14-11-2015, 06:48 PM
hello
please can you post the ppt of the ppt of this topic
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ppt presentation of wireless battery charger using microwaves rf to dc conversion
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hello
please can you post the ppt of the ppt of this topic
16-11-2015, 02:36 PM
ppt presentation of wireless battery charger using microwaves rf to dc conversion
Battery life of mobile phone is always been a problem for manufacturers. People are complaining about their mobile’s battery life, that they don’t have long battery life and they have to charge their phone several times. Portable electronic devices are very popular nowadays. As the usage of these portable electronic devices is increasing, the demands for longer battery life are also increasing. These batteries need to be recharged or replaced periodically. It is a hassle to charge or change the battery after a while, especially when there is no power outlet around. This wireless battery charger is expected to eliminate all the hassles with today’s battery technology. The advantage of this device is that it can wirelessly charge up the batteries which can save time and money in a long run for the general public. prototype device that converts microwave signals to DC power. Once the prototype has been proved to be working, it is possible to implement this prototype into other applications such as in television remote control, fire alarm, clock, and places that are far to reach to change battery.
RF energy is currently broadcasted from billions of radio transmitters around the world, including mobile telephones, handheld radios, mobile base stations, and television/ radio broadcast stations. The ability to harvest RF energy, from ambient or dedicated sources, enables wireless charging of low-power devices and has resulting benefits to product design, usability, and reliability. Battery-based systems can be trickled charged to eliminate battery replacement or extend the operating life of systems using disposable batteries. Battery-free devices can be designed to operate upon demand or when sufficient charge is accumulated. In both cases, these devices can be free of connectors, cables, and battery access panels, and have freedom of placement and mobility during charging and usage.
Energy Sources
The obvious appeal of harvesting ambient RF energy is that it is essentially “free” energy. The number of radio transmitters, especially for mobile base stations and handsets, continues to increase. ABI Research and iSupply estimate the number of mobile phone subscriptions has recently surpassed 5 billion, and the ITU estimates there are over 1 billion subscriptions for mobile broadband. Mobile phones represent a large source of transmitters from which to harvest RF energy, and will potentially enable users to provide power-on-demand for a variety of close range sensing applications. Also, consider the number of WiFi routers and wireless end devices such as laptops. In some urban environments, it is possible to literally detect hundreds of WiFi access points from a single location. At short range, such as within the same room, it is possible to harvest a tiny amount of energy from a typical WiFi router transmitting at a power level of 50 to 100 mW. For longer-range operation, larger antennas with higher gain are needed for practical harvesting of RF energy from mobile base stations and broadcast radio towers. In 2005, Powercast demonstrated ambient RF energy harvesting at 1.5 miles (~2.4 km) from a small, 5-kW AM radio station.
RF energy can be broadcasted in unlicensed bands such as 868MHz, 915MHz, 2.4GHz, and 5.8GHz when more power or more predictable energy is needed than what is available from ambient sources. At 915MHz, government regulations limit the output power of radios using unlicensed frequency bands to 4W effective isotropic radiated power (EIRP), as in the case of radio-frequency- identification (RFID) interrogators. As a comparison, earlier generations of mobile phones based on analog technology had maximum transmission power of 3.6W, and Powercast’s TX91501 transmitter that sends power and data is 3W.
RF Harvesting Receivers
RF energy harvesting devices, such as Powercast’s Powerharvester® receivers, convert RF energy into DC power. These components are easily added to circuit board designs and work with standard or custom 50-ohm antennas. With current RF sensitivity of the P2110 Powerharvester receiver at -11dBm, powering devices or charging batteries at distances of 40-45 feet from a 3W transmitter is easily achieved and can be verified with Powercast’s development kits. Improving the RF sensitivity allows for RF-to-DC power conversion at greater distances from an RF energy source. However, as the range increases the available power and rate of charge decreases.
An important performance aspect of an RF energy harvester is the ability to maintain RF-to-DC conversion efficiency over a wide range of operating conditions, including variations of input power and output load resistance. For example, Powercast’s RF energy-harvesting components do not require additional energy-consuming circuitry for maximum power point tracking (MPPT) as is required with other energy-harvesting technologies. Powercast’s components maintain high RF-to-DC conversion efficiency over a wide operating range that enables scalability across applications and devices. RF energy-harvesting circuits that can accommodate multi-band or wideband frequency ranges, and automatic frequency tuning, will further increase the power output, potentially expand mobility options, and simplify installation.
Typical Applications
RF energy can be used to charge or operate a wide range of low-power devices. At close range to a low-power transmitter, this energy can be used to trickle charge a number of devices including GPS or RLTS tracking tags, wearable medical sensors, and consumer electronics such as e-book readers and headsets. At longer range the power can be used for battery-based or battery-free remote sensors for HVAC control and building automation, structural monitoring, and industrial control. Depending on the power requirements and system operation, power can be sent continuously, on a scheduled basis, or on-demand. In large-scale sensors deployments significant labor cost avoidance is possible by eliminating the future maintenance efforts to replace batteries.
Available power from a 3W transmitter will be low milliwatts within a few feet and tens of microwatts at around 40 feet. This amount of power is best used for devices with low-power consumption and long or frequent charge cycles. Typically, devices that operate for weeks, months, or years on a single set of batteries are good candidates for being wirelessly recharged by RF energy. In some applications simply augmenting the battery life or offsetting the sleep current of a microcontroller is enough to justify adding RF-based wireless power and energy harvesting technology.
A network of transmitters can be positioned in a facility to provide wireless power on a room-by-room basis, or for a many-to-many charging topology. Mobile phones can be used as portable power sources for a number of battery-free wireless devices. Imagine a mobile phone powering a battery-less, body-worn sensor that sends data to the phone via a commonly used protocol such as Wi-Fi, Bluetooth, or ZigBee. This data can be displayed locally on the handset or transmitted by the phone to a monitoring service. Powercast has already demonstrated this application using ambient RF energy from an iPhone (see video to right).
Improved Product Design
Products with embedded wireless power technology can be sealed from environmental conditions such as moisture and from user access. In addition, connectors and cables can be eliminated. Product reliability and lifecycle can be significantly improved as a result. When in range of a suitable RF source, charging is automatic and transparent to the end-user which provides increased convenience of use. With Powercast’s components, multiple battery chemistries and charge voltages can be supported which allows for maximum power storage flexibility.
Conclusion
Ambient radio waves are universally present over an ever-increasing range of frequencies and power levels, especially in highly populated urban areas. These radio waves represent a unique and widely available source of energy if it can be effectively and efficiently harvested. The growing number of wireless transmitters is naturally resulting in increased RF power density and availability. Dedicated power transmitters further enable engineered and predictable wireless power solutions. With continued decreases in the power consumption of electronic components, increased sensitivity of passive receivers for RF harvesting, and improved performance of low-leakage energy storage devices, the applications for wire-free charging by means of RF-based wireless power and energy harvesting will continue to grow.
Harry Ostaffe is vice president, marketing & business development at Powercast. He has 20-plus years of experience in the fields of data communications and wireless networking, industrial controls, and computing. Before joining Powercast, Ostaffe held positions with Ericsson, Marconi, Lucent Technologies, AT&T Network Systems, Bayer, and IBM. He holds an MBA from Carnegie Mellon University and earned his BS in Electrical Engineering from Penn State University
Battery life of mobile phone is always been a problem for manufacturers. People are complaining about their mobile’s battery life, that they don’t have long battery life and they have to charge their phone several times. Portable electronic devices are very popular nowadays. As the usage of these portable electronic devices is increasing, the demands for longer battery life are also increasing. These batteries need to be recharged or replaced periodically. It is a hassle to charge or change the battery after a while, especially when there is no power outlet around. This wireless battery charger is expected to eliminate all the hassles with today’s battery technology. The advantage of this device is that it can wirelessly charge up the batteries which can save time and money in a long run for the general public. prototype device that converts microwave signals to DC power. Once the prototype has been proved to be working, it is possible to implement this prototype into other applications such as in television remote control, fire alarm, clock, and places that are far to reach to change battery.
RF energy is currently broadcasted from billions of radio transmitters around the world, including mobile telephones, handheld radios, mobile base stations, and television/ radio broadcast stations. The ability to harvest RF energy, from ambient or dedicated sources, enables wireless charging of low-power devices and has resulting benefits to product design, usability, and reliability. Battery-based systems can be trickled charged to eliminate battery replacement or extend the operating life of systems using disposable batteries. Battery-free devices can be designed to operate upon demand or when sufficient charge is accumulated. In both cases, these devices can be free of connectors, cables, and battery access panels, and have freedom of placement and mobility during charging and usage.
Energy Sources
The obvious appeal of harvesting ambient RF energy is that it is essentially “free” energy. The number of radio transmitters, especially for mobile base stations and handsets, continues to increase. ABI Research and iSupply estimate the number of mobile phone subscriptions has recently surpassed 5 billion, and the ITU estimates there are over 1 billion subscriptions for mobile broadband. Mobile phones represent a large source of transmitters from which to harvest RF energy, and will potentially enable users to provide power-on-demand for a variety of close range sensing applications. Also, consider the number of WiFi routers and wireless end devices such as laptops. In some urban environments, it is possible to literally detect hundreds of WiFi access points from a single location. At short range, such as within the same room, it is possible to harvest a tiny amount of energy from a typical WiFi router transmitting at a power level of 50 to 100 mW. For longer-range operation, larger antennas with higher gain are needed for practical harvesting of RF energy from mobile base stations and broadcast radio towers. In 2005, Powercast demonstrated ambient RF energy harvesting at 1.5 miles (~2.4 km) from a small, 5-kW AM radio station.
RF energy can be broadcasted in unlicensed bands such as 868MHz, 915MHz, 2.4GHz, and 5.8GHz when more power or more predictable energy is needed than what is available from ambient sources. At 915MHz, government regulations limit the output power of radios using unlicensed frequency bands to 4W effective isotropic radiated power (EIRP), as in the case of radio-frequency- identification (RFID) interrogators. As a comparison, earlier generations of mobile phones based on analog technology had maximum transmission power of 3.6W, and Powercast’s TX91501 transmitter that sends power and data is 3W.
RF Harvesting Receivers
RF energy harvesting devices, such as Powercast’s Powerharvester® receivers, convert RF energy into DC power. These components are easily added to circuit board designs and work with standard or custom 50-ohm antennas. With current RF sensitivity of the P2110 Powerharvester receiver at -11dBm, powering devices or charging batteries at distances of 40-45 feet from a 3W transmitter is easily achieved and can be verified with Powercast’s development kits. Improving the RF sensitivity allows for RF-to-DC power conversion at greater distances from an RF energy source. However, as the range increases the available power and rate of charge decreases.
An important performance aspect of an RF energy harvester is the ability to maintain RF-to-DC conversion efficiency over a wide range of operating conditions, including variations of input power and output load resistance. For example, Powercast’s RF energy-harvesting components do not require additional energy-consuming circuitry for maximum power point tracking (MPPT) as is required with other energy-harvesting technologies. Powercast’s components maintain high RF-to-DC conversion efficiency over a wide operating range that enables scalability across applications and devices. RF energy-harvesting circuits that can accommodate multi-band or wideband frequency ranges, and automatic frequency tuning, will further increase the power output, potentially expand mobility options, and simplify installation.
Typical Applications
RF energy can be used to charge or operate a wide range of low-power devices. At close range to a low-power transmitter, this energy can be used to trickle charge a number of devices including GPS or RLTS tracking tags, wearable medical sensors, and consumer electronics such as e-book readers and headsets. At longer range the power can be used for battery-based or battery-free remote sensors for HVAC control and building automation, structural monitoring, and industrial control. Depending on the power requirements and system operation, power can be sent continuously, on a scheduled basis, or on-demand. In large-scale sensors deployments significant labor cost avoidance is possible by eliminating the future maintenance efforts to replace batteries.
Available power from a 3W transmitter will be low milliwatts within a few feet and tens of microwatts at around 40 feet. This amount of power is best used for devices with low-power consumption and long or frequent charge cycles. Typically, devices that operate for weeks, months, or years on a single set of batteries are good candidates for being wirelessly recharged by RF energy. In some applications simply augmenting the battery life or offsetting the sleep current of a microcontroller is enough to justify adding RF-based wireless power and energy harvesting technology.
A network of transmitters can be positioned in a facility to provide wireless power on a room-by-room basis, or for a many-to-many charging topology. Mobile phones can be used as portable power sources for a number of battery-free wireless devices. Imagine a mobile phone powering a battery-less, body-worn sensor that sends data to the phone via a commonly used protocol such as Wi-Fi, Bluetooth, or ZigBee. This data can be displayed locally on the handset or transmitted by the phone to a monitoring service. Powercast has already demonstrated this application using ambient RF energy from an iPhone (see video to right).
Improved Product Design
Products with embedded wireless power technology can be sealed from environmental conditions such as moisture and from user access. In addition, connectors and cables can be eliminated. Product reliability and lifecycle can be significantly improved as a result. When in range of a suitable RF source, charging is automatic and transparent to the end-user which provides increased convenience of use. With Powercast’s components, multiple battery chemistries and charge voltages can be supported which allows for maximum power storage flexibility.
Conclusion
Ambient radio waves are universally present over an ever-increasing range of frequencies and power levels, especially in highly populated urban areas. These radio waves represent a unique and widely available source of energy if it can be effectively and efficiently harvested. The growing number of wireless transmitters is naturally resulting in increased RF power density and availability. Dedicated power transmitters further enable engineered and predictable wireless power solutions. With continued decreases in the power consumption of electronic components, increased sensitivity of passive receivers for RF harvesting, and improved performance of low-leakage energy storage devices, the applications for wire-free charging by means of RF-based wireless power and energy harvesting will continue to grow.
Harry Ostaffe is vice president, marketing & business development at Powercast. He has 20-plus years of experience in the fields of data communications and wireless networking, industrial controls, and computing. Before joining Powercast, Ostaffe held positions with Ericsson, Marconi, Lucent Technologies, AT&T Network Systems, Bayer, and IBM. He holds an MBA from Carnegie Mellon University and earned his BS in Electrical Engineering from Penn State University
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