Circuit Design of Baseband Transceiver for Direct Sequence Ultra-Wide Band Systems

Huang, Chun-Yuan

26 June 2009

A circuit design of baseband transceiver for direct sequence ultra-wide band system is presented in this thesis. A low complexity Viterbi decoder is also proposed. This Viterbi decoder circuit is based on compare-select-add unit and trace-forward architecture. The decision bit operator is reduced to one adder and this can lower down the hardware complexity. Further, two trace-forward operators are used in the survivor management unit. Only two single port SRAM¡¦s with a length of T are applied for reducing the area of memory. The chip is implemented by TSMC standard 0.18-£gm 1P6M CMOS process with core area 1.061 ¡Ñ 1.069 mm2. The post-layout simulation with 1.8V supply at 25 shows that the proposed direct sequence ultra-wide band system of baseband transceiver chip can work above 141 MHz with 86.41 mW power dissipation.

Viterbi decoder

Trace forward

Investigation of coded and uncoded CPM based wireless communication systems

Levita, C. J. A.

January 1999

No description available.

621.382

Design and Implementation of Low-Cost Dual Mode Channel Decoder

Ding, Yu-Chung

14 September 2006

This thesis addresses the design and implementation of a dual-mode channel decoder for two advanced wireless communication systems. One of the targetsystems is the digital video broadcasting for hand-held terminals (DVB-H) , and the other one is Worldwide Interoperability for Microwave Access (WiMAX) system based on the recently approved IEEE 802.16e. Both standards promise to deliver high data bandwidth within very broad regions. The error control coding schemes of both standards are all built on the similar concatenated code, with the exception of the way of data interleaving. Therefore, the decoders for both standards can be highly integrated. To achieve the low-cost and low-power decoder, this thesis proposes several novel design ideas. First, a fast dynamic multiple path convergence mechanism is proposed for the design of Viterbi decoder module, which can determine the survivor path at earlier stage. Furthermore, a new modified forward path prediction method is also presented which can efficiently predict the possiblesurvivor path such that the number of memory operations during the trace-back canbe significantly reduced. The proposed methodology can reduce up to 50% to 80%of memory operations compared with the best prediction scheme in the literature at high signal-to-noise ration. Secondly, for the block deinterleaver adopted by IEEE 802.16. a new multi-bank architecture is proposed by properly splitting and allocating the input data to suitable bank. The proposed block deinterleaver can be highly integrated with the byte-level convolutional deinterleaver adopted by the DVB-H standard by realizing the multiply First-In-First-Out (FIFO) data branches as the circular buffer. The other salient feature of the proposed dual-mode decoder is that all the major data storage units can all be realized by single-port memory such that the overall cost can be highly reduced.

DVB

channel decoder

Viterbi decoder

block deinterleaver

On a Viterbi decoder design for low power dissipation

Ranpara, Samirkumar Dhirajlal

29 April 1999

Convolutinal coding is a coding scheme often employed in deep space communications and recently in digital wireless communications. Viterbi decoders are used to decode convolutional codes. Viterbi decoders employed in digital wireless communications are complex and dissipate large power. With the proliferation of battery powered devices such as cellular phones and laptop computers, power dissipation, along with speed and area, is a major concern in VLSI design. In this thesis, we investigated a low-power design of Viterbi decoders for wireless communications applications. In CMOS technology the major source of power dissipation is attributed to dynamic power dissipation, which is due to the switching of signal values. The focus of our research in the low-power design of Viterbi decoders is reduction of dynamic power dissipation at logic level in the standard cell design environment. We considered two methods, clock-gating and toggle-filtering, in our design. A Viterbi decoder consists of five blocks. The clock-gating was applied to the survivor path storage block and the toggle-filtering to the trace-back block of a Viterbi decoder. We followed the standard cell design approach to implement the design. The behavior of a Viterbi decoder was described in VHDL, and then the VHDL description was modified to embed the low-power design. A gate level circuit was obtained from the behavioral description through logic synthesis, and a full scan design was incorporated into the gate level circuit to ease testing. The gate level circuit was placed and routed to generate a layout of the design. Our experimental result shows the proposed design reduces the power dissipation of a Viterbi decoder by about 42 percent compared with the on without considering the low-power design. / Master of Science

Full scan

Viterbi decoder

Low power

Synopsys

VITERBI DECODER FOR NASA’S SPACE SHUTTLE’S TELEMETRY DATA

Mayer, Robert, McDaniels, James, Kalil, Lou F.

10 1900

International Telemetering Conference Proceedings / October 26-29, 1992 / Town and Country Hotel and Convention Center, San Diego, California / In the event of a NASA Space Shuttle mission landing at the While Sands Missile Range, White Sands, New Mexico, a data communications system for processing Shuttle’s telemetry data has been installed there in the Master Control Telemetry Station, JIG-56. This data system required a Viterbi decoder since the Shuttle’s data is convolutionally encoded. However, the Shuttle uses a nonstandard code, and the manufacturer which in the past has provided decoders for Shuttle support, no longer produces them. Since no other company produced a Viterbi decoder designed to decode the shuttle’s data, it was necessary to develop the required decoder. The purpose of this paper is to describe the functional performance requirements and design of this decoder.

Viterbi decoder

Convolutional Encoding

Constraint Length

Code Generating Polynomials

A Low-power Convolutional Decoder with Error Detection Ability

Yeh, Wei-ting

03 August 2010

In wireless communication systems, we may encounter many problems. One of the main issues is noise interference. To overcome the problem, the sender can use the Convolutional coding method to encode the data, and the receiver can utilize the Viterbi algorithm for decoding and correction purposes. Due to the high complexity of the Viterbi algorithm, the VLSI structure of Viterbi decoder will consume large amounts of power, leading the portable devices to short standby time and high operating temperature. In order to solve these problems we have to design a low power decoder. As a matter of fact, the Viterbi decoder can be actually shutdown when no noise interference exists. As a consequence, we use a detection circuit to determine whether the signal is influenced by noise. If the signal is interfered, we choose the Viterbi decoder to perform the decoding process. Otherwise, we utilize a low cost decoder to lessen the power consumed at the receiver end. In addition, dynamic adjustment of SMU module is also developed and implemented in the proposed decoder. SMU module consumes the most power in Viterbi decoder. So, our developed and goal is to reduce the usage of SMU module. If noise distribution is not so dense, we don¡¦t have to use high decoding ability to decode section data. Therefore, the registers in SMU can be decreased. Clock gating technique is adopted in this thesis to shutdown these idle registers to reduce the power consumption of SMU. The proposed decoder has been implemented and synthesized using the Artisan TSMC 0.13£gm standard cell library. Compared with the traditional Viterbi decoder, the proposed decoder can achieve 25% and nearly 60% power saving when the SNR is 1dB and 8dB respectively, with 6% area reduction. According to the above experimental results, we can say that the proposed decoder is able to reduce power consumption.

Modulo Normalization

Dynamic Decoding Ability

Viterbi Decoder

Error Detection

Low-Power Adaptive Viterbi Decoder with Section Error Identification

Li, Shih-Jie

28 July 2011

In wireless communication system, convolutional coding method is often used to encode the data. In decoding convolutional code (CC), Viterbi algorithm is considered to be the best mechanism. Viterbi decoder (VD) was developed to execute the algorithm on mobile devices more effectively. This decoder is often used on 2G and 3G mobile phones. However, on 2G phones, VD consumes about one third of total power consumption of the signal receiver. Therefore it is very necessary to reduce the power consumption of VD on 2G and 3G phones. VD uses large amount of register in survivor metric unit (SMU), so that the decoder can receive enough CC and converge automatically. The goal of this thesis is to decrease power consumption of SMU by using path metric compare unit (PMCU) to find the best state of path metric unit (PMU). This way decreases half of registers and multiplexers required in SMU, leading to significant area reduction in decoder. During the process of signal transmission in wireless communication, different causes like the atmosphere, outer space radiation and man-made will interfere the signal by different degree. The stronger the noise is, the more interference CC will get. The error detection circuit used will mark the sections with noise interference before the CC enters the VD. If CC is interfered, it will be decoded by the whole VD. Otherwise, it will be decoded by low power decoder, where the controller will start clock gating mechanism on SMU to close up unnecessary power consumption block. The power consumption of is varying proposed Adaptive Viterbi decoder according to the interference degree. When interference degree is high, the power consumption is 21% less than conventional VD; when interference is low, it is 44% less. The results show that the proposed method can effectively reduce the power consumption of VD.

error detection

wireless communication

Viterbi decoder

convolutional code

low power

NEW TELEMETRY HARDWARE FOR THE DEEP SPACE NETWORK TELEMETRY PROCESSOR SYSTEM

Puri, Amit, Ozkan, Siragan, Schaefer, Peter, Anderson, Bob, Williams, Mike

10 1900

International Telemetering Conference Proceedings / October 23-26, 2000 / Town & Country Hotel and Conference Center, San Diego, California / This paper describes the new Telemetry Processor Hardware (TPH) that Avtec Systems has developed for the Deep Space Network (DSN) Telemetry Processor (TLP) system. Avtec is providing the Telemetry Processor Hardware to RTLogic! for integration into the Telemetry Processor system. The Deep Space Network (DSN) is an international network of antennas that supports interplanetary spacecraft missions for exploration of the solar system and the universe. The Jet Propulsion Laboratory manages the DSN for NASA. The TLP system provides the capability to acquire, process, decode and distribute deep space probe and Earth orbiter telemetry data. The new TLP systems will be deployed at each of the three deep-space communications facilities placed approximately 120 degrees apart around the world: at Goldstone, California; near Madrid, Spain; and near Canberra, Australia. The Telemetry Processor Hardware (TPH) supports both CCSDS and TDM telemetry data formats. The TPH performs the following processing steps: soft-symbol input selection and measurement; convolutional decoding; routing to external decoders; time tagging; frame synchronization; derandomization; and Reed-Solomon decoding. The TPH consists of a VME Viterbi Decoder/MCD III Interface board (VM-7001) and a PCI-mezzanine Frame Synchronizer/Reed-Solomon Decoder (PMC- 6130-J) board. The new Telemetry Processor Hardware is implemented using the latest Field Programmable Gate Array (FPGA) technology to provide the density and speed to meet the current requirements as well as the flexibility to accommodate processing enhancements in the future.

Telemetry Processor

Deep Space Network

JPL

CCSDS

Viterbi Decoder

Reed-Solomon

Frame Synchronizer

Low Power Register Exchange Viterbi Decoder for Wireless Applications

El-Dib, Dalia

January 2004

Since the invention of wireless telegraphy by Marconi in 1897, wireless technology has not only been enhanced, but also has become an integral part of our everyday lives. The first wireless mobile phone appeared around 1980. It was based on first generation analog technology that involved the use of Frequency Division Multiple Access (FDMA) techniques. Ten years later, second generation (2G) mobiles were dependent on Time Division Multiple Access (TDMA) techniques and Code Division Multiple Access (CDMA) techniques. Nowadays, third generation (3G) mobile systems depend on CDMA techniques to satisfy the need for faster, and more capacious data transmission in mobile wireless networks. Wideband CDMA (WCDMA) has become the major 3G air interface in the world. WCDMA employs convolutional encoding to encode voice and MPEG4 applications in the baseband transmitter at a maximum frequency of 2<i>Mbps</i>. To decode convolutional codes, Andrew Viterbi invented the Viterbi Decoder (VD) in 1967. In 2G mobile terminals, the VD consumes approximately one third of the power consumption of a baseband mobile transceiver. Thus, in 3G mobile systems, it is essential to reduce the power consumption of the VD. Conceptually, the Register Exchange (RE) method is simpler and faster than the Trace Back (TB) method for implementing the VD. However, in the RE method, each bit in the memory must be read and rewritten for each bit of information that is decoded. Therefore, the RE method is not appropriate for decoders with long constraint lengths. Although researchers have focused on implementing and optimizing the TB method, the RE method is focused on and modified in this thesis to reduce the RE method's power consumption. This thesis proposes a novel modified RE method by adopting a <i>pointer</i> concept for implementing the survivor memory unit (SMU) of the VD. A pointer is assigned to each register or memory location. The contents of thepointer which points to one register is altered to point to a second register, instead of copying the contents of the first register to the second. When the pointer concept is applied to the RE's SMU implementation (modified RE), there is no need to copy the contents of the SMU and rewrite them, but one row of memory is still needed for each state of the VD. Thus, the VDs in CDMA systems require 256 rows of memory. Applying the pointer concept reduces the VD's power consumption by 20 percent as estimated by the VHDL synthesis tool and by the new power reduction estimation that is introduced in this work. The coding gain for the modified RE method is 2. 6<i>dB</i> at an SNR of approximately 10-3. Furthermore, a novel zero-memory implementation for the modified RE method is proposed. If the initial state of the convolutional encoder is known, the entire SMU of the modified RE VD is reduced to only one row. Because the decoded data is generated in the required order, even this row of memory is dispensable. The zero-memory architecture is called the MemoryLess Viterbi Decoder (MLVD), and reduces the power consumption by approximately 50 percent. A prototype of the MLVD with a one third convolutional code rate and a constraint length of nine is mapped into a Xilinx 2V6000 chip, operating at 25 <i>MHz</i> with a decoding throughput of more than 3<i>Mbps</i> and a latency of two data bits. The other problem of the VD which is addressed in this thesis is the Add Compare Select Unit (ACSU) which is composed of 128 butterfly ACS modules. The ACSU's high parallelism has been previously solved by using a bit serial implementation. The 8-bit First Input First Output (FIFO) register, needed for the storage of each path metric (PM), is at the heart of the single bit serial ACS butterfly module. A new, simply controlled shift register is designed at the circuit level and integrated into the ACS module. A chip for the new module is also fabricated.

Electrical & Computer Engineering

viterbi decoder

wireless

low power

register exchange

Low Power Register Exchange Viterbi Decoder for Wireless Applications

El-Dib, Dalia

January 2004

Since the invention of wireless telegraphy by Marconi in 1897, wireless technology has not only been enhanced, but also has become an integral part of our everyday lives. The first wireless mobile phone appeared around 1980. It was based on first generation analog technology that involved the use of Frequency Division Multiple Access (FDMA) techniques. Ten years later, second generation (2G) mobiles were dependent on Time Division Multiple Access (TDMA) techniques and Code Division Multiple Access (CDMA) techniques. Nowadays, third generation (3G) mobile systems depend on CDMA techniques to satisfy the need for faster, and more capacious data transmission in mobile wireless networks. Wideband CDMA (WCDMA) has become the major 3G air interface in the world. WCDMA employs convolutional encoding to encode voice and MPEG4 applications in the baseband transmitter at a maximum frequency of 2<i>Mbps</i>. To decode convolutional codes, Andrew Viterbi invented the Viterbi Decoder (VD) in 1967. In 2G mobile terminals, the VD consumes approximately one third of the power consumption of a baseband mobile transceiver. Thus, in 3G mobile systems, it is essential to reduce the power consumption of the VD. Conceptually, the Register Exchange (RE) method is simpler and faster than the Trace Back (TB) method for implementing the VD. However, in the RE method, each bit in the memory must be read and rewritten for each bit of information that is decoded. Therefore, the RE method is not appropriate for decoders with long constraint lengths. Although researchers have focused on implementing and optimizing the TB method, the RE method is focused on and modified in this thesis to reduce the RE method's power consumption. This thesis proposes a novel modified RE method by adopting a <i>pointer</i> concept for implementing the survivor memory unit (SMU) of the VD. A pointer is assigned to each register or memory location. The contents of thepointer which points to one register is altered to point to a second register, instead of copying the contents of the first register to the second. When the pointer concept is applied to the RE's SMU implementation (modified RE), there is no need to copy the contents of the SMU and rewrite them, but one row of memory is still needed for each state of the VD. Thus, the VDs in CDMA systems require 256 rows of memory. Applying the pointer concept reduces the VD's power consumption by 20 percent as estimated by the VHDL synthesis tool and by the new power reduction estimation that is introduced in this work. The coding gain for the modified RE method is 2. 6<i>dB</i> at an SNR of approximately 10-3. Furthermore, a novel zero-memory implementation for the modified RE method is proposed. If the initial state of the convolutional encoder is known, the entire SMU of the modified RE VD is reduced to only one row. Because the decoded data is generated in the required order, even this row of memory is dispensable. The zero-memory architecture is called the MemoryLess Viterbi Decoder (MLVD), and reduces the power consumption by approximately 50 percent. A prototype of the MLVD with a one third convolutional code rate and a constraint length of nine is mapped into a Xilinx 2V6000 chip, operating at 25 <i>MHz</i> with a decoding throughput of more than 3<i>Mbps</i> and a latency of two data bits. The other problem of the VD which is addressed in this thesis is the Add Compare Select Unit (ACSU) which is composed of 128 butterfly ACS modules. The ACSU's high parallelism has been previously solved by using a bit serial implementation. The 8-bit First Input First Output (FIFO) register, needed for the storage of each path metric (PM), is at the heart of the single bit serial ACS butterfly module. A new, simply controlled shift register is designed at the circuit level and integrated into the ACS module. A chip for the new module is also fabricated.

Electrical & Computer Engineering

viterbi decoder

wireless

low power

register exchange