Abstract: The present invention relates to nanofiber based non-insertable nasal filter. The joint geometry of the nasal filter designed enables easy usability and enables application on nasal periphery in one go. The nasal filter provides multilayer filtration for particulate matter between 2.5 PM and 10 PM aerosols with high efficiency and may be used in industries, by traffic police, by commuters for daily use and people with pollen allergy.

Abstract: Method and system for user authentication using one or more unique ID's associated with one or more electronic devices connected in a communication network, more specifically in short range radio communication network. the method comprising the steps of polling and detection of a short range wireless electronic device within a short range radio communication network, establishing a connection between such short range wireless electronic device with a centralized server, authenticating the short range wireless device ID, requesting further the user to feed a pre-determined authentication code, verifying the fed authentication code with corresponding entries in the database of the central server, establishing an encrypted channel if authentication code found in such database, receiving a user authentication certificate from the wireless electronic device.

Abstract: System and method for creating networked short range zone through remote delivery of short range proxy server on a remotely located machine, the method comprising the steps of registering with the system network, receiving a unique ID, accessing the server for further processing, downloading the relevant application with enabling means, connecting a device to short range dongles, running the application and registering the device using the unique ID, entering the location based and/or other relevant information, enabling the device for creating networked short range zone.

Abstract: A system for remote control of live TV capability for TV screens, the system comprising satellite feeds (2003) broadcasting means (2002, 2004), a set top box (2005), a Smart-IB box (2006) capable of sending and receiving data/content, a central server capable of interpreting received data/content from Smart-IB, a communication network having interactive means coupled with world wide web (2008), a display screen (2007) having display means operable to display data/information. A method for remote control of live TV capability for TV screens, the method comprising the steps of receiving a schedule to record and/or relay set top box content, forwarding desired frequency to remote signal inducing means (RSIM), generating infrared (IR) signal, interpreting infrared (IR) signal by set top box, changing audio-video (AV) output as per the schedule list, recording/relaying audio-video (AV) output.

Abstract: Method and system for user authentication using one or more unique ID's associated with one or more electronic devices connected in a communication network, more specifically in short range radio communication network. the method comprising the steps of polling and detection of a short range wireless electronic device within a short range radio communication network, establishing a connection between such short range wireless electronic device with a centralized server, authenticating the short range wireless device ID, requesting further the user to feed a pre-determined authentication code, verifying the fed authentication code with corresponding entries in the database of the central server, establishing an encrypted channel if authentication code found in such database, receiving a user authentication certificate from the wireless electronic device.

Abstract: System and method for creating networked short range zone through remote delivery of short range proxy server on a remotely located machine, the method comprising the steps of registering with the system network, receiving a unique ID, accessing the server for further processing, downloading the relevant application with enabling means, connecting a device to short range dongles, running the application and registering the device using the unique ID, entering the location based and/or other relevant information , enabling the device for creating networked short range zone.

Abstract: A system and method for tagging of content/data for display on a display screen, the system comprising World Wide Web connected to a central server through connecting means, smart IBs capable of sending and receiving data/content, a display media device having interactive means in as short range wireless network, administrators system to schedule data/content.

Abstract: A first voltage variable material (“VVM”) includes an insulative binder, first conductive particles with a core and a shell held in the insulating binder and second conductive particles without a shell held in the insulating binder; a second VVM includes an insulating binder, first conductive particles with a core and a shell held in the insulating binder, second conductive particles without a shell held in the insulating binder, and semiconductive particles with a core and a shell held in the insulating binder; a third VVM includes only first conductive particles with a core and a shell held in the insulating binder.

Abstract: A system for remote control of live TV capability for TV screens, the system comprising satellite feeds (2003) broadcasting means (2002, 2004), a set top box (2005), a Smart-IB box (2006) capable of sending and receiving data/content, a central server capable of interpreting received data/content from Smart-IB, a communication network having interactive means coupled with world wide web (2008), a display screen (2007) having display means operable to display data/information. A method for remote control of live TV capability for TV screens, the method comprising the steps of receiving a schedule to record and/or relay set top box content, forwarding desired frequency to remote signal inducing means (RSIM), generating infrared (IR) signal, interpreting infrared (IR) signal by set top box, changing audio-video (AV) output as per the schedule list, recording/relaying audio-video (AV) output.

Abstract: A first voltage variable material (“VVM”) includes an insulative binder, first conductive particles with a core and a shell held in the insulating binder and second conductive particles without a shell held in the insulating binder; a second VVM includes an insulating binder, first conductive particles with a core and a shell held in the insulating binder, second conductive particles without a shell held in the insulating binder, and semiconductive particles with a core and a shell held in the insulating binder; a third VVM includes only first conductive particles with a core and a shell held in the insulating binder.

Abstract: A first voltage variable material (“VVM”) includes an insulative binder, first conductive particles with a core and a shell held in the insulating binder and second conductive particles without a shell held in the insulating binder; a second VVM includes an insulating binder, first conductive particles with a core and a shell held in the insulating binder, second conductive particles without a shell held in the insulating binder, and semiconductive particles with a core and a shell held in the insulating binder; a third VVM includes only first conductive particles with a core and a shell held in the insulating binder.

Abstract: A first voltage variable material (“VVM”) includes an insulative binder, first conductive particles with a core and a shell held in the insulating binder and second conductive particles without a shell held in the insulating binder; a second VVM includes an insulating binder, first conductive particles with a core and a shell held in the insulating binder, second conductive particles without a shell held in the insulating binder, and semiconductive particles with a core and a shell held in the insulating binder; a third VVM includes only first conductive particles with a core and a shell held in the insulating binder.

Abstract: A voltage variable material (“VVM”) including an insulative binder that is formulated to intrinsically adhere to conductive and non-conductive surfaces is provided. The binder and thus the VVM is self-curable and applicable in a spreadable form that dries before use. The binder eliminates the need to place the VVM in a separate device or to provide separate printed circuit board pads on which to electrically connect the VVM. The binder and thus the VVM can be directly applied to many different types of substrates, such as a rigid FR-4 laminate, a polyimide, a polymer or a multilayer PCB via a process such as screen or stencil printing. In one embodiment, the VVM includes two types of conductive particles, one with a core and one without a core. The VVM can also have core-shell type semiconductive particles.

Abstract: A voltage variable material (“VVM”) including an insulative binder that is formulated to intrinsically adhere to conductive and non-conductive surfaces is provided. The binder and thus the VVM is self-curable and applicable in a spreadable form that dries before use. The binder eliminates the need to place the VVM in a separate device or to provide separate printed circuit board pads on which to electrically connect the VVM. The binder and thus the VVM can be directly applied to many different types of substrates, such as a rigid (FR-4) laminate, a polyimide or a polymer. The VVM can also be directly applied to different types of substrates that are placed inside a device. In one embodiment, the VVM includes doped semiconductive particles having a core, such which can be silicon, and an inert coating, which can be an oxide. The particles are mixed in the binder with conductive particles.

Abstract: An improved electrical circuit that includes an embedded electrical component and an embedded voltage variable material (“VVM”) is provided. In one embodiment, the embedded VVM is provided as a voltage variable substrate, which is used in combination with an embedded electrical component, such as an embedded resistive material or an embedded capacitive material.

Abstract: A voltage variable material (“VVM”) including an insulative binder that is formulated to intrinsically adhere to conductive and non-conductive surfaces is provided. The binder and thus the VVM is self-curable and applicable in a spreadable form that dries before use. The binder eliminates the need to place the VVM in a separate device or to provide separate printed circuit board pads on which to electrically connect the VVM. The binder and thus the VVM can be directly applied to many different types of substrates, such as a rigid FR-4 laminate, a polyimide, a polymer or a multilayer PCB via a process such as screen or stencil printing. In one embodiment, the VVM includes two types of conductive particles, one with a core and one without a core. The VVM can also have core-shell type semiconductive particles.

Abstract: A voltage variable material (“VVM”) including an insulative binder that is formulated to intrinsically adhere to conductive and non-conductive surfaces is provided. The binder and thus the VVM is self-curable and applicable in a spreadable form that dries before use. The binder eliminates the need to place the VVM in a separate device or to provide separate printed circuit board pads on which to electrically connect the VVM. The binder and thus the VVM can be directly applied to many different types of substrates, such as a rigid (FR-4) laminate, a polyimide or a polymer. The VVM can also be directly applied to different types of substrates that are placed inside a device. In one embodiment, the VVM includes doped semiconductive particles having a core, such which can be silicon, and an inert coating, which can be an oxide. The particles are mixed in the binder with conductive particles.