Design And Simulation of Modulation Schemes used for FPGA Based Software Defi...Sucharita Saha
Design of a BPSK and QPSK digital Modulation scheme and its implementation on FPGAs for universal mobile telecommunications system and SDR applications. The simulation of the system is made in MATLAB Simulink environment and System Generator, a tool used for FPGA design. Hardware Co-Simulation is designed using VHDL a hardware description language targeting a Xilinx FPGA and is verified using MATLAB Simulink. It is then converted to VHDL level using Simulink HDL coder. The design is synthesized and fitted with Xilinx 14.2 ISE Edition software, and downloaded to Spartan 3E (XC3S500E) board.
Application of Microcontroller in Transmitter Section of Wireless Systemijceronline
International Journal of Computational Engineering Research (IJCER) is dedicated to protecting personal information and will make every reasonable effort to handle collected information appropriately. All information collected, as well as related requests, will be handled as carefully and efficiently as possible in accordance with IJCER standards for integrity and objectivity.
WIRELESS HOME AUTOMATION USING PIC MICROCONTROLLER BASED ON RF-MODULEEng.Manfred Kibona
This paper presents a project-based final year project course on completion of Bachelor degree in Telecommunication engineering. The goal of this project was to provide engineering students a hands-on experience involving actual engineering design on communication circuits, printed circuit board (PCB) design, layout, fabrication, assembly, and testing.
The scope of the project was been projected in develop a RF remote control system that will be capable for controlling various electrical appliances in the vicinity of 100 meters. The control signals has to traverse wirelessly by means of modulation with radio frequency carrier signal ranging from frequency band of 385MHz to 480MHz.
This project seeks to design innovative tools to measure in vivo biomechanical parameters of joint prostheses, orthopaedic implants, bones and ligaments. These tools, partly implanted, partly external, will record and analyze relevant information in order to improve medical treatments. An implant module includes sensors in order to measure the forces, temperature sensors to measure the interface frictions, magneto-resistance sensors to measure the 3D orientation of the knee joint as well as accelerometers to measure stem micro-motion and impacts. An external module, fixed on the patient.s body segments, includes electronic components to power and to communicate with the implant, as well as a set of sensors for measurements that can be realized externally.
This equipment is designed to help the surgeon with the alignment or positioning phase during surgery. After surgery, by providing excessive wear and micro-motion information about the prosthesis, it will allow to detect any early migration and potentially avoid later failure. During rehabilitation, it will provide useful outcomes to evaluate in vivo joint function. The tools provided can also be implanted during any joint surgery in order to give the physician the information needed to diagnose future disease such as ligament insufficiency, osteoarthritis or prevent further accident. The proposed nanosystems are set to improve the efficiency of healthcare, which is both a benefit to the patient and to society. Although the scientific and technical developments proposed in this project can be applied to all orthopaedic implants, the technological platform which is being built as a demonstrator is limited to the case of knee prosthesis. In addition, by reaching the minimum size achievable thanks to clever packaging techniques and also by reducing, or even removing, the cumbersome battery, it paves the way for a new generation of autonomous implantable medical devices.
Design And Simulation of Modulation Schemes used for FPGA Based Software Defi...Sucharita Saha
Design of a BPSK and QPSK digital Modulation scheme and its implementation on FPGAs for universal mobile telecommunications system and SDR applications. The simulation of the system is made in MATLAB Simulink environment and System Generator, a tool used for FPGA design. Hardware Co-Simulation is designed using VHDL a hardware description language targeting a Xilinx FPGA and is verified using MATLAB Simulink. It is then converted to VHDL level using Simulink HDL coder. The design is synthesized and fitted with Xilinx 14.2 ISE Edition software, and downloaded to Spartan 3E (XC3S500E) board.
Application of Microcontroller in Transmitter Section of Wireless Systemijceronline
International Journal of Computational Engineering Research (IJCER) is dedicated to protecting personal information and will make every reasonable effort to handle collected information appropriately. All information collected, as well as related requests, will be handled as carefully and efficiently as possible in accordance with IJCER standards for integrity and objectivity.
WIRELESS HOME AUTOMATION USING PIC MICROCONTROLLER BASED ON RF-MODULEEng.Manfred Kibona
This paper presents a project-based final year project course on completion of Bachelor degree in Telecommunication engineering. The goal of this project was to provide engineering students a hands-on experience involving actual engineering design on communication circuits, printed circuit board (PCB) design, layout, fabrication, assembly, and testing.
The scope of the project was been projected in develop a RF remote control system that will be capable for controlling various electrical appliances in the vicinity of 100 meters. The control signals has to traverse wirelessly by means of modulation with radio frequency carrier signal ranging from frequency band of 385MHz to 480MHz.
This project seeks to design innovative tools to measure in vivo biomechanical parameters of joint prostheses, orthopaedic implants, bones and ligaments. These tools, partly implanted, partly external, will record and analyze relevant information in order to improve medical treatments. An implant module includes sensors in order to measure the forces, temperature sensors to measure the interface frictions, magneto-resistance sensors to measure the 3D orientation of the knee joint as well as accelerometers to measure stem micro-motion and impacts. An external module, fixed on the patient.s body segments, includes electronic components to power and to communicate with the implant, as well as a set of sensors for measurements that can be realized externally.
This equipment is designed to help the surgeon with the alignment or positioning phase during surgery. After surgery, by providing excessive wear and micro-motion information about the prosthesis, it will allow to detect any early migration and potentially avoid later failure. During rehabilitation, it will provide useful outcomes to evaluate in vivo joint function. The tools provided can also be implanted during any joint surgery in order to give the physician the information needed to diagnose future disease such as ligament insufficiency, osteoarthritis or prevent further accident. The proposed nanosystems are set to improve the efficiency of healthcare, which is both a benefit to the patient and to society. Although the scientific and technical developments proposed in this project can be applied to all orthopaedic implants, the technological platform which is being built as a demonstrator is limited to the case of knee prosthesis. In addition, by reaching the minimum size achievable thanks to clever packaging techniques and also by reducing, or even removing, the cumbersome battery, it paves the way for a new generation of autonomous implantable medical devices.