This document compares two digital business card services, Bump and Poken. Bump allows users to exchange contact information by bumping smartphones together, while Poken integrates with social networks to share information. Both aim to replace physical business cards by making contact sharing digital but offer different approaches to how information is exchanged and accessed.
OLED (organic light-emitting diode) is a display technology for use in mobile devices and televisions.
OLED describes a specific type of thin-film display technology in which organic compounds form the electroluminescent material.
This document provides ideas for the design of a game called Smart Bump that involves stunt driving, puzzles, and physical interaction. It discusses using cell-shaded and art deco graphics, storytelling through environments and banners, a single player linear level structure with input, process, and output stages, and developing the game using the free Unity 3D version, Blender, and Garage Band.
OLED (organic light-emitting diode) is a solid-state device that emits light when electricity is applied. It is composed of thin layers of organic material placed between an anode and a cathode. OLEDs have several advantages over LCDs including being thinner, lighter, more flexible, more energy efficient, and capable of faster refresh rates and larger viewing angles. Different types of OLEDs include passive matrix, active matrix, transparent, top-emitting, foldable, and white OLEDs which have various applications including displays for phones, TVs, signs, clothing, and more.
Ppt for the seminr topic on gi fi technologyVikram Emmidi
Gi-Fi is a next generation wireless technology developed in Australia that operates at 60GHz for high speed data transfer of up to 5Gbps. It was created to overcome the slow speeds and high power consumption of previous technologies like Bluetooth and Wi-Fi. Gi-Fi provides cable-like replacement with 10x faster transfer speeds than current wireless and lower power consumption than its predecessors. Its small chip design allows for portable, low-cost deployment and integration into various devices for applications like wireless home networks, device connectivity, and video streaming. Gi-Fi is expected to become the dominant wireless networking technology within five years.
OLEDs (organic light emitting diodes) are thin, lightweight displays made of organic material that emit light when electric current is applied. The basic OLED structure consists of organic layers sandwiched between a transparent anode and metallic cathode. When a voltage is applied, holes and electrons recombine in the organic layers, producing electroluminescence. Key advantages of OLEDs include high brightness, wide viewing angles, thinness, flexibility, and low energy consumption. However, organic materials are susceptible to degradation from oxygen and water. Carrier injection and transport in OLEDs occurs via thermionic emission, field emission, and hopping between localized states in the organic layers.
This document compares two digital business card services, Bump and Poken. Bump allows users to exchange contact information by bumping smartphones together, while Poken integrates with social networks to share information. Both aim to replace physical business cards by making contact sharing digital but offer different approaches to how information is exchanged and accessed.
OLED (organic light-emitting diode) is a display technology for use in mobile devices and televisions.
OLED describes a specific type of thin-film display technology in which organic compounds form the electroluminescent material.
This document provides ideas for the design of a game called Smart Bump that involves stunt driving, puzzles, and physical interaction. It discusses using cell-shaded and art deco graphics, storytelling through environments and banners, a single player linear level structure with input, process, and output stages, and developing the game using the free Unity 3D version, Blender, and Garage Band.
OLED (organic light-emitting diode) is a solid-state device that emits light when electricity is applied. It is composed of thin layers of organic material placed between an anode and a cathode. OLEDs have several advantages over LCDs including being thinner, lighter, more flexible, more energy efficient, and capable of faster refresh rates and larger viewing angles. Different types of OLEDs include passive matrix, active matrix, transparent, top-emitting, foldable, and white OLEDs which have various applications including displays for phones, TVs, signs, clothing, and more.
Ppt for the seminr topic on gi fi technologyVikram Emmidi
Gi-Fi is a next generation wireless technology developed in Australia that operates at 60GHz for high speed data transfer of up to 5Gbps. It was created to overcome the slow speeds and high power consumption of previous technologies like Bluetooth and Wi-Fi. Gi-Fi provides cable-like replacement with 10x faster transfer speeds than current wireless and lower power consumption than its predecessors. Its small chip design allows for portable, low-cost deployment and integration into various devices for applications like wireless home networks, device connectivity, and video streaming. Gi-Fi is expected to become the dominant wireless networking technology within five years.
OLEDs (organic light emitting diodes) are thin, lightweight displays made of organic material that emit light when electric current is applied. The basic OLED structure consists of organic layers sandwiched between a transparent anode and metallic cathode. When a voltage is applied, holes and electrons recombine in the organic layers, producing electroluminescence. Key advantages of OLEDs include high brightness, wide viewing angles, thinness, flexibility, and low energy consumption. However, organic materials are susceptible to degradation from oxygen and water. Carrier injection and transport in OLEDs occurs via thermionic emission, field emission, and hopping between localized states in the organic layers.
Gi Fi - Fastest Wireless Transfer TechnologyPradeep Rapolu
Gi-Fi is a next generation wireless technology that allows data transfer speeds up to 5 gigabits per second within a 10 meter range. It aims to overcome the slow transfer speeds and high power consumption of existing technologies like Bluetooth and Wi-Fi. Gi-Fi operates using 60GHz frequency and supports the IEEE 802.15.3C standard. It is expected to become the dominant wireless networking technology within 5 years, enabling wirelessly connected homes and offices with fast, low-cost broadband access.
This document discusses the next generation wireless technology called Gi-Fi. Gi-Fi allows wireless transfer of audio and video data at speeds up to 5 gigabits per second, which is 10 times faster than existing technologies like Wi-Fi. Researchers at Melbourne University developed a Gi-Fi chip that can transmit complex 60GHz signals at high speeds while being small enough to fit on a single silicon chip. Compared to Wi-Fi and Bluetooth, Gi-Fi provides higher data transfer rates, longer ranges, lower power consumption, lower costs, better security, and more flexibility without needing complex connections. The document outlines several applications for Gi-Fi in wireless networks, vehicle communication systems, households, and video information transfer.
The document discusses organic light emitting diodes (OLEDs), which are thin, light-emitting devices composed of organic material. It provides a history of OLED development, describes how OLEDs work through electroluminescence without the need for backlighting, and covers manufacturing methods. The document also examines different types of OLEDs including passive matrix, active matrix, and transparent OLEDs. It outlines advantages such as thinness, flexibility, high contrast, and wide viewing angles, as well as challenges including short blue light lifespan. Applications mentioned include use of OLEDs in televisions, mobile phones, and smart watches.
Gi-Fi (Gigabit Wireless) is a new wireless technology that can transfer data at up to 5 gigabits per second, which is 10 times faster than current wireless technologies. It uses 60GHz frequency and can transfer large files like HD videos within a 10 meter range. Gi-Fi aims to provide higher data transfer rates than Bluetooth and Wi-Fi at lower power consumption. It uses small antennas and works best with line of sight. Applications include wireless connectivity between devices in homes and offices for applications like streaming HD content, high-speed inter-vehicle communication, and more. Gi-Fi is expected to become the dominant wireless technology for networking within five years.
Gi-Fi is a new wireless technology that offers faster data transfer rates than Wi-Fi and WiMax. It uses 60GHz frequency and can transfer data at rates up to 5 gigabits per second, which is 10 times faster than current wireless technologies. Gi-Fi uses an integrated transceiver chip developed in Australia that operates at low power. It allows quick transfer of large files like videos within seconds over short ranges. Gi-Fi is expected to become the dominant wireless technology for applications like wireless home networks and high-speed transfer between devices.
This document summarizes a seminar on Gi-Fi technology. It discusses currently used wireless technologies like Wi-Fi and Bluetooth. It then introduces Gi-Fi, explaining that it uses light waves to transmit data wirelessly over short distances at high speeds. The document outlines Gi-Fi's architecture, features like high speed data transfer and low power consumption. It also lists some applications and concludes that Gi-Fi is expected to become the dominant wireless networking technology within five years, bringing wireless broadband to both homes and offices.
Gi-Fi is a new wireless technology that provides transmission speeds up to 10 times faster than Wi-Fi. It uses the 60GHz frequency band and allows for data transfer rates up to 5Gbps. Some key advantages of Gi-Fi include high speeds, low power consumption, lower production costs compared to other wireless technologies like Bluetooth and Wi-Fi, and a small compact form factor. Potential applications of Gi-Fi include high-speed internet access, wireless transfers between devices like phones and computers, and use in intelligent systems requiring high security.
Haptics is a technology that adds the sense of touch to interactions with virtual objects by connecting user movements and actions to corresponding computer-generated feedback such as forces, vibrations, and motions. This allows virtual objects to seem real and tangible to the user. Haptics links the brain's sensing of body position and movement through sensory nerves to provide an immersive experience when interacting with virtual environments and simulated objects.
OLED technology uses organic light emitting diodes to create brighter, thinner, and more flexible displays. An OLED is composed of thin films of organic molecules that emit light when electricity is applied. The first OLED was developed in 1987, and since then OLEDs have been used in various displays. OLEDs offer advantages over LCDs like higher contrast, better viewing angles, and less power consumption. Major applications of OLEDs include televisions, smartphones, and laptops.
The document discusses the emerging field of polytronics, which uses conductive polymers rather than silicon in electronic devices. It notes that polytronics offers lower costs than silicon chips and more flexibility. The document provides an introduction to polymers and their properties. It outlines some of the history behind polytronics and discusses how polymers can conduct electricity. Examples of applications are given, such as organic field-effect transistors. Advantages of polytronics include lower electronic waste and more affordable access to technology.
Gi Fi - Fastest Wireless Transfer TechnologyPradeep Rapolu
Gi-Fi is a next generation wireless technology that allows data transfer speeds up to 5 gigabits per second within a 10 meter range. It aims to overcome the slow transfer speeds and high power consumption of existing technologies like Bluetooth and Wi-Fi. Gi-Fi operates using 60GHz frequency and supports the IEEE 802.15.3C standard. It is expected to become the dominant wireless networking technology within 5 years, enabling wirelessly connected homes and offices with fast, low-cost broadband access.
This document discusses the next generation wireless technology called Gi-Fi. Gi-Fi allows wireless transfer of audio and video data at speeds up to 5 gigabits per second, which is 10 times faster than existing technologies like Wi-Fi. Researchers at Melbourne University developed a Gi-Fi chip that can transmit complex 60GHz signals at high speeds while being small enough to fit on a single silicon chip. Compared to Wi-Fi and Bluetooth, Gi-Fi provides higher data transfer rates, longer ranges, lower power consumption, lower costs, better security, and more flexibility without needing complex connections. The document outlines several applications for Gi-Fi in wireless networks, vehicle communication systems, households, and video information transfer.
The document discusses organic light emitting diodes (OLEDs), which are thin, light-emitting devices composed of organic material. It provides a history of OLED development, describes how OLEDs work through electroluminescence without the need for backlighting, and covers manufacturing methods. The document also examines different types of OLEDs including passive matrix, active matrix, and transparent OLEDs. It outlines advantages such as thinness, flexibility, high contrast, and wide viewing angles, as well as challenges including short blue light lifespan. Applications mentioned include use of OLEDs in televisions, mobile phones, and smart watches.
Gi-Fi (Gigabit Wireless) is a new wireless technology that can transfer data at up to 5 gigabits per second, which is 10 times faster than current wireless technologies. It uses 60GHz frequency and can transfer large files like HD videos within a 10 meter range. Gi-Fi aims to provide higher data transfer rates than Bluetooth and Wi-Fi at lower power consumption. It uses small antennas and works best with line of sight. Applications include wireless connectivity between devices in homes and offices for applications like streaming HD content, high-speed inter-vehicle communication, and more. Gi-Fi is expected to become the dominant wireless technology for networking within five years.
Gi-Fi is a new wireless technology that offers faster data transfer rates than Wi-Fi and WiMax. It uses 60GHz frequency and can transfer data at rates up to 5 gigabits per second, which is 10 times faster than current wireless technologies. Gi-Fi uses an integrated transceiver chip developed in Australia that operates at low power. It allows quick transfer of large files like videos within seconds over short ranges. Gi-Fi is expected to become the dominant wireless technology for applications like wireless home networks and high-speed transfer between devices.
This document summarizes a seminar on Gi-Fi technology. It discusses currently used wireless technologies like Wi-Fi and Bluetooth. It then introduces Gi-Fi, explaining that it uses light waves to transmit data wirelessly over short distances at high speeds. The document outlines Gi-Fi's architecture, features like high speed data transfer and low power consumption. It also lists some applications and concludes that Gi-Fi is expected to become the dominant wireless networking technology within five years, bringing wireless broadband to both homes and offices.
Gi-Fi is a new wireless technology that provides transmission speeds up to 10 times faster than Wi-Fi. It uses the 60GHz frequency band and allows for data transfer rates up to 5Gbps. Some key advantages of Gi-Fi include high speeds, low power consumption, lower production costs compared to other wireless technologies like Bluetooth and Wi-Fi, and a small compact form factor. Potential applications of Gi-Fi include high-speed internet access, wireless transfers between devices like phones and computers, and use in intelligent systems requiring high security.
Haptics is a technology that adds the sense of touch to interactions with virtual objects by connecting user movements and actions to corresponding computer-generated feedback such as forces, vibrations, and motions. This allows virtual objects to seem real and tangible to the user. Haptics links the brain's sensing of body position and movement through sensory nerves to provide an immersive experience when interacting with virtual environments and simulated objects.
OLED technology uses organic light emitting diodes to create brighter, thinner, and more flexible displays. An OLED is composed of thin films of organic molecules that emit light when electricity is applied. The first OLED was developed in 1987, and since then OLEDs have been used in various displays. OLEDs offer advantages over LCDs like higher contrast, better viewing angles, and less power consumption. Major applications of OLEDs include televisions, smartphones, and laptops.
The document discusses the emerging field of polytronics, which uses conductive polymers rather than silicon in electronic devices. It notes that polytronics offers lower costs than silicon chips and more flexibility. The document provides an introduction to polymers and their properties. It outlines some of the history behind polytronics and discusses how polymers can conduct electricity. Examples of applications are given, such as organic field-effect transistors. Advantages of polytronics include lower electronic waste and more affordable access to technology.
8. Convenience -(void) configUserName: (NSString *)name; -(NSString *) otherUserName; -(void) connectToDoContactExchange:(BumpContact*) contact; -(void) connectToShareThisApp; - If this method is used, you can bump phones to present the user with an iTunes download link of your app.
9. Resources Bump API Homepage http://bu.mp/api Bump API Resources http://bu.mp/apiresources Bump Iphone Google Group http://groups.google.com/group/bump-api