS of Type 2 Stealth Aircraft. *Experiment #8 RCS of Apache Stealth Helicopter.

SATELLITE COMMUNICATION SCT04



430X302mm Corporate Brochure Printo

*Laptops Not Included

Features • Learn the next generation of Satellite Communication

technology with modular approach and complete flexibility in design and operation

• Based on latest generation of Software Defined Radio technology with complete control over frequency, modulation schemes and system design

• Emulate the functionality and characteristics of Earth Station Transmitter, Satellite Repeater and Earth Station Receiver

• Implement complete signal processing chain for transmission and reception of any kind of data such as voice, video, image, file, text messages or any other custom data

• Complete control over telemetry link

• Design any analog or digital modulation scheme for implementing data and telemetry links

• Use modern signal processing algorithms and observe the effect in real-time

• Modular system allows use of channel coding and error correction coding schemes

• Flexibility in inserting various real-world parameters such as noise, delay and effect of channel

• Implement complete end-to-end system using various Digital Video Broadcasting technologies and mimic a real satellite system

• Emulate GPS transmission and Reception by transmitting custom GPS data and decoding at receiver

• Control Satellite and its various parameters

• Test remote fault insertion, diagnostics and measure parameters such as Packet Error Rate (PER)

• Study link characteristics and Performance

• Study Orbital Mechanics using license-free tools

Introduction The Amitec Satellite Communication Training Lab SCT04 is a highly configurable and adaptable training and research and development system optimized to implement modern communication technologies. The complete system consists of Earth Station Transmitting Emulator, Earth Station Receiving Emulator and Satellite Emulator. All three sub-systems consist of Software Programmable Hardware transceiver which allows limitless satellite communication laboratory experiments to be performed on a single setup. Implement existing satellite communication standards using real-world modulation schemes and parameters. Software programmability of the system allows it to be upgraded, making it obsolesce-proof. Study and implement a wide range of communication concepts such as various modulation schemes, including NBFM, WBFM, DBPSK, DQPSK, QAM and custom modulation, packetisation, whitening, scrambling, differential encoding, error correction coding schemes and channel models. Study real-time performance and measurement of parameters such as link budget, packet error rate and other concepts. Learn the use and implementation of telemetry signals. Observe and measure the effect of different antennas and study the characteristics. The entry barrier is lowered to include the under graduate students by providing a graphical programming environment. The burden on faculty is lowered by using courseware designed at Amitec from simple FM to most complex Modulation techniques. The systems offer high bandwidth and dynamic range. Study Orbital mechanics with a license-free tool. Configure various orbits, launch sites and parameters to implement a real-world system and adapt the system in real-time.





Earth Station Transmitter Data Transmit/Uplink Frequency Range 300 MHz to 4 GHz

Telemetry Transmit/Uplink Frequency Range 300 MHz to 4 GHz

Telemetry Receive/Downlink Frequency Range 300 MHz to 4 GHz

Frequency Band Upgradable Upgradable to DC on lower Side and 60 GHz on upper side Wireless transmission and reception Over the air transmission through SMA Signal Capture The IQ Vectors at any part of signal chain. User can process the IQ data Data Modulations supported Any, Custom Modulations possible Transmit Baseband Bandwidth 30 MHz

RF Output Power +5 dBm Max., customizable

ADC/DAC IQ Sampling Rates Any sampling rate, Max. 40 MSPS TX/RX SMA Impedance 50 Ohm


Data Type Voice, Video, Chat, File

Telemetry Modulations supported Any, Custom Modulations possible Telemetry Link Full Duplex

Data Receiver for testing Yes

Data Receiver Frequency Range 300 MHz to 4 GHz

Satellite Emulator Data Receiver/Uplink Frequency Range 300 MHz to 4 GHz

Data Transmit/Downlink Frequency Range 300 MHz to 4 GHz

Telemetry Transmit/Downlink Frequency Range 300 MHz to 4 GHz

Telemetry Receive/Uplink Frequency Range 300 MHz to 4 GHz

Frequency Band Upgradable Upgradable to DC on lower Side and 60 GHz on upper side Wireless transmission and reception Over the air transmission through SMA Signal Capture The IQ Vectors at any part of signal chain. User can process the IQ data Data Modulations supported Any, Custom Modulations possible Transmit Baseband Bandwidth 30 MHz





Telemetry Modulations supported Any, Custom Modulations possible Telemetry Link Full Duplex

Data Receiver for testing Yes

Earth Station Receiver Data Receiver/Downlink Frequency Range 300 MHz to 4 GHz

Data Transmit Frequency Range 300 MHz to 4 GHz

Frequency Band Upgradable Upgradable to DC on lower Side and 60 GHz on upper side Wireless transmission and reception Over the air reception through SMA Signal Capture The IQ Vectors at any part of signal chain. User can process the IQ data Data Modulations supported Any, Custom Modulations possible Transmit Baseband Bandwidth 30 MHz





Antennas

Directional LPDA 0.4-6 GHz X3, Omni Directional Dipole 0.4-6 GHz X3, High-gain Dish X2 Circularly-polarized Helix X2

Shipping List Deliverable Earth Station Transmitter, Satellite Emulator, Earth Station Receiver, Antennas X10, SMA-SMA Cables X 6 pcs, Attenuator 20dB X 3pcs

Orbital Mechanics Software License-free operation





• Implement Satellite Earth Station with complete control over signal processing chain and telemetry link

• Implementing On-air Transmission and Reception using Digital Modulation and Demodulation techniques like NBFM, WBFM ASK, FSK, BPSK, DBPSK, MSK, GMSK, DQPSK, QPSK, OQPSK, pi/4QPSK, 8PSK,16QAM, 64QAM, 256QAM, CPFSK, GFSK, and other variants,

• Spread spectrum techniques like CSS, DSSS, FHSS, THSS

• Study the performance of satellite communication link in presence of: Analog Channel Models like Noise (Uniform, Linear, Laplacian, Gaussian, Phase noise), Interference (Cross talk, Co-channel, Inter symbol), Distortion (Inter modulation), Frequency response (Attenuation & phase shift), Group delay, Propagation Doppler shift, Fading modeling slow, fast, selective/dispersive, Multipath, Rayleigh, Rician),

• Implement Channel Coding & Decoding such as-Convolutional, Viterbi, Trellis

• Channel performance measurements such as: Spectral bandwidth, Symbol Rate, Bit Rate, Channel Capacity, Channel Utilization Signal to Noise ratio, Bit Error Rate BER, Latency, Jitter

• Visualize the data using Constellation diagram, Oscilloscope, Spectrum Analyzer, Waterfall display

• Emulate Satellite with complete uplink and downlink characteristics. Implement complete signal processing chain and telemetry link

• Implement Satellite Receiver with custom algorithms

• Transmit telemetry data and control the satellite from earth station

• Receive various types of data from Earth station including Voice, Video, Chat and File

• Study the block level implementation of commercial Digital Video Broadcasting(DVB) system. Implement end-to-end video transmission link over DVB

• Simulate GPS satellites by generating and transmitting custom GPS data and receive and decode the data at the earth station

GPS Trajectory Simulation

DVB- Webcam Capture

DVB- Time Overlay over Video

DVB-Picture in picture compositing

Constellation Diagram

Waterfall Display




List of Experiments 1. Design and Implement a complete real-time

SATCOM link using Analog Modulation schemes such as NBFM and WBFM

2. Design and Implement a complete real-time SATCOM link using Digital Modulation schemes such as DBPSK, DQPSK, D8PSK, BPSK, QPSK, 8PSK

3. Design and implement an Audio transmission and reception SATCOM system using various codes such as g721 codec and Frequency Modulation in real-time over a SATCOM link

4. Video transmission and reception using various modulation schemes with complete encoding and decoding in real-time over a SATCOM link

5. Design and implement a complete RF system using Digital Video Broadcasting(DVB) for audio and video transmission and reception over a SATCOM link

6. Design and implement a system to practically demonstrate and understand the concept of frequency offset correction, matched filtering and timing synchronization and phase offset correction modern communication system over a SATCOM

7. Design and implement a complete system to transmit and receive a Pseudo Random Sequence over a SATCOM link

8. Design and implement a complete system to transmit and receive data via TCP/IP over a SATCOM using different modulation schemes

9. Design and implement a complete system to understand and demonstrate the concept of Equalizers and Forward Error Correction(FEC) in a communication system

10. Design and Implement a complete real-time SATCOM link in the presence of different channel conditions

11. Design and implement a real-time system for Packet Error Measurement(PER) Measurement over a SATCOM link

12. Design and implement a real-time system using Spread Spectrum over a SATCOM link

13. Design and implement a real-time system for measurement of Signal to Noise Ratio (SNR) over a SATCOM link.

And Many More….

Dish and Helical Antenna

GPS Sky Plot

Circularly Polarized Patch Array

Waterfall Display

Orbital Mechanics Simulation

COGNITIVE WIRELESS COMMUNICATION SOFTWARE DEFINED RADIO SDR-LAB SDR04



+91-11-41505510, +91-120-4371276

Laptops not included Features: • Courseware designed at Indian Institute of Technology Delhi * Learn next generation communication & convergence

technologies (Software Defined Radio, Cognitive Radio including white spaces, Cooperative Communication, Communication over Cellular Network, Femto Cell, Wireless Network, Mobile

Adhoc Network, Research in 4G/5G) • Works with Linux GnuRadio, Compatible to LabVIEW™, MATLAB Simulink™ but does not need one!

• No recurring cost of software. Ever ! • ASIC Architecture: 0.4-4 GHz combines LNA, PA driver, RX/TX Mixers, RX/TX Filters, Synthesizers, RX Gain

control, TX power control – 2 Radios • +5dBm Transmit power & -120dBm Sensitivity Receiver • FPGA program transmit & receive for high performance

• Differential Baseband Signals • Modulation Bandwidth Programmable upto 30 MHz • Supports both TDD &FDD Full Duplex upto 30MHz

• Calibrated +0.04 ppm TCXO (Almost no need for GPSDO!) • Dual 40 MS/s, 12-bit ADC & Dual 40 MS/s, 12-bit DAC • Up to 5GbpS/s USB 3.0 Data Streaming to Computer

• MIMO Capability – 2X2 and 4X4 • 200MHz ARM9 with 512KB embedded SRAM • Alterra Cyclone FPGA with single cycle access memory,

18X18 multipliers for dedicated DSP & programmable general logic elements • Works as spectrum analyzer, vector signal generator & vector

signal analyzer • Covers white spaces, broadcast television, public safety, land-mobile communications, low-power unlicensed devices,

wireless sensor networks, cell phones, amateur radio bands. • Future ready from simple FM to WCDMA/HSPA, 4G-LTE standard to whatever future may hold

• Hundreds of experiments and growing.....

Description:

1. The Amitec SDR-LAB is a software programmable hardware transceiver which allows limitless telecommunication

laboratory experiments to be performed on a single device. The entry barrier is lowered to include the under graduate students by providing a graphical programming environment.

The burden on faculty is lowered by using courseware designed at IITD from simple FM to most complex MIMO. Lab technicians are eased by integrated hardware and software

from same source for trouble free performance. 2. The system is ideally suited for applications requiring high RF

performance and great bandwidth such as physical layer

prototyping, dynamic spectrum access and cognitive radio, spectrum monitoring and even networked sensor deployment.

3. The Superspeed USB 3.0 interface at 5Gbps serves as the

connection between the SDR-LAB and the mobile workstation. This enables the user to realize 40 MS/s of real-time bandwidth in the receive and transmit directions,

simultaneously (full duplex). FPGA is autoloading so hadrware is plug and play as a pen drive! No need to program the FPGA for most cases!

4. The systems offers MIMO capability with high bandwidth and dynamic range. Two units may be connected to realize a complete 2x2 MIMO configuration. External PPS and

reference inputs can also be used to create larger multi-channel systems.

5. ASIC houses complete RF and DAQ subsystems on a single

board. Coupled with these benefits it hosts onboard RF Transceiver subsystems capable of tuning frequencies from 400MHz to 4GHz.




+91-11-41505510, +91-120-4371276

Hardware Technical Specifications SDR: Transmit Frequency Range 0.4-4GHz Receive Frequency Range 0.4-4GHz Mode Full Duplex/TDD/FDD Architecture ASIC/FPGA/Zero IF Baseband Bandwidth <1-15MHz Frequency Resolution <3Hz Maximum RF Output power +5dBm Receiver Sensitivity -120dBm Tx Output Impedance 50 Ohms SMA PLL Phase Noise -125dBc/Hz at 1MHz Spurious Output -50dBc Transmit Gain Control Range >50dB Transmit Gain Control Step 1dB Rx Input Impedance 50 Ohms SMA Rx Noise Figure <5dB Rx Gain Control Range >50dB Rx Gain Control Step 3dB IQ Phase Error 3 degree IQ Amplitude Error 0.5dB PLL Settling time 20us ADC Sample Rate upto 40 MS/s ADC Resolution 12 bits ADC Wideband SFDR 60 dBc Input Amplitude 1Vp/p differential DAC Sample Rate upto 40 MS/s DAC Resolution 12 bits DAC Wideband SFDR 60 dBc Output Amplitude 250mV p/p differential Host Sample Rate 50/25 MS/s Frequency Accuracy 2.5 ppm SSB/LO Suppression >40 dBc FPGA Altera Cyclone Integrated Transceiver 3 Gbps Logic Elements 40,000 M9K Memory Blocks >400 Embedded Memory >2000 Kbits 18bit X18bit Multipliers >100 PLL 4 Maximum User I/Os >500 Maximum Channels >200 Differential Current Consumption <500mA, USB driven Cable High Speed USB 3.0 Serial Cable, RG316 SMA-SMA Antennas Directional LPDA 0.4-6 GHz, Omni Directional Dipole 0.4-6 GHz

Upgrade 1 year auto upgrade of new experiments/training videos/ operation manuals/ firmware /support over internet Shipping List Deliverable SDR X 2 pcs, Antennas X 4 SMA-SMA Cables X 4 pcs USB3.0 Cable X 2 Attenuator 20dB X 2pcs Software GUI features Audio, Boolean, Byte Operators, Channelizers, Channel Models, Coding, Control Port, Debug Tools Deprecated, Equalizers, Error Coding, File Operators, Filters, Fourier Analysis, GUI Widgets, Impairment Models, Instrumentation, Level Controllers, Math Operators, Measurement Tools,Message Tools, Misc, Modulators, Networking Tools, NOAA, OFDM, Packet Operators, Pager, Peak Detectors, Resamplers, Sinks, Sources, Stream Operators, Stream Tag Tools, Symbol Coding, Synchronizers, Trellis Coding, Type Converters, Variables, Waveform Generators. Scope of Experimentation * Introduction to SDR-LAB Hardware and Software environment * On air transmission & reception using Analog modulation & demodulation techniques like AM, DSBSC, SSB, Narrowband FM, Wideband FM, Stereo FM, * On air transmission & reception using Digital Modulation & Demodulation techniques like ASK, FSK, BPSK, DBPSK, MSK, GMSK, DQPSK, QPSK, OQPSK, pi/4QPSK, 8PSK,16QAM, 64QAM, 256QAM, CPFSK, GFSK, and other variants, * Spread spectrum techniques like CSS, DSSS, FHSS, THSS * Multiplexing techniques like TDM, FDM/WDM,SDM, Polarization, Spatial, Packet Switching, MC-SS, OFDM * Analog Channel Models like Noise (Uniform, Linear, Laplacian, Gaussian, Phase noise), Interference (Cross talk, Co-channel, Inter symbol), Distortion (Inter modulation), Frequency response (Attenuation & phase shift), Group delay, Propagation Doppler shift, Fading modeling slow, fast, selective/dispersive, Multipath, Rayleigh, Rician), *Channel Coding & decoding-Convolutional, Viterbi, Trellis, * Channel performance measurements (spectral bandwidth, Symbol Rate, Bit Rate, Channel Capacity, Channel Utilization, Signal to noise ratio, Bit Error Rate BER, Latency, Jitter, Eye Diagram, Constellation diagram, Oscilloscope, Spectrum Analyser, Waterfall display




+91-11-41505510, +91-120-4371276

Scope of Experimentation Contd. * Line Coding & Decoding Digital Baseband * Filters-IIR, FIR, Pulse Shaping-RRC root raised cosine, High pass, Low pass, Bandpass, Band stop, FFT, frequency translating filter, * Equalizer adaptive-CMA , Kurtotic, LMS DD * Synchronizers-Costas Loop, Clock Recovery, Frequency locked loop, phase locked loop, correlate and sync, carrier acquisition, * Modeling mathematical equations * Networking- TCP, UDP, Socket, Broadcasting, * Encoding decoding for data, voice & video-PSK31, MPEG, CVSD and more * On air link for Voice, Data, Video, * OFDM complete on air implementation * GSM on air decoding from live signals * CDMA Introduction Optional*: Vector Signal Generator Implementation* Vector Signal Analyser Implementation* MIMO 2X2 implementation* Cognitive Radio* Spectrum Sensing* Jammer Implementation* 4G LTE Implementation* RFID Implementation* Radar, SAR, Doppler, FMCW Implementation* Smart Distributed RF Sensors* Phased Array Antenna Beam forming* WiFi Implementation* GPS/GNSS Implementation* Satellite Radio Implementation* Radio Astronomy* Amateur Radio* GSM BTS & Network Implementation* CDMA Implementation* Student projects Research And more.....

GSM BTS Downlink On Air Capture

FIR RRC Filter Designing

SDR Architecture

Doppler Radar Implementation




+91-11-41505510, +91-120-4371276




Narrow Band FM signal captured on air 3G spectrum on Air


antenna training lab ats04 - tecnos · 3d software compatibility matlab 3d plot compliance ieee...

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