Global ETD Search

1	Programmerbar signalanpassning Jansson, Patrick January 2001 (has links) The data acquisition system COMET developed by Saab AB contains a unit for signal conditioning and A/D conversion, called KSM. The varieties in signal conditioning constitutes of a number of specific PBAs and maintenance as well as reconfiguration of these are complicated not to mention costly. This thesis has aimed to investigating whether the signal conditioning circuits can be replaced by a general purpose, programmable solution. If so, how can this be done? The development has been carried out by evaluating ideas through the use of a laboratory environment and has resulted in an analog design for laboratory purpose. A reconfigurable design is the result of this thesis as an alternative to the solution used today. In the proposed design mainly digital otentiometers, switches and MUXes are used. In that way signal path and overall behaviour can be selected. Some extensions have been made in comparison to the current functionality, but additional development is necessary to make the design complete. Future versions of the COMET system could be significantly improved by considering the result of this thesis when developing the signal conditioning circuitry. Electronics Signalanpassning Bryggkomplettering Digital potentiometer MUX Switch Elektronik Electronics Elektronik
2	Programmerbar signalanpassning Jansson, Patrick January 2001 (has links) <p>The data acquisition system COMET developed by Saab AB contains a unit for signal conditioning and A/D conversion, called KSM. The varieties in signal conditioning constitutes of a number of specific PBAs and maintenance as well as reconfiguration of these are complicated not to mention costly. This thesis has aimed to investigating whether the signal conditioning circuits can be replaced by a general purpose, programmable solution. If so, how can this be done? </p><p>The development has been carried out by evaluating ideas through the use of a laboratory environment and has resulted in an analog design for laboratory purpose. A reconfigurable design is the result of this thesis as an alternative to the solution used today. In the proposed design mainly digital otentiometers, switches and MUXes are used. In that way signal path and overall behaviour can be selected. Some extensions have been made in comparison to the current functionality, but additional development is necessary to make the design complete. </p><p>Future versions of the COMET system could be significantly improved by considering the result of this thesis when developing the signal conditioning circuitry.</p> Electronics Signalanpassning Bryggkomplettering Digital potentiometer MUX Switch Elektronik Electronics Elektronik
3	Development of a Digital Potentiometer Circuit for Digital Compensation of Frequency and Temperature Variations of Kvco to Provide Reprogramming of the Transmitter RF Center Frequency in the Field Oder, Stephen, St. Gelais, Robert, Caron, Peter, Bajgot, Douglas 10 1900 (has links) ITC/USA 2013 Conference Proceedings / The Forty-Ninth Annual International Telemetering Conference and Technical Exhibition / October 21-24, 2013 / Bally's Hotel & Convention Center, Las Vegas, NV / Cobham Electronic Systems, Inc. has developed a digital potentiometer circuit to allow for digital compensation of frequency and temperature variations in the VCO/PLL frequency control loop of a telemetry transmitter. The ability to reprogram the RF center frequency of a telemetry transmitter is a useful feature and is required on many telemetry programs. When setting the frequency modulation deviation (FM Modulation Index) of a telemetry transmitter, the exact setting will change with RF center frequency due to the variation of the transfer function of the VCO (Kvco). Typically, a resistor divider is used to set the frequency modulation deviation level by setting the output data signal amplitude. However, since Kvco varies with respect to RF center frequency, a method of adjusting frequency modulation deviation for each frequency setting is required. The shunt resistor in the resistor divider is replaced with a digital potentiometer to provide the necessary adjustment, using the on-board microprocessor to store a look-up table of settings versus frequency. A key feature of the digital potentiometer circuit is a method to increase the frequency bandwidth of the potentiometer. Digital potentiometers typically have frequency bandwidths measured in kiloHertz to MegaHertz, which limits their use in setting the frequency modulation deviation of high data rate telemetry transmitters. The circuit consists of a 256 position digital potentiometer and several resistors that are used to adjust the slope of the resistance vs. digital code curve and to translate the curve up and down along the Y-Axis. Adding external resistors to the digital potentiometer helps to increase the frequency bandwidth of the digital potentiometer. The selection of the maximum resistance range of the digital potentiometer is also important, as the potentiometer bandwidth is greater when a small portion of the total resistance is used. This paper will explore various methods of increasing the effective bandwidth of a digital potentiometer, with the goal of making them suitable for use in dynamically setting the frequency modulation deviation via digital control. Transmitter Frequency Modulation Deviation Digital Potentiometer Increased Bandwidth
4	Methods to simulate resistance at high resolution and accuracy Jansson, Ola January 2021 (has links) In this paper, four methods to simulate or generate electric resistance at high resolution have been developed, tested and evaluated. Each method is called a Resistor Simulator and are numbered from one to four. Resistor Simulator one is based upon a set of digital potentiometers configured to achieve increased performance over a single 8-bit potentiometer. There were many issues with calibration and control over the individual potentiometers leading to a decent but uneven characteristic. Resistor Simulator two tests the setup of an encapsulated LED a photoresistor pair where output resistance is controlled by the light output of the current controlled LED. Although the output was purely resistive, and the resistance was controllable. This method has big issues with non-linearity and very poor repetitivity were the same input could give resistances several kiloOhms apart. Resistor Simulator three uses an ADC in combination with a DAC to measure the current going through the simulator over a shunt-resistor and regulate the voltage output to match the voltage-drop that the set resistance would generate. There were some issues with working in the extreme ends of the analog electronics in the circuit limiting how low currents that could be properly measured. This problem could be bypassed to evaluate the rest of the system with good results. The limiting factor of the simulator was the resolution of the DAC at high resistances. Resistor Simulator four was the largest and costliest of them all, but performance was also the best. It is built as a resistance ladder with a set of 16 binary matched resistors and bypass switches for each resistance. This way, output resistance is set just like a binary number. The performance of the simulator was equally good throughout the entire resistance span. The only thing that limited performance from great to good was that it was hard to get precisely matched resistors of odd values and low tolerance making for some deviation from the theoretical resistances. All four resistance simulators were realized on a single Arduino shield PCB, designed with Altium Designer and assembled by the student. Although an Arduino was used for this project, any microcontroller could be used as all communication with the PCB is done via SPI. Resistance performance was evaluated with an automated test system for inaccuracy, resolution and repetitivity. Furthermore, practicality parameters such as size and cost were evaluated to further determine the suitability of each resistor simulator. The outcome from this work is intended to be used as basis to design systems for test and evaluation of alarm systems. / Denna rapport beskriver fyra metoder för att simulera eller generera elektisk resistans med hög upplösning och noggrannhet. Metoderna har identifierats, utvecklats, testats och utvärderats. Varje metod benämns som en Resistor Simulator och är numrerade från ett till fyra. Resistor Simulator ett bygger på en uppsättning av digitala potentiometrar konfigurerade i en krets för att utöka dess upplösning och prestanda jämfört med en enkel 8-bitars potentiometer. Dock så stöttes en hel del problem på i samband med kalibrering och styrning av de individuella potentiometrarna med hyffsad men ojämn karaktäristik. Resistor Simulator två utvärderar konceptet med en inkapslad LED och fotoresistor där resistansen styrs genom att kontrollera ljusflödet med strömstyrning av dioden. Denna lösning var den enda med rent resistiv utgång och resistansen var kontrollerbar. Dock så har metoden stora problem med icke-linjärt beteende och variationer mellan test där samma styrsignal kan ge resistanser flera kiloOhm från varandra. Resistor Simulator tre använder en ADC tillsammans med en DAC för att mäta strömmen genom simulatorn och reglera spänningen för att motsvara det spänningsfall som den valda resistansen skulle generera. Denna lösning stötte på en del problem med för höga spänningsnivåer på den analoga elektronik som användes vilket begränsade hur låga strömmar som kunde mätas. Detta problem kunde förbigås för att utvärdera resten av systemet med goda resultat. Den begränsande faktorn för simulatorns upplösning låg dock i upplösningen på DAC vid höga resistanser. Resistor Simulator fyra var den största och dyraste av dem alla, men också den som presterade bäst. Den är byggd som en resistorstege med en uppsättning av 16 binärt matchade resistorer som alla försetts med en kortslutande styrbar brytare vilket gör att resistans kan beräknas på samma sätt som ett binärtal räknas. Prestandan var genomgående bra i hela mätområdet med enda baksida att det var svårt att införskaffa resistorer av udda värden med mycket låga toleranser varav mindre avvikelser från den teoretiska upplösningen uppkom. Alla simulatorer realiserades på ett tilläggskort till en Arduino som designats med Altium Designer och byggdes ihop av studenten. Även om en Arduino användes för just detta projekt skulle vilken annan mikrokontroller kunna användas då all kommunikation på kretskortet sker via SPI. Prestandan av simulerad resistans testades med ett automatiskt testsystem och utvärderades för onoggrannhet, upplösning och repeterbarhet. Utöver detta utvärderades praktiska parametrar som storlek och materialkostnad för att kunna utvärdera i vilka sammanhang respektive simulator passar bäst till. Utfallet från detta arbete avser att ligga till grund för utveckling av utrustning för test och utvärdering av larmsystem. variable resistance digital potentiometer potentiometer simulate resistance variabel resistans digital potentiometer potentiometer simulera resistans Annan elektroteknik och elektronik
5	Implementering av ett parameteriserbart aktivt vågfilter / Implementation of a parameterized wave active filter Gustafsson, Helena January 2003 (has links) <p>Detta examensarbete gick ut på att försöka hitta ett sätt att mäta kompo nentkänslighet hos parameteriserbara aktiva vågfilter. Två olika ansatser har gjorts, men bara ett försök har avslutats. </p><p>Det första försöket behandlar möjligheten att realisera ett vågfilter med hjälp av standardkomponenter i en kretskortslösning. Detta fungerade inte beroende på att nödvändiga komponenter inte finns på marknaden idag. Komponenterna som finns har för stora parasitkapacitanser. Dessa oönskade parasiter var så stora att de skulle kunna förstöra funktionen och det var således inte värt att fortsätta försöket. De komponenter som undersöktes var resistansstegar och digitala potentiometrar. Den största delen av studierna till det första försöket har bestått i att studera datablad från olika kretstillverkare för att hitta lämpliga komponenter. </p><p>Istället startades ett nytt försök som syftade till att undersöka möjligheten att implementera ett aktivt vågfilter i en integrerad krets. I denna rapport presenteras en förstudie till hur en sådan lösning skulle kunna se ut. För att möjliggöra en fortsättning där mitt examensarbete tar slut har arbetet förklarats ingående. Jag har också inkluderat min programkod som bilagor i slutet av rapporten.</p> / <p>The purpose of this thesis was to find a way of measuring the sensitivity of component values for parameterized wave active filters. Two different approaches were made, but only one was finished. </p><p>The first approach is about the possibility of making a wave active filter with standard components on a printed circuit board. This did not work though, because of a scarce market of possible components. The compo-nents existing today have too high parasite capacitances. These unwanted parasites are so large in value that they could destroy the functionality and it was therefore not worth continuing the attempt. The components that were investigated as possible on the board were ladder networks and digitally controlled potentiometers. The main part of the studies for the first attempt was to read data sheets from different electronic companies trying to find possible components. </p><p>Instead a new approach was made with the purpose of investigating the possibility of making a wave active filter as an integrated circuit. In this report a pilot study for such an attempt is presented. To make it possible to continue work where these studies end, the work has been carefully explained. I have also included the computer programs I have made in the appendix of the report.</p> Electronics aktivt vågfilter digital potentiometer resistansstege Cauer parameteriserbar ASIC Elektronik Electronics Elektronik
6	Implementering av ett parameteriserbart aktivt vågfilter / Implementation of a parameterized wave active filter Gustafsson, Helena January 2003 (has links) Detta examensarbete gick ut på att försöka hitta ett sätt att mäta kompo nentkänslighet hos parameteriserbara aktiva vågfilter. Två olika ansatser har gjorts, men bara ett försök har avslutats. Det första försöket behandlar möjligheten att realisera ett vågfilter med hjälp av standardkomponenter i en kretskortslösning. Detta fungerade inte beroende på att nödvändiga komponenter inte finns på marknaden idag. Komponenterna som finns har för stora parasitkapacitanser. Dessa oönskade parasiter var så stora att de skulle kunna förstöra funktionen och det var således inte värt att fortsätta försöket. De komponenter som undersöktes var resistansstegar och digitala potentiometrar. Den största delen av studierna till det första försöket har bestått i att studera datablad från olika kretstillverkare för att hitta lämpliga komponenter. Istället startades ett nytt försök som syftade till att undersöka möjligheten att implementera ett aktivt vågfilter i en integrerad krets. I denna rapport presenteras en förstudie till hur en sådan lösning skulle kunna se ut. För att möjliggöra en fortsättning där mitt examensarbete tar slut har arbetet förklarats ingående. Jag har också inkluderat min programkod som bilagor i slutet av rapporten. / The purpose of this thesis was to find a way of measuring the sensitivity of component values for parameterized wave active filters. Two different approaches were made, but only one was finished. The first approach is about the possibility of making a wave active filter with standard components on a printed circuit board. This did not work though, because of a scarce market of possible components. The compo-nents existing today have too high parasite capacitances. These unwanted parasites are so large in value that they could destroy the functionality and it was therefore not worth continuing the attempt. The components that were investigated as possible on the board were ladder networks and digitally controlled potentiometers. The main part of the studies for the first attempt was to read data sheets from different electronic companies trying to find possible components. Instead a new approach was made with the purpose of investigating the possibility of making a wave active filter as an integrated circuit. In this report a pilot study for such an attempt is presented. To make it possible to continue work where these studies end, the work has been carefully explained. I have also included the computer programs I have made in the appendix of the report. Electronics aktivt vågfilter digital potentiometer resistansstege Cauer parameteriserbar ASIC Elektronik Electronics Elektronik
7	Vision for the Blind Atighechi, Arsham, Haidari, Hussein January 2018 (has links) How can we improve the living standards of the visuallyimpaired using an Arduino?Living with visual impairment could potentially be oneof the hardest things one could do. Constantly having toworry about obstacles and carrying a stick to feel your wayforward. In order to combat this difficulty, we have designedVision for the Blind.One of the usages of ultrasonic sensors are to measurethe distance from objects using sound waves. These sensors,in combination with Piezo buzzers, have been used inVision for the Blind to warn the user of incoming obstaclesby emitting sound from the buzzers. The volume of thebuzzers is controlled by using a digital potentiometer andvaries depending on the measured distance. All three areconnected to an Arduino which has been coded to performthe given task. / Hur kan vi öka levnadsstandarden för visuellt nedsattamänniskor med hjälp av en Arduino?Att leva med visuell nedsättning är självklart ett stortproblem som medför svårigheter, att alltid vara orolig överhinder som kan finnas i vägen eller bära en pinne med sigför att hitta sin väg. För att bekämpa de här svårigheternahar vi konstruerat Vision for the Blind.Ultraljudsbaserade sensorer använder ljudvågor för attmäta avstånd från ett objekt. Dessa sensorer har använtsi Vision for the Blind i kombination med Piezo sumrarför att varna användaren om inkommande hinder genomatt emittera ljud från sumrarna. Ljudvolymen kontrollerasmed hjälp av en digital potentiometer och varierar med detuppmätta avståndet. Alla tre är kopplade till en Arduinosom är kodad för att utföra det givna uppdraget. Mechatronics ultrasound sensors buzzers distance measurement digital potentiometer Mechanical Engineering Maskinteknik
8	A General Purpose Analog Circuit to Accumulate Data From Resistive Sensors Höjlund, Karl, Alhallak, Alan January 2022 (has links) Minimizing the need to physically adjust hardware platforms used for sensor measurements during the construction phase of an electric vehicle can be beneficial. Since different sensors have different measuring ranges a hardware platform used for a specific sensor might not work for another one, without physically tampering with it. One way to solve such an issue is to build a general hardware platform that can be adjusted digitally through software to match the range of a variety of sensors. In this thesis, the implementation of a prototype General Purpose Data Acquisition Unit has been investigated. The design consists of a Wheatstone bridge implementation for measurements with resistive sensors, due to its capabilities of accurate detection of small changes in resistance. Digital potentiometers were implemented in the design to add dynamic capabilities for calibration and measurements with different types of resistive sensors through software. The proposed implementation has been tested on a prefboard and built on a Printed Circuit Board. Further testing is required to better specify and evaluate the proposed implementation. / Att minimera behovet av att fysiskt justera hårdvaruplattformar för mätningsprocessorer med sensorer vid tillverkning av en elektriskt driven bil kan vara fördelaktigt. Olika sensorer har olika mätområden och en hårdvaruplattform kan fungera väl för en sensor men inte nödvändigtvis för en annan utan att hårdvaran fysiskt behöver justeras. Ett sätt att lösa detta problem är att utveckla en generell hårdvaruplattform för insamling av data från sensorer som digitalt kan anpassas för att fungera med ett större utbud av sensorer. I denna rapport har en implementering av en generell hårdvaruplattform för datainsamling undersökts. Implementationen består av en konfiguration av en Wheatstone brygga för resisitiva sensorer, på grund av dess förmåga att noggrant mäta små förändringar av resistans. Digitala potentiometrar användes i implementeringen för att ge möjligheten till att dynamiskt kunna kalibrera och mäta data från olika typer av resistiva sensorer genom mjukvara. Den förslagna implementationen har genomfört ett test på en perfboard och monterats på ett kretskort. Fler tester krävs för att bättre kunna specificera och evaluera den förslagna implementationen. / Kandidatexjobb i elektroteknik 2022, KTH, Stockholm Data acquisition Wheatstone bridge Analog conditioning Digital potentiometer Elektroteknik och elektronik
9	Kmitočtové filtry řízené mikroprocesory / Frequency filters controlled via microprocessors Bronec, David January 2015 (has links) This thesis is focused on the microprocessor-controlled frequency filter project. The main goal of the thesis is to present basic terms and principles of frequency filters and active frequency filters for cascading synthesis. Furthermore, the work contains information on digital potentiometers. The thesis includes circuit simulations and a project of connecting with a printed circuit board. The last chapter contains the results of the measurements.
10	Elektronicky řiditelný aktivní filtr 2. řádu / Electronically controlled active 2-nd order filter Ševčík, Břetislav January 2009 (has links) The diploma thesis deals with the modern design of the control circuits for digital potentiometers and their application in analog systems. The concept of the digital control is demonstrated on the electronically controlled active 2-nd order filter and programmable oscillator. The proposed design of the active filter describes a programmable active 2-nd order filter Sallen-Key. In this circuit it is possible independently programme cut-off frequency, Q factor and type of approximation with very good accuracy. The circuits of the designed filter and designed oscillator are simulated in PSpice (OrCAD), parasite effects and effects of the real parts are studied. Properties simulated circuits are compare with experimental results. These results appreciate quality and efficiency of the digitally controlled potentiometers in dependence on variable input circuit parameters. Integral part of this project is author’s universal control program called Digipot and comunications interface for many types of digital potentiometers with I2C, SPI or Up/Down interface. It is possible to use this device for many applications. The constructional details of the filter are presented at the end of this work. The software equipment is availability on enclosed CD.

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