An Open Systems Architecture for Telemetry Receivers

Parker, Peter, Nelson, John, Pippitt, Mark

10 1900

An open systems architecture (OSA) is one in which all of the interfaces are fully defined, available to the public, and maintained according to a group consensus. One approach to achieve this is to use modular hardware and software and to buy commercial, off-the-shelf and commodity hardware. Benefits of an OSA include providing easy access to the latest technological advances in both hardware and software, enabling net-centric operations, and allowing a flexible design that can easily change as the needs of customers may change. This paper will provide details of an OSA system designed for a telemetry receiver and list the benefits of OSA for the telemetry community.

Open systems architecture

software defined radio

telemetry receiver architecture

C-band transition

Simultaneous Transmit/Receive Multi-Functional Ultra-Wideband Transceiver with Reduced Hardware

Bojja Venkatakrishnan, Satheesh

27 October 2017

No description available.

Electrical Engineering

Receiver Architecture

Transceivers

Simultaneous Transmit and Receive-STAR

On-site Coding Receiver-OSCR

Low Power Receiver Architecture And Algorithms For Low Data Rate Wireless Personal Area Networks

Dwivedi, Satyam

12 1900

Sensor nodes in a sensor network is power constrained. Transceiver electronics of a node in sensor network consume a good share of total power consumed in the node. The thesis proposes receiver architecture and algorithms which reduces power consumption of the receiver. The work in the thesis ranges from designing low power architecture of the receiver to experimentally verifying the functioning of the receiver. Concepts proposed in the thesis are: Low power adaptive architecture :-A baseband digital receiver design is proposed which changes its sampling frequency and bit-width based on interference detection and SNR estimation. The approach is based on Look-up-table (LUT) in the digital section of the receiver. Interference detector and SNR estimator has been proposed which suits this approach. Settings of different sections of digital receiver changes as sampling frequency and bit-width varies. But, this change in settings ensures that the desired BER is achieved. Overall, the receiver reduces amount of processing when conditions are benign and does more processing when conditions are not favorable. It is shown that the power consumption by the digital baseband can be reduced by 85% (7 times) when there is no interference and SNR is high. Thus the proposed design meets our requirement of low power hardware. The design is coded in Verilog HDL and power and area estimation is done using Synopsys tools. Faster Simulation Methodologies :-Usually physical layer simulations are done on baseband equivalent model of the signal in the receiver chain. Simulating Physical layer algorithms on bandpass signals for BER evaluation is very time consuming. We need to do the bandpass simulations to capture the effect of quantization on bandpass signal in the receiver. We have developed a variance measuring simulation methodology for faster simulation which reduces simulation time by a factor of 10. Low power, Low area, Non-coherent, Non-data-aided joint tracking and acquisition algorithm :-Correlation is a very popular function used particularly in synchronization algorithms in the receivers. But correlation requires usage of multipliers. Multipliers are area and power consuming blocks. A very low power and low area joint tracking and acquisition algorithm is developed. The algorithm does not use any multiplier to synchronize. Even it avoids squaring and adding the signals to achieve non-coherency. Beside the algorithm is non-data-aided as well and does not require ROM to store the sequence. The Algorithm saves area/power of existing similar algorithms by 90%. Experimental setup for performance evaluation of the receiver :-The developed baseband architecture and algorithms are experimentally verified on a wireless test setup. Wireless test setup consists of FPGA board, VSGs, Oscilloscopes, Spectrum analyzer and a discrete component RF board. Packet error and packet loss measurement is done by varying channel conditions. Many practical and interesting issues dealing with wireless test setup infrastructure were encountered and resolved.

Wireless Receiving Sets

Algorithms

Personal Receiving Sets

Wireless Personal Area Networks

Wireless Sensor Networks

Power Receiver Architecture

Power Scalable Receiver

IEEE 802.15.4

Low Power Radio Receiver

Low Power Receiver Architecture

Communication Engineering

Une infrastructure flexible de collecte et de traitement de données d’un réseau de capteurs urbain mutualisé / A flexible gateway receiver architecture for the urban sensor networks

Vallérian, Mathieu

15 June 2016

Dans les réseaux de capteurs urbains, les nœuds émettent des signaux en utilisant plusieurs protocoles de communication qui coexistent. Ces protocoles étant en évolution permanente, une approche orientée radio logicielle semble être la meilleure manière d’intégrer tous les protocoles sur la passerelle collectant les données. Tous les signaux sont donc numérisés en une fois. La grande plage dynamique des signaux reçus est alors le principal problème : ceux-ci peuvent être reçus avec une puissance très variable selon les conditions de propagation. Dans le cas d’une réception simultanée, le Convertisseur Analogique-Numérique (CAN) doit être capable d’absorber une telle dynamique. Une première étude est menée afin d’établir les caractéristiques requises du CAN sur une passerelle d’un tel réseau de capteurs. La résolution minimale de 21 bits obtenue s’avérant trop importante pour être atteinte au vu de l’état de l’art actuel, deux approches différentes sont explorées pour réduire la plage dynamique des signaux avant la numérisation. La première approche s’appuie sur la technique du companding. Des lois de compression connues sont explorées afin d’étudier leur viabilité dans le cas de la numérisation de signaux multiples, et deux nouvelles implémentations sont proposées pour la plus performante d’entre elles. La deuxième technique proposée consiste en une nouvelle architecture de réception utilisant deux voies de réception. La première d’entre elles est dédiée au signal le plus fort sur la bande : celui-ci est démodulé et sa fréquence d’émission est mesurée. À partir de cette mesure, la seconde branche est reconfigurée de manière à atténuer ce signal fort, en réduisant ainsi la plage dynamique. Les autres signaux sont ensuite numérisés sur cette branche avec une résolution du CAN réduite. Cette deuxième approche semblant plus prometteuse, elle est testée en expérimentation. Sa viabilité est démontrée avec des scénarios de réception de signaux prédéfinis représentant les pires cas possibles. / In this thesis, a receiver architecture for a gateway in a urban sensors network was designed. To embed the multiple protocols coexisting in this environment, the best approach seems to use a reconfigurable architecture, following the scheme of the Software-Defined Radio (SDR). All the received signals should be digitized at once by the Analog-to-Digital Converter (ADC) in order to sustain the reconfigurability of the architecture: then all the signal processing will be able to be digitally performed. The main complication comes from the heterogeneity of the propagation conditions: from the urban environment and from the diversity of the covered applications, the signals can be received on the gateway with widely varying powers. Then the gateway must be able to deal with the high dynamic range of these signals. This constraint applies strongly on the ADC whose resolution usually depends on the reachable digitized frequency band. A first study is led to evaluate the required ADC resolution to cope with the dynamic range. For this the dynamic range of the signals is first evaluated, then the required resolution to digitize the signals is found theoretically and with simulations. For a 100~dB power ratio between strong and weak signals, we showed that the ADC resolution needed 21 bits which is far too high to be reached with existing ADCs. Two different approaches are explored to reduce analogically the signals' dynamic range. The first one uses the companding technique, this technique being commonly used in analog dynamic range reduction in practice (\emph{e.g.} in audio signals acquisition), its relevance in multiple signal digitization is studied. Three existing compression laws are explored and two implementations are proposed for the most efficient of them. The feasibility of these implementations is also discussed. In the second approach we propose to use a two-antennas receiver architecture to decrease the dynamic range. In this architecture two digitization paths are employed: the first one digitizes only the strongest signal on the band. Using the information we get on this signal we reconfigure the second branch of the architecture in order to attenuate the strong signal. The dynamic range being reduced, the signals can be digitized with an ADC with a lower resolution. We show in this work that the ADC resolution can de decreased from 21 to 16 bits using this receiver architecture. Finally, the promising two-antennas architecture is tested in experimentation to demonstrate its efficiency with dynamic signals (\emph{i.e.} with appearing and disappearing signals).

Télécommunications

Réseaux de capteurs urbains

Front-End RF

Plage dynamique

Numérisation

Signaux multiples

Companding

Telecommunications

Urban sensors networks

RF front-End

Reconfigurable receiver architecture

Dynamic range

Digitization

Multiple signals

Companding

621.384 072

Power Scaling Mechanism for Low Power Wireless Receivers

Ghosal, Kaushik

January 2015

LOW power operation for wireless radio receivers has been gaining importance lately on account of the recent spurt of growth in the usage of ubiquitous embedded mobile devices. These devices are becoming relevant in all domains of human influence. In most cases battery life for these devices continue to be an us-age bottleneck as energy storage techniques have not kept pace with the growing demand of such mobile computing devices. Many applications of these radios have limitations on recharge cycle, i.e. the radio needs to last out of a battery for long duration. This will specially be true for sensor network applications and for im-plantable medical devices. The search for low power wireless receivers has become quite advanced with a plethora of techniques, ranging from circuit to architecture to system level approaches being formulated as part of standard design procedures. However the next level of optimization towards “Smart” receiver systems has been gaining credence and may prove to be the next challenge in receiver design and de-velopment. We aim to proceed further on this journey by proposing Power Scalable Wireless Receivers (PSRX) which have the capability to respond to instantaneous performance requirements to lower power even further. Traditionally low power receivers were designed for worst-case input conditions, namely low signal and high interference, leading to large dynamic range of operation which directly im-pacts the power consumption. We propose to take into account the variation in performance required out of the receiver, under varying Signal and Interference conditions, to trade-off power. We have analyzed, designed and implemented a Power Scalable Receiver tar-geted towards low data-rate receivers which can work for Zigbee or Bluetooth Low Energy (BLE) type standards. Each block of such a receiver system was evaluated for performance-power trade-offs leading to identification of tuning/control knobs at the circuit architecture level of the receiver blocks. Then we developed an usage algorithm for finding power optimal operational settings for the tuning knobs, while guaranteeing receiver reception performance in terms of Bit-Error-Rate (BER). We have proposed and demonstrated a novel signal measurement system to gen-erate digitized estimates of signal and interference strength in the received signal, called Received Signal Quality Indicator (RSQI). We achieve a RSQI average energy consumption of 8.1nJ with a peak energy consumption of 9.4nJ which is quite low compared to the packet reception energy consumption for low power receivers, and will be substantially lower than the energy savings which will be achieved from a power scalable receiver employing a RSQI. The full PSRX system was fabricated in UMC 130nm RF-CMOS process to test out our concepts and to formally quantify the power savings achieved by following the design methodology. The test chip occupied an area of 2.7mm2 with a peak power consumption of 5.5mW for the receiver chain and 18mW for the complete PSRX. We were able to meet the receiver performance requirements for Zigbee standard and achieved about 5X power savings for the range of input condition variations.

Power Scalable Wireless Receivers

Low Power Wireless Receivers

Low Noise Amplifier (LNA)

Wireless Radio Receivers

Power Scalable Receiver Architecture

Received Signal Quality Indicator

Power Scalabe Receiver Control Policy

Power Scaling Mechanism

Power Scalable Receiver

Power Scalable Receiver System

Variable Gain Amplifier (VGA)

Power Scaling Methodology

Power-Scalable RF CMOS Receiver

Electrical Communicatin Engineering

Systemanalyse und Entwicklung Six-Port basierter Funkempfängerarchitekturen unter Berücksichtigung analoger Störeffekte

Mailand, Marko

09 January 2008

Due to the increasing demand of broadband capability and reconfigurability for mobile applications, there is an enormous interest to develop appropriate analog receiver front-ends. In this respect, one promising candidate group is the Six-Port-based direct conversion receiver. The presented work focuses on the investigation of Six-Port-based mobile receiver front-ends with their specific systematical signal processing. Thereby, issues of spurious interfering signals which are generated within the down conversion process of such receivers are of special interest. Based on a comprehensive description of the analog signal processing within additive frequency conversion, a reason could be identified why existing Six-Port receivers have not found any practical application in mobile communication yet – the dynamic DC-offset. With this insight compensation techniques were developed to overcome the negative influences of the dynamic DC-offset. Furthermore, this work presents novel Six-Port-based receiver architectures which, on the one hand, keep the advantages of additive mixing systems like: low power consumption, broadband capability and simplicity of implementation especially for mm-wave transmissions. On the other hand, these novel architectures comprise compensation techniques such that systematically generated spurious signals are inherently compensated in the analog part of the receiver. Moreover, the influence of impairments of phase and amplitude within the IQ-branches of a receiver was investigated. The resulting, unwanted IQ-imbalance was shown to be a mixing method (multiplicative or additive) independent spurious effect. It is suggested to compensate for IQ-imbalance in the digital part of the receiver system. This can be realized with the use of adaptive algorithms. The comparison with conventional analog receiver architectures (especially homodyne receivers) with respect to the reception of today’s and future digitally modulated transmission signals indicate the proposed Six-Port-based receiver architectures to be suitable candidates to fulfill the difficult tasks of modern mobile communication.

Empfänger

Six-Port

Five-Port

Hochfrequenz

Hochfrequenzselbstmishcungsprodukt

IQ-Imbalance

blinde Signalseparation

Seven-Port

N-Port

Architektur

Funk

Mobilfunk

Front-End

Software Defined Radio

UWB

Ultra Wideband

Empfängerarchitektur

Störef

Receiver

Six-Port

Five-Port

Seven-Port

N-Port

radio frequency

spurious effect

analog

front-end

architecture

receiver architecture

blind source separation

IQ-imbalance

radio transmission

software defined radio

UWB

Ultra Wideband

mobile com

ddc:620

rvk:ZN 6560

Systemanalyse und Entwicklung Six-Port basierter Funkempfängerarchitekturen unter Berücksichtigung analoger Störeffekte

Mailand, Marko

22 October 2007

Due to the increasing demand of broadband capability and reconfigurability for mobile applications, there is an enormous interest to develop appropriate analog receiver front-ends. In this respect, one promising candidate group is the Six-Port-based direct conversion receiver. The presented work focuses on the investigation of Six-Port-based mobile receiver front-ends with their specific systematical signal processing. Thereby, issues of spurious interfering signals which are generated within the down conversion process of such receivers are of special interest. Based on a comprehensive description of the analog signal processing within additive frequency conversion, a reason could be identified why existing Six-Port receivers have not found any practical application in mobile communication yet – the dynamic DC-offset. With this insight compensation techniques were developed to overcome the negative influences of the dynamic DC-offset. Furthermore, this work presents novel Six-Port-based receiver architectures which, on the one hand, keep the advantages of additive mixing systems like: low power consumption, broadband capability and simplicity of implementation especially for mm-wave transmissions. On the other hand, these novel architectures comprise compensation techniques such that systematically generated spurious signals are inherently compensated in the analog part of the receiver. Moreover, the influence of impairments of phase and amplitude within the IQ-branches of a receiver was investigated. The resulting, unwanted IQ-imbalance was shown to be a mixing method (multiplicative or additive) independent spurious effect. It is suggested to compensate for IQ-imbalance in the digital part of the receiver system. This can be realized with the use of adaptive algorithms. The comparison with conventional analog receiver architectures (especially homodyne receivers) with respect to the reception of today’s and future digitally modulated transmission signals indicate the proposed Six-Port-based receiver architectures to be suitable candidates to fulfill the difficult tasks of modern mobile communication.

info:eu-repo/classification/ddc/620

ddc:620