Low Cost Analytical Techniques for Transceiver Characterization

January 2013

abstract: Radio frequency (RF) transceivers require a disproportionately high effort in terms of test development time, test equipment cost, and test time. The relatively high test cost stems from two contributing factors. First, RF transceivers require the measurement of a diverse set of specifications, requiring multiple test set-ups and long test times, which complicates load-board design, debug, and diagnosis. Second, high frequency operation necessitates the use of expensive equipment, resulting in higher per second test time cost compared with mixed-signal or digital circuits. Moreover, in terms of the non-recurring engineering cost, the need to measure complex specfications complicates the test development process and necessitates a long learning process for test engineers. Test time is dominated by changing and settling time for each test set-up. Thus, single set-up test solutions are desirable. Loop-back configuration where the transmitter output is connected to the receiver input are used as the desirable test set- up for RF transceivers, since it eliminates the reliance on expensive instrumentation for RF signal analysis and enables measuring multiple parameters at once. In-phase and Quadrature (IQ) imbalance, non-linearity, DC offset and IQ time skews are some of the most detrimental imperfections in transceiver performance. Measurement of these parameters in the loop-back mode is challenging due to the coupling between the receiver (RX) and transmitter (TX) parameters. Loop-back based solutions are proposed in this work to resolve this issue. A calibration algorithm for a subset of the above mentioned impairments is also presented. Error Vector Magnitude (EVM) is a system-level parameter that is specified for most advanced communication standards. EVM measurement often takes extensive test development efforts, tester resources, and long test times. EVM is analytically related to system impairments, which are typically measured in a production test i environment. Thus, EVM test can be eliminated from the test list if the relations between EVM and system impairments are derived independent of the circuit implementation and manufacturing process. In this work, the focus is on the WLAN standard, and deriving the relations between EVM and three of the most detrimental impairments for QAM/OFDM based systems (IQ imbalance, non-linearity, and noise). Having low cost test techniques for measuring the RF transceivers imperfections and being able to analytically compute EVM from the measured parameters is a complete test solution for RF transceivers. These techniques along with the proposed calibration method can be used in improving the yield by widening the pass/fail boundaries for transceivers imperfections. For all of the proposed methods, simulation and hardware measurements prove that the proposed techniques provide accurate characterization of RF transceivers. / Dissertation/Thesis / Ph.D. Electrical Engineering 2013

Electrical engineering

BiST

EVM Test

RF Test

Transceiver

Efficient Test Methods for RF Transceivers

Erdogan, Erdem Serkan

January 2010

<p>Advancements of the semiconductor technology opened a new era in</p> <p>wireless communications which led manufacturers to produce faster,</p> <p>more functional devices in much smaller sizes. However, testing</p> <p>these devices of today's technology became much harder and expensive</p> <p>due to the complexity of the devices and the high operating speeds.</p> <p>Moreover, testing these devices becomes more important since decreasing</p> <p>feature sizes increase the probability of parametric and catastrophic</p> <p>faults because of the severe effects of process variations. Manufacturers</p> <p>have to increase their test budgets to address quality and reliability</p> <p>concerns. In the radio frequency (RF) domain, overall test cost are higher</p> <p>due to equipment costs, test development and test time costs. Advanced</p> <p>circuit integration, which integrates various analog and digital circuit</p> <p>blocks into single device, increases test costs further because of the</p> <p>additional tests requiring new test setups with extra test equipments.</p> <p>Today's RF transceiver circuits contain many analog and digital circuit</p> <p>blocks, such as synthesizers, data converters and the analog RF front-end</p> <p>leading to a mixed signal device. Verification of the specifications and</p> <p>functionality of each circuit block and the overall transceiver require</p> <p>RF instrumentation and lengthy test routines. In this dissertation, we</p> <p>propose efficient component and system level test methods for RF</p> <p>transceivers which are low cost alternatives to traditional tests.</p> <p>In the first component level test, we focus on in-band phase noise of the</p> <p>phase locked loops (PLL). Most on-chip self-test methods for PLLs aim at</p> <p>measuring the timing jitter that may require precise reference clocks and/or</p> <p>additional computation of measured specs. We propose a built in test (BiT)</p> <p>circuit to perform a go/no-go test for in-band PLL phase noise. The proposed</p> <p>circuit measures the band-limited noise power at the input of the voltage</p> <p>controlled oscillator (VCO). This noise power is translated as the high</p> <p>frequency in-band phase noise at the output of the PLL. Our circuit contains</p> <p>a self calibration sequence based on a simple sinusoidal input signal to make</p> <p>it robust with respect to process variations.</p> <p>The second component level test is a built in self test (BiST) scheme</p> <p>proposed for analog to digital converters (ADC) based on a linear ramp</p> <p>generator and efficient output analysis. The proposed analysis method is</p> <p>an alternative to histogram based analysis techniques to provide test time</p> <p>improvements, especially when the resources are scarce. In addition to the</p> <p>measurement of differential nonlinearity (DNL) and integral nonlinearity</p> <p>(INL), non-monotonic behavior of the ADC can also be detected with the</p> <p>proposed technique. The proposed ramp generator has a high linearity</p> <p>capable of testing 13-bit ADCs.</p> <p>In the proposed system level test methods, we utilize the loop-back</p> <p>configuration to eliminate the need for an RF instrument. The first loop-back</p> <p>test method, which is proposed for wafer level test of direct conversion</p> <p>transceivers, targets catastrophic and large parametric faults. The use of</p> <p>intermediate frequencies (IF) generates a frequency offset between the transmit</p> <p>and receive paths and prevents a direct loop-back connection. We overcome this</p> <p>problem by expanding the signal bandwidth through saturating the receive path</p> <p>composed of low noise amplifier (LNA) and mixer. Once the dynamic range of the</p> <p>receiver path is determined, complete transceiver can be tested for catastrophic</p> <p>signal path faults by observing the output signal. A frequency spectrum</p> <p>envelope signature technique is proposed to detect large parametric faults.</p> <p>The impact of impairments, such as transmitter receiver in-phase/quadrature</p> <p>(I/Q) gain and phase mismatches on the performance have become severe due to</p> <p>high operational speeds and continuous technology scaling. In the second system</p> <p>level loop-back test method, we present BiST solutions for quadrature modulation</p> <p>transceiver circuits with quadrature phase shift keying (QPSK) and Gaussian</p> <p>minimum shift keying (GMSK) baseband modulation schemes. The BiST methods</p> <p>use only transmitter and receiver baseband signals for test analysis. The</p> <p>mapping between transmitter input signals and receiver output signals are</p> <p>used to extract impairment and nonlinearity parameters separately with the</p> <p>help of signal processing methods and detailed nonlinear system modeling.</p> <p>The last system level test proposed in this dissertation combines the benefits </p> <p>of loop-back and multi-site test approaches. In this test method, we present </p> <p>a 2x-site test solution for RF transceivers. We perform all operations on </p> <p>communication standard-compliant signal packets, thereby putting the device </p> <p>under the normal operating conditions. The transmitter on one device under </p> <p>test (DUT) is coupled with a receiver on another DUT to form a complete TX-RX </p> <p>path. Parameters of the two devices are decoupled from one another by carefully </p> <p>modeling the system into a known format and using signal processing techniques.</p> / Dissertation

Engineering, Electronics and Electrical

ADC

Loop-back

Multi-site

RF Test

Synthesizer

Wafer Level

Efficient Alternate Test Generation for RF Transceiver Architectures

Halder, Achintya

03 May 2006

The production testing cost of modern wireless communication systems, especially basestation units, is estimated to be as high as 30-40 percent of their manufacturing cost and is increasing with system complexity, high levels of device integration and scaling of CMOS process technology and operating frequencies. The major production testing challenges for RF transceivers are: (a) the high cost of automated test development because of system-level simulation difficulties and the large simulation times involved, (b) the high cost of using high-end, communication protocol-aware RF test instrumentation, and (c) lack of external test access to RF circuits embedded inside integrated transceivers. Consequently, there exists a need for developing efficient design-for-test methodologies and non-invasive system-level test techniques for wireless transceivers to reduce their test cost. This dissertation is focused towards development of new system-level alternate test methodologies for RF transceiver architectures. The research proposes using non-invasive testing techniques for RF subsystems and digital-compatible built-in testing techniques for baseband and intermediate frequency (IF) analog circuits. The objectives of this research are: (a) to develop automatic test stimulus generation algorithms that allow accurate determination of targeted RF system-level test specification values using behavioral modeling and simulation techniques, (b) to develop RF transceiver test techniques that allow testing of embedded RF systems with limited test access, while reducing the test time for complex RF and baseband system-level performance metrics (b) to significantly reduce the test instrumentation overhead for testing complex frequency-domain and modulation-domain system specifications. The feasibility and the cost benefits of using the proposed alternate test approaches have been demonstrated using 900 MHz and 1575 MHz transceiver prototypes.

Wireless test

Alternate test

RF test

Wireless transceiver

System-level test

Production test

Digitally assisted test methodology for RF receivers

Zeidan, Mohamad A.

25 February 2013

Addressing the high cost of RF instrumentation has motivated significant research activity, where researchers have proposed various non-standard and alternative test methods of RF circuits to mitigate high test cost. This dissertation describes a test methodology for RF receivers, whereby simple digital circuits comprise the core of the otherwise complex and costly broadband RF/analog signal generation. The proposed test methodology relies on a digital clock, commonly available to RF ICs for the purpose of digital communication, to generate the broadband RF stimulus needed for the receiver analog tests. The test method also utilizes commonly available baseband signal digitization (on-chip or off-chip) to acquire the baseband signal. It then relies on sophisticated, but inexpensive, signal processing to extract and compute standard RF performance parameters, like gain, noise figure (NF), and input-referred third-order intercept point (IIP3). In addition, the test method can extract important baseband (BB) parameters like the BB filter 3 dB bandwidth (BW), filter rejection at specific BB frequencies, or the BB filter profile. The motivation behind the proposed test methodology can be categorized as both architectural and cost reduction-oriented. Architecturally, the proposed test method aims at shifting the complexity involved in the test of RF receivers from the hardware (input) RF signal generation side to the signal processing done on the (output) baseband side. The process of shifting the complexity from the hardware design side to the signal processing side involves significant complex and sophisticated analysis, which is part of this dissertation. Cost-wise, the proposed test methodology enables the use of digital automatic test equipment (ATE) with limited baseband capability, instead of the full standard RF testers. Such a step reduces the initial tester cost and impacts the cost/sec figure spent on test for the life of the ATE tester, thus leading to test cost reduction. / text

RF receiver

RF test

Multitone

Gain

NF

IIP3

Phase-shift

Receiver state transition

Low cost BIST techniques for linear and non-linear analog circuits / Técnicas de teste embarcado de baixo custo para circuitos analógicos lineares e não-lineares

Negreiros, Marcelo

January 2005

Com a crescente demanda por produtos eletrônicos de consumo de alta complexidade, o mercado necessita de um rápido ciclo de desenvolvimento de produto com baixo custo. O projeto de equipamentos eletrônicos baseado no uso de núcleos de propriedade intelectual ("IP cores") proporciona flexibilidade e velocidade de desenvolvimento dos chamados "sistemas num chip". Entretanto, os custos do teste destes sistemas podem alcançar um percentual significativo do valor total de produção, principalmente no caso de sistemas contendo "IP cores" analógicos ou "mixed-signal". Técnicas de teste embarcado (BIST e DFT) para circuitos analógicos, embora potencialmente capazes de minimizar o problema, apresentam limitações que restringem seu emprego a casos específicos. Algumas técnicas são dependentes do circuito, necessitando reconfiguração do circuito sob teste, e não são, em geral, utilizáveis em RF. No ambiente de "sistemas num chip", como recursos de processamento e memória estão disponíveis, eles poderiam ser utilizados durante o teste. No entanto, a sobrecarga de adicionar conversores AD e DA pode ser muito onerosa para a maior parte dos sistemas, e o roteamento analógico dos sinais pode não ser possível, além de poder introduzir distorção do sinal. Neste trabalho um digitalizador simples e de baixo custo é usado ao invés de um conversor AD para possibilitar a implementação de estratégias de teste no ambiente de "sistemas num chip". Graças ao baixo acréscimo de área analógica do conversor, múltiplos pontos de teste podem ser usados. Graças ao desempenho do conversor, é possível observar características dos sinais analógicos presentes nos "IP cores", incluindo a faixa de freqüências de RF usada em transceptores para comunicações sem fio. O digitalizador foi utilizado com sucesso no teste de circuitos analógicos de baixa freqüência e de RF. Como o teste é baseado no domínio freqüência, características nãolineares como produtos de intermodulação podem também ser avaliadas. Especificamente, resultados práticos com protótipos foram obtidos para filtros de banda base e para um mixer a 100MHz. A aplicação do conversor para avaliação da figura de ruído também foi abordada, e resultados experimentais utilizando amplificadores operacionais convencionais foram obtidos para freqüências na faixa de áudio. O método proposto é capaz de melhorar a testabilidade de projetos que utilizam circuitos de sinais mistos, sendo adequado ao uso no ambiente de "sistemas num chip" usado em muitos produtos atualmente. / With the ever increasing demands for high complexity consumer electronic products, market pressures demand faster product development and lower cost. SoCbased design can provide the required design flexibility and speed by allowing the use of IP cores. However, testing costs in the SoC environment can reach a substantial percent of the total production cost. Analog testing costs may dominate the total test cost, as testing of analog circuits usually require functional verification of the circuit and special testing procedures. For RF analog circuits commonly used in wireless applications, testing is further complicated because of the high frequencies involved. In summary, reducing analog test cost is of major importance in the electronic industry today. BIST techniques for analog circuits, though potentially able to solve the analog test cost problem, have some limitations. Some techniques are circuit dependent, requiring reconfiguration of the circuit being tested, and are generally not usable in RF circuits. In the SoC environment, as processing and memory resources are available, they could be used in the test. However, the overhead for adding additional AD and DA converters may be too costly for most systems, and analog routing of signals may not be feasible and may introduce signal distortion. In this work a simple and low cost digitizer is used instead of an ADC in order to enable analog testing strategies to be implemented in a SoC environment. Thanks to the low analog area overhead of the converter, multiple analog test points can be observed and specific analog test strategies can be enabled. As the digitizer is always connected to the analog test point, it is not necessary to include muxes and switches that would degrade the signal path. For RF analog circuits, this is specially useful, as the circuit impedance is fixed and the influence of the digitizer can be accounted for in the design phase. Thanks to the simplicity of the converter, it is able to reach higher frequencies, and enables the implementation of low cost RF test strategies. The digitizer has been applied successfully in the testing of both low frequency and RF analog circuits. Also, as testing is based on frequency-domain characteristics, nonlinear characteristics like intermodulation products can also be evaluated. Specifically, practical results were obtained for prototyped base band filters and a 100MHz mixer. The application of the converter for noise figure evaluation was also addressed, and experimental results for low frequency amplifiers using conventional opamps were obtained. The proposed method is able to enhance the testability of current mixed-signal designs, being suitable for the SoC environment used in many industrial products nowadays.

Eletrônica

Testes : Circuitos integrados

Analog testing

Analog BIST

RF test

Low cost analog test

Low cost BIST techniques for linear and non-linear analog circuits / Técnicas de teste embarcado de baixo custo para circuitos analógicos lineares e não-lineares

Negreiros, Marcelo

January 2005

Com a crescente demanda por produtos eletrônicos de consumo de alta complexidade, o mercado necessita de um rápido ciclo de desenvolvimento de produto com baixo custo. O projeto de equipamentos eletrônicos baseado no uso de núcleos de propriedade intelectual ("IP cores") proporciona flexibilidade e velocidade de desenvolvimento dos chamados "sistemas num chip". Entretanto, os custos do teste destes sistemas podem alcançar um percentual significativo do valor total de produção, principalmente no caso de sistemas contendo "IP cores" analógicos ou "mixed-signal". Técnicas de teste embarcado (BIST e DFT) para circuitos analógicos, embora potencialmente capazes de minimizar o problema, apresentam limitações que restringem seu emprego a casos específicos. Algumas técnicas são dependentes do circuito, necessitando reconfiguração do circuito sob teste, e não são, em geral, utilizáveis em RF. No ambiente de "sistemas num chip", como recursos de processamento e memória estão disponíveis, eles poderiam ser utilizados durante o teste. No entanto, a sobrecarga de adicionar conversores AD e DA pode ser muito onerosa para a maior parte dos sistemas, e o roteamento analógico dos sinais pode não ser possível, além de poder introduzir distorção do sinal. Neste trabalho um digitalizador simples e de baixo custo é usado ao invés de um conversor AD para possibilitar a implementação de estratégias de teste no ambiente de "sistemas num chip". Graças ao baixo acréscimo de área analógica do conversor, múltiplos pontos de teste podem ser usados. Graças ao desempenho do conversor, é possível observar características dos sinais analógicos presentes nos "IP cores", incluindo a faixa de freqüências de RF usada em transceptores para comunicações sem fio. O digitalizador foi utilizado com sucesso no teste de circuitos analógicos de baixa freqüência e de RF. Como o teste é baseado no domínio freqüência, características nãolineares como produtos de intermodulação podem também ser avaliadas. Especificamente, resultados práticos com protótipos foram obtidos para filtros de banda base e para um mixer a 100MHz. A aplicação do conversor para avaliação da figura de ruído também foi abordada, e resultados experimentais utilizando amplificadores operacionais convencionais foram obtidos para freqüências na faixa de áudio. O método proposto é capaz de melhorar a testabilidade de projetos que utilizam circuitos de sinais mistos, sendo adequado ao uso no ambiente de "sistemas num chip" usado em muitos produtos atualmente. / With the ever increasing demands for high complexity consumer electronic products, market pressures demand faster product development and lower cost. SoCbased design can provide the required design flexibility and speed by allowing the use of IP cores. However, testing costs in the SoC environment can reach a substantial percent of the total production cost. Analog testing costs may dominate the total test cost, as testing of analog circuits usually require functional verification of the circuit and special testing procedures. For RF analog circuits commonly used in wireless applications, testing is further complicated because of the high frequencies involved. In summary, reducing analog test cost is of major importance in the electronic industry today. BIST techniques for analog circuits, though potentially able to solve the analog test cost problem, have some limitations. Some techniques are circuit dependent, requiring reconfiguration of the circuit being tested, and are generally not usable in RF circuits. In the SoC environment, as processing and memory resources are available, they could be used in the test. However, the overhead for adding additional AD and DA converters may be too costly for most systems, and analog routing of signals may not be feasible and may introduce signal distortion. In this work a simple and low cost digitizer is used instead of an ADC in order to enable analog testing strategies to be implemented in a SoC environment. Thanks to the low analog area overhead of the converter, multiple analog test points can be observed and specific analog test strategies can be enabled. As the digitizer is always connected to the analog test point, it is not necessary to include muxes and switches that would degrade the signal path. For RF analog circuits, this is specially useful, as the circuit impedance is fixed and the influence of the digitizer can be accounted for in the design phase. Thanks to the simplicity of the converter, it is able to reach higher frequencies, and enables the implementation of low cost RF test strategies. The digitizer has been applied successfully in the testing of both low frequency and RF analog circuits. Also, as testing is based on frequency-domain characteristics, nonlinear characteristics like intermodulation products can also be evaluated. Specifically, practical results were obtained for prototyped base band filters and a 100MHz mixer. The application of the converter for noise figure evaluation was also addressed, and experimental results for low frequency amplifiers using conventional opamps were obtained. The proposed method is able to enhance the testability of current mixed-signal designs, being suitable for the SoC environment used in many industrial products nowadays.

Eletrônica

Testes : Circuitos integrados

Analog testing

Analog BIST

RF test

Low cost analog test

Low cost BIST techniques for linear and non-linear analog circuits / Técnicas de teste embarcado de baixo custo para circuitos analógicos lineares e não-lineares

Negreiros, Marcelo

January 2005

Com a crescente demanda por produtos eletrônicos de consumo de alta complexidade, o mercado necessita de um rápido ciclo de desenvolvimento de produto com baixo custo. O projeto de equipamentos eletrônicos baseado no uso de núcleos de propriedade intelectual ("IP cores") proporciona flexibilidade e velocidade de desenvolvimento dos chamados "sistemas num chip". Entretanto, os custos do teste destes sistemas podem alcançar um percentual significativo do valor total de produção, principalmente no caso de sistemas contendo "IP cores" analógicos ou "mixed-signal". Técnicas de teste embarcado (BIST e DFT) para circuitos analógicos, embora potencialmente capazes de minimizar o problema, apresentam limitações que restringem seu emprego a casos específicos. Algumas técnicas são dependentes do circuito, necessitando reconfiguração do circuito sob teste, e não são, em geral, utilizáveis em RF. No ambiente de "sistemas num chip", como recursos de processamento e memória estão disponíveis, eles poderiam ser utilizados durante o teste. No entanto, a sobrecarga de adicionar conversores AD e DA pode ser muito onerosa para a maior parte dos sistemas, e o roteamento analógico dos sinais pode não ser possível, além de poder introduzir distorção do sinal. Neste trabalho um digitalizador simples e de baixo custo é usado ao invés de um conversor AD para possibilitar a implementação de estratégias de teste no ambiente de "sistemas num chip". Graças ao baixo acréscimo de área analógica do conversor, múltiplos pontos de teste podem ser usados. Graças ao desempenho do conversor, é possível observar características dos sinais analógicos presentes nos "IP cores", incluindo a faixa de freqüências de RF usada em transceptores para comunicações sem fio. O digitalizador foi utilizado com sucesso no teste de circuitos analógicos de baixa freqüência e de RF. Como o teste é baseado no domínio freqüência, características nãolineares como produtos de intermodulação podem também ser avaliadas. Especificamente, resultados práticos com protótipos foram obtidos para filtros de banda base e para um mixer a 100MHz. A aplicação do conversor para avaliação da figura de ruído também foi abordada, e resultados experimentais utilizando amplificadores operacionais convencionais foram obtidos para freqüências na faixa de áudio. O método proposto é capaz de melhorar a testabilidade de projetos que utilizam circuitos de sinais mistos, sendo adequado ao uso no ambiente de "sistemas num chip" usado em muitos produtos atualmente. / With the ever increasing demands for high complexity consumer electronic products, market pressures demand faster product development and lower cost. SoCbased design can provide the required design flexibility and speed by allowing the use of IP cores. However, testing costs in the SoC environment can reach a substantial percent of the total production cost. Analog testing costs may dominate the total test cost, as testing of analog circuits usually require functional verification of the circuit and special testing procedures. For RF analog circuits commonly used in wireless applications, testing is further complicated because of the high frequencies involved. In summary, reducing analog test cost is of major importance in the electronic industry today. BIST techniques for analog circuits, though potentially able to solve the analog test cost problem, have some limitations. Some techniques are circuit dependent, requiring reconfiguration of the circuit being tested, and are generally not usable in RF circuits. In the SoC environment, as processing and memory resources are available, they could be used in the test. However, the overhead for adding additional AD and DA converters may be too costly for most systems, and analog routing of signals may not be feasible and may introduce signal distortion. In this work a simple and low cost digitizer is used instead of an ADC in order to enable analog testing strategies to be implemented in a SoC environment. Thanks to the low analog area overhead of the converter, multiple analog test points can be observed and specific analog test strategies can be enabled. As the digitizer is always connected to the analog test point, it is not necessary to include muxes and switches that would degrade the signal path. For RF analog circuits, this is specially useful, as the circuit impedance is fixed and the influence of the digitizer can be accounted for in the design phase. Thanks to the simplicity of the converter, it is able to reach higher frequencies, and enables the implementation of low cost RF test strategies. The digitizer has been applied successfully in the testing of both low frequency and RF analog circuits. Also, as testing is based on frequency-domain characteristics, nonlinear characteristics like intermodulation products can also be evaluated. Specifically, practical results were obtained for prototyped base band filters and a 100MHz mixer. The application of the converter for noise figure evaluation was also addressed, and experimental results for low frequency amplifiers using conventional opamps were obtained. The proposed method is able to enhance the testability of current mixed-signal designs, being suitable for the SoC environment used in many industrial products nowadays.

Eletrônica

Testes : Circuitos integrados

Analog testing

Analog BIST

RF test

Low cost analog test

Signature driven low cost test, diagnosis and tuning of wireless systems

Devarakond , Shyam Kumar

26 March 2013

With increased and varied performance demands, it is essential that complex multi-standard radio/systems coexist on a same chip. To have cost and performance benefits, these analog/RF systems are implemented in scaled nanometer nodes. At these nodes, the high level of variability in process variations is making the task of manufacturing high fidelity systems a challenge leading to yield and reliability issues. Hence, in the post-manufacturing phase, test and diagnosis steps are critical to identify the cause and effect of the process variations. Further, intelligent post-manufacturing tuning techniques are required to correct the effect of process variations on analog/RF systems. In this work, a die-level concurrent test and diagnosis approach using optimized measurements obtained in high volume manufacturing environment is proposed for analog/RF circuits. Such a simultaneous test and diagnosis methodology enables monitoring parametric process shifts and providing rapid feedback to the fab to minimize or prevent yield loss. In the case of devices that are continuously operating in the field, an efficient on-line diagnosis approach has been developed to perform reliability related prognosis. For advanced RF technologies such as MIMO-OFDM systems, a rapid system-level testing scheme is presented that performs concurrent testing of the multiple RF chains. Depending on the availability of the computational resources and system tuning knobs, different low-cost methodologies for post-manufacture tuning or self-healing of RF SISO/MIMO systems are developed. These include faster digital monitoring and tuning techniques, on-chip tuning techniques using digital logic that enables die-level self-tuning, and DSP-based power conscious iterative techniques for SISO/MIMO RF systems. An adaptive power-performance tuning technique is developed for those devices that have a post-manufacture power consumption value that is more than the acceptable limit. These intelligent post-manufacturing techniques result in reduced manufacturing cost, improved yield, and reliability of analog/RF systems.

Analog/RF self-tuning

Spice-level diagnosis

Analog/RF test

Wireless communication systems

Radio

Radio frequency

Mixed signal circuits

Characterization and modeling of devices and amplifier circuits at millimeter wave band / Mesure et modélisation de dispositifs et d’amplificateurs aux fréquences millimétriques

Hamani, Rachid

12 December 2014

Ces travaux de thèse portent sur l’étude des solutions innovantes de caractérisation destinées à l’amélioration de la précision du schéma équivalent petit signal à des fréquences d’ordre millimétrique. Après un état de l’art dans ce domaine et suite à plusieurs caractérisations au niveau composant, une nouvelle structure de test “nouvelle approche” est conçue, réalisée et caractérisée. Cette approche est basée sur une nouvelle méthode d’extraction du schéma équivalent petit signal à partir d’une structure adaptée. Cette méthode réalise une adaptation des impédances du transistor sous test aux impédances des équipements de mesure. Comme résultats, la transmission du signal entre la source et le composant sous test ainsi que la précision de la mesure des paramètres extraits sont améliorés. La méthode développée permet la validation des modèles compacts des composants fabriqués en technologie BiCMOS 0.25μm au niveau circuit. Les mesures réalisées ont montré une bonne amélioration de l’extraction entre un transistor sous test seul et un transistor sous test adapté. La méthode d’investigation proposée permet l’extraction des modèles à des très hautes fréquences avec une meilleure précision. Cette thèse ouvre donc des perspectives pour la caractérisation en bande millimétrique notamment caractérisation des structures adaptées en impédances et de méthodes de de-embedding dédiées à ces dernières. / This thesis deals with the study of innovative solutions for small signal characterization at millimeter wave frequency. After a state of the art in this field and following to several characterizations at device level, a new test structure “new approach” is designed, fabricated, and characterized. The approach of characterizing at circuit level is based on a new method to extract the small signal equivalent circuit using matched test structures. This method proposed here makes the DUT impedances carefully match the characteristic impedances of the measurement equipment. In results, the transmission of the signal from the source to the DUT is improved while the parameters extraction accuracy is improved. The developed method enables the BiCMOS 0.25μm compact models validation in circuit level in mm-Wave band and enables accurate parameter extraction in a narrow band at higher frequencies. The verification results demonstrated that the new test structure significantly outperformed the conventional method in measurement accuracy specifically in very high frequency. Some aspects of the matched test structure could be subject of further investigation. In particularly topics such as, characterization over multiple test structure geometries and deembedding test structure losses.

Bande millimétrique

Caractérisation RF

Structures de test RF

Paramètres S

Circuit RF

Millimeter waves

RF characterization

RF test structures

S-parameters

RF circuit

621.381 5

Built-In Self-Test of Flexible RF Transmitters Using Nonuniform Undersampling / Application de la technique de sous-échantillonnage non-uniforme au test intégré des émetteurs RF flexibles

Dogaru, Emanuel

06 March 2015

Le secteur de communications sécurisés et portables connait une véritable révolution avec l’apparition des plateformes dites radios logiciels (Software Defined Radios, SDRs). Les performances exceptionnelles de ces systèmes sont les résultats d’une interaction assez complexe et souvent peu évidente entre le logiciel embarqué, le circuit de traitement numérique et les blocs mixtes analogiques/RF. Cette complexité limite la testabilité du produit fini. La méthodologie de test utilisée actuellement a atteint ses limites dues au cout élevé, le long temps de test et le bas degré de généralisation. De plus, les plateformes SDRs peuvent évoluer sur le terrain et elles vont supporter des standards et des scénarios qui n’ont pas été considérés pendant le la phase de conception. Donc, une stratégie de test sur le terrain (en ligne) n’est plus une caractéristique optionnelle mais une nécessité. Dans ce contexte, le but de notre recherche est d’inventer et développer une méthodologie de test capable de garantir le bon fonctionnement d’une plateforme SDR après la production et pendant sa vie. Notre objectif final est de réduire le coût du test en profitant de la reconfigurabilité de la plateforme. Pour les radios tactiques qui doivent être mises à jour sur le terrain sans équipement spécial, les stratégies Built-In Self-Test (BIST) sont, sans doute, la seule moyenne de garantir la conformité aux spécifications. Dans cette mémoire, nous introduisons une nouvelle architecture de test RF BIST qui utilise la technique de de sous-échantillonnage nonuniform à la sortie de l’émetteur (TX) d’une SDR afin d’évaluer la conformité de la masque spectrale. Notre solution s’appuie sur une implémentation autonome, est modulable et peut être appliquée pour le test sur le terrain avec des modifications minimes. Par rapport aux autres techniques de test analogiques/RF, cet approche ne dépends pas de la architecture du TX, ni d’un modèle ad-hoc, ce qui est idéale pour le test des SDRs. / The advent of increasingly powerful Integrated Circuits (IC) has led to the emergence of the Software Defined Radio (SDR) concept, which brought the sector of secured mobile communications into a new era. The outstanding performance of these systems results from optimal trade-offs among advanced analog/Radio Frequency (RF) circuitry, high-speed reconfigurable digital hardware and sophisticated real-time software. The inherent sophistication of such platforms poses a challenging problem for product testing. Currently deployed industrial test strategies face rising obstacles due to the costlier RF test equipment, longer test time and lack of flexibility. Moreover, an SDR platform is field-upgradeable, which means it will support standards and scenarii not considered during the design phase. Therefore, an in-field test strategy is not anymore 'a nice to have' feature but a mandatory requirement. In this context, our research aims to invent and develop a new test methodology able to guarantee the correct functioning of the SDR platform post-fabrication and over its operational lifetime. The overall aim of our efforts is to reduce post-manufacture test cost of SDR transceivers by leveraging the reconfigurability of the platform.For tactical radio units that must be field-upgradeable without specialized equipment, Built-in Self-Test (BIST) schemes are arguably the only way to ensure continued compliance to specifications. In this study we introduce a novel RF BIST architecture which uses Periodically Nonuniform Sampling (PNS2) of the transmitter (TX) output to evaluate compliance to spectral mask specifications. Our solution supports a stand-alone implementation, is scalable across a wide set of complex specifications and can be easily applied for in-field testing with small added hardware. Compared to existing analog/RF test techniques, this approach is not limited to a given TX architecture and does not rely on an ad-hoc TX model, which makes it ideal for SDR testing.

RF BIST

Test analogique mixt/RF

Test sur terrain

Radio logicielle

SDR

Sous-échantillonnage

RF BIST

Mixed-Signal/RF Test

In-Field Test

Software Radios

SDR

Periodically Nonuniform Sampling

Subsampling

378.242