A Remote Electricity Billing System

Electric power distribution is the most valuable part of electrical power system in the process of delivering electricity to consumer. Electric power companies are now-a-days adopting some advanced systems such as computer aided monitoring control and management of electric power, so that it can provide better services to electric consumers. This project results an approach to automate the electricity billing system. The concept of prepaid is one of the emerging fields for the paid service providers. The concept is becoming so popular because it has so many advantages. The services like electricity, gas, water telephone etc are now days get privatized. The service provider company some time incurs heavy losses due to non collection of bills. These service items cannot be recovered from the user after providing, so the concept of prepaid reduce risk and increase profitability. Also the bill collection infrastructure is not necessary which intern increase improve the efficiency of the service providing companies. The concept of prepaid starts in the manual form by receiving advance deposits but now due to the revolution of IT and electronics industry the manual recharging process is replaced with automatic and electronic recharging. The recharging methods can be with wire based like telephone line and also by using wireless technology like radio and bluetooth communication. The prepaid system is designed with a smart technology using microcontroller and the recharging process is by some method of communication. The Mobile based recharging is very attractive recharging system. The recharging can be done from any remote place without accessing the energy meter physically. This concept of remote charging makes the system more flexible

Power management circuit: design and comparison of efficient techniques for ultra-low power analog switch and rectifier circuit

Dissertação de mestrado integrado em Engenharia Eletrónica Industrial e Computadores, Instrumentação e Microssistemas EletrónicosA presente dissertação de mestrado apresenta um estudo na área de CMOS em circuitos analógicos/digitais para extração e conversão de potência adequado para aplicações em energy harvesting. As principais contribuições científicas deste trabalho são: o desenvolvimento de circuitos de baixo consumo energético, tais como um interruptor analógico e um retificador que podem extrair e converter eficientemente a potência de saída do energy harvester. Com os dois circuitos apresentados na presente dissertação, é possível alimentar um nó de uma rede de sensores sem fios. Estes circuitos foram projetados utilizando a tecnologia CMOS de 130 nm e as respetivas simulações foram realizadas utilizando o software Cadence Virtuoso Analog Environment. Neste trabalho projetou-se novo interruptor analógico para aplicações em energy harvesting com especial atenção para a obtenção de um baixo consumo energético. A configuração apresentada consegue atingir uma baixa resistência, quando em condução (ON), e evitar correntes reversas indesejadas provenientes da carga. Os resultados das simulações revelam que o circuito: consome uma potência de 200.8 nW; atinge uma baixa resistência, quando em condução, de 216 Ω; gera uma baixa corrente de fuga de 44 pA. Assim sendo, é possível verificar que este circuito consegue operar com um baixo consumo, baixa tensão e com uma baixa frequência. Para além disso, o mesmo interruptor analógico consegue realizar a técnica de up-conversion dentro do circuito de controlo de potência, o que indica a possibilidade de o mesmo contribuir para uma aplicação real com energy harvesters vibracionais. O retificador em CMOS proposto é constituído por dois estágios: um passivo com um conversor de tensão negativa; e um outro estágio com um díodo ativo controlado por um circuito de cancelamento de threshold. O primeiro estágio é responsável por retificar completamente o sinal de entrada com uma queda de tensão de 1 mV, enquanto que o último tem a função de reduzir a corrente reversa indesejada, o que consequentemente consegue aumentar a potência transferida para a carga. Deste modo, o circuito consegue atingir uma eficiência em tensão e potência de 99 % e 90%, respetivamente, para um sinal de entrada com 0.45 V de amplitude e para cargas resistivas de valor baixo. Ainda assim, este circuito consegue funcionar a uma banda de frequências desde os 800 Hz até 51.2 kHz, o que se revela ser promissor para a aplicação prática deste projeto.The master dissertation presents a study in the area of mixed analog/digital CMOS power extraction and conversion circuits for Power Management Circuit (PMC) suitable for energy harvesting applications. The main contributions of the work are the development of low power circuits, such as an Analog Switch and a Rectifier, that can efficiently extract and convert the output power of the vibrational energy harvester into suitable electric energy for powering a Wireless Sensor Network (WSN) node. The circuit components were fully designed in the standard 130 nm CMOS process, and the respective simulation experiments were carried out using the Cadence Virtuoso Analog Environment. A new Analog Switch was designed for energy harvesting applications with special consideration for achieving low power consumption. The proposed structure can achieve a reduced ON-resistance and avoid the reverse leakage current from the load. Simulation results reveal a power consumption of about 200.8 nW, a low ON-resistance of 244.6 Ω, and a low leakage current of around 44 pA, which indicates that the analog switch has features of low power consumption, low voltage, and low-frequency operation. Furthermore, this switching circuit is suitable for performing the up-conversion technique in the PMC, which may contribute to the real application of vibrational energy harvesters. The proposed CMOS Rectifier consists of two stages, one passive stage with a negative voltage converter, and another stage with an active diode controlled by a threshold cancellation circuit. The former stage conducts the signal full-wave rectification with a voltage drop of 1 mV while the latter reduces the reverse leakage current, consequently enhancing the output power delivered to the ohmic load. As a result, the rectifier can achieve a voltage and a power conversion efficiency of over 99 % and 90 %, respectively, for an input voltage of 0.45 V and low ohmic loads. This circuit works for an operating frequency range from 800 Hz to 51.2 kHz, which is promising for practical applications

A long-range and long-life telemetry data-acquisition system for heart rate and multiple body temperatures from free-ranging animals

The system includes an implantable transmitter, external receiver-retransmitter collar, and a microprocessor-controlled demodulator. The size of the implant is suitable for animals with body weights of a few kilograms or more; further size reduction of the implant is possible. The ECG is sensed by electrodes designed for internal telemetry and to reduce movement artifacts. The R-wave characteristics are then specifically selected to trigger a short radio frequency pulse. Temperatures are sensed at desired locations by thermistors and then, based on a heartbeat counter, transmitted intermittently via pulse interval modulation. This modulation scheme includes first and last calibration intervals for a reference by ratios with the temperature intervals to achieve good accuracy even over long periods. Pulse duration and pulse sequencing are used to discriminate between heart rate and temperature pulses as well as RF interference

Mixed Signal Integrated Circuit Design for Custom Sensor Interfacing

Low-power analog integrated circuits (ICs) can be utilized at the interface between an analog sensor and a digital system\u27s input to decrease power consumption, increase system accuracy, perform signal processing, and make the necessary adjustments for compatibility between the two devices. This interfacing has typically been done with custom integrated solutions, but advancements in floating-gate technologies have made reconfigurable analog ICs a competitive option. Whether the solution is a custom design or built from a reconfigurable system, digital peripheral circuits are needed to configure their operation for these analog circuits to work with the best accuracy.;Using an analog IC as a front end signal processor between an analog sensor and wireless sensor mote can greatly decrease battery consumption. Processing in the digital domain requires more power than when done on an analog system. An Analog Signal Processor (ASP) can allow the digital wireless mote to remain in sleep mode while the ASP is always listening for an important event. Once this event occurs, the ASP will wake the wireless mote, allowing it to record the event and send radio transmissions if necessary. As most wireless sensor networks employ the use of batteries as a power source, an energy harvesting system in addition to an ASP can be used to further supplement this battery consumption.;This thesis documents the development of mixed-signal integrated circuits for use as interfaces between analog sensors and digital Wireless Sensor Networks (WSNs). The following work outlines, as well as shows the results, of development for sensor interfacing utilizing both custom mixed signal integrated circuits as well as a Field Programmable Analog Array (FPAA) for post fabrication customization. An Analog Signal Processor (ASP) has been used in an Acoustic Vehicle Classification system. To keep these interfacing methods low power, a prototype energy harvesting system using commercial-off-the-shelf (COTS) devices is detailed which has led to the design of a fully integrated solution

Analog Violin Audio Synthesizer

Abstract In the past decade, music electronics have almost completely shifted from analog to digital technology. Digital keyboards and effects provide more sound capabilities than their analog predecessors, while also reducing size and cost. However, many musicians still prefer analog instruments due to the perception that they produce superior sound quality. Many musicians spend extra money and accommodate the extra space required for analog technologies instead of digital. Furthermore, audio synthesizers are commonly controlled with the standard piano keyboard interface. Many musicians can perform sufficiently on a keyboard, but requiring a specific skill set limits the size of the market for a product. Also, when reproducing instruments such as a violin, a keyboard will not suffice in simulating a controllable vibrato from a fretless fingerboard. There is a need for an interface that allows the user to successfully reproduce the sound of the desired instrument. The violin is just one example of instruments that cannot be completely reproduced on a keyboard. For example, cellos, trombones and slide guitars all have features that a keyboard cannot simulate in real time. The Analog Violin Synthesizer uses oscillators and analog technology to reproduce the sound of a violin. The user controls the synthesizer with a continuous touch sensor, representing the fretless violin fingerboard. The continuous interface allows for a violin sound played as a standard note, or a warmer sound with adjustable vibrato, based on how the user moves his or her hand. This product provides an innovation and next step to the use of analog technology in sound synthesis. However, as digital technology continues to improve, this product could potentially cross over into digital, with the continued use of the touch interface. Currently, there are products that utilize touch input, however they are often used for sound effects, and atmospheric sounds. Rarely are they used to allow for the digital playability of a synthesized acoustic instrument

Rectification, amplification and switching capabilities for energy harvesting systems: power management circuit for piezoelectric energy harvester

Dissertação de mestrado em Biomedical EngineeringA new energy mechanism needs to be addressed to overcome the battery dependency, and consequently extend Wireless Sensor Nodes (WSN) lifetime effectively. Energy Harvesting is a promising technology that can fulfill that premise. This work consists of the realization of circuit components employable in a management system for a piezoelectric-based energy harvester, with low power consumption and high efficiency. The implementation of energy harvesting systems is necessary to power-up front-end applications without any battery. The input power and voltage levels generated by the piezoelectric transducer are relatively low, especially in small-scale systems, as such extra care has to be taken in power consumption and efficiency of the circuits. The main contribution of this work is a system capable of amplifying, rectifying and switching the unstable signal from an energy harvester source. The circuit components are designed based on 0.13 Complementary Metal-Oxide-Semiconductor (CMOS) technology. An analog switch, capable of driving the harvesting circuit at a frequency between 1 and 1 , with proper temperature behaviour, is designed and verified. An OFF resistance of 520.6 Ω and isolation of −111.24 , grant excellent isolation to the circuit. The designed voltage amplifier is capable of amplifying a minor signal with a gain of 42.56 , while requiring low power consumption. The output signal is satisfactorily amplified with a reduced offset voltage of 8 . A new architecture of a two-stage active rectifier is proposed. The power conversion efficiency is 40.4%, with a voltage efficiency of up to 90%. Low power consumption of 17.7 is achieved by the rectifier, with the embedded comparator consuming 113.9 . The outcomes validate the circuit’s power demands, which can be used for other similar applications in biomedical, industrial, and commercial fields.Para combater a dependência dos dispositivos eletrónicos relativamente ás baterias é necessário um novo sistema energético, que permita prolongar o tempo de vida útil dos mesmos. Energy Harvesting é uma tecnologia promissora utilizada para alimentar dispositivos sem bateria. Este trabalho consiste na realização de componentes empregáveis num circuito global para extrair energia a partir ds vibrações de um piezoelétricos com baixo consumo de energia e alta eficiência. Os níveis de potência e voltagem gerados pelo transdutor piezoelétrico são relativamente baixos, especialmente em sistemas de pequena escala, por isso requerem cuidado extra relativamente ao consumo de energia e eficiência dos circuitos. A principal contribuição deste trabalho é um sistema apropriado para amplificar, retificar e alternar o sinal instável proveniente de uma fonte de energy harvesting. Os componentes do sistema são implementados com base na tecnologia CMOS com 0.13 . Um interruptor analógico capaz de modelar a frequência do sinal entre 1 e 1 e estável perante variações de temperatura, é implementado. O circuito tem um excelente isolamento de −111.24 , devido a uma resistência OFF de 520.6 Ω. O amplificador implementado é apto a amplificar um pequeno sinal com um ganho de 42.56 e baixo consumo. O sinal de saída é satisfatoriamente amplificado com uma voltagem de offset de 8 . Um retificador ativo de dois estágios com uma nova arquitetura é proposto. A eficiência de conversão de energia atinge os 40.4%, com uma eficiência de voltagem até 90%. O retificador consome pouca energia, apenas 17.7 , incorporando um comparador de 113.9 . Os resultados validam as exigências energéticas do circuito, que pode ser usado para outras aplicações similares no campo biomédico, industrial e comercial

An international comparison of phase angle standards between the novel impedance bridges of CMI, INRIM and METAS

We report here the results of a comparison of electrical impedance standards aimed at evaluating four novel digital impedance bridges developed by the national metrology institutes CMI, INRIM and METAS. This comparison, which is the first of its kind, involved phase angle impedance standards developed by TÜBITAK UME with phase angles of  ± 30° and  ± 60°, and magnitudes ranging from about 100 Ω to 1 MΩ. The comparison demonstrated agreement among the measurement results obtained with the different bridges, and allowed us to gather information on the stability of the phase standards and on more critical aspects related to the characterization of the bridges