Abstract: Apparatus and methods for reducing the exposure of a human eye to external radio frequency (RF) radiation comprises eyeglass frames and/or a lens, positioned in front of the eye, and a material, intentionally added on or in the frames or lens, which is operative to shield, attenuate, or reflect high-frequency RF energy. The invention is also applicable to contact lenses without frames. The invention is also effective in shielding the human brain and other tissues. In the preferred embodiments, the material is operative to shield, attenuate, or reflect energy in the range of 100 MHz to 30 GHz and/or provide an RF power reduction of at least 25 percent. The material may include ferrite beads. Embedded components may include an RF detector and circuitry to actively attenuate the level of RF energy received in response to the detected level, or an RF detector and circuitry to alert a user as to the level of RF energy received in response to the detected level. The alert may be visual or audible.

Abstract: A wireless implantable device for communicating with a remote unit, wherein the wireless device is capable of self-initializing, namely initial booting without requiring an external general booting program to force the booting process. The implantable device can download program instructions from the remote unit for the operation of the implantable device. Moreover, the implantable device provides for checking the validity and integrity of any program instructions received from the remote unit for the operation of the implantable device. The implantable device has power-saving capability in order to extend the operation of the implantable device between battery charges.

Abstract: A remote locator (RL) continuously transmits multi-frame pings in a slow ping mode. The user activates a transponder/micro-transponder (MT) to receive at least a portion of the multi-frame ping and transmits a reply to the RL. The RL calculates a distance between the RL and the MT using the time-of-flight between the transmission of the ping and the receipt of the corresponding reply. The RL continues to send pings to the MT, where the ping includes distance measurements encoded therein. The user initiates sending a message from the MT to the RL to change to a fast ping mode, where the RL transmits pings at an increased rate. The MT includes a compass to captures readings while receiving and replying to pings. The MT determines a directional location for the RL with the collected measurements and received information and can provide a distance and directional readout to the user.

Abstract: The location of a transponder or micro-transponder (MT) device can be determined relative to a remote locator (RL) device. The RL transmits a multi-frame ping to the MT when initiated by a user. The MT receives the multi-frame ping, and transmits a multi-frame reply that can be hollowed out to conserve transmit power and reduce interference between devices. The RL calculates a distance between the RL and the MT using the time-of-flight (TOF) between the transmission of a ping and the receipt of a reply. The user designates one or more threshold ranges for the MT relative to the RL. The RL provides a user alert whenever the MT travels outside a threshold range. Alerts can be provided through a number of mechanisms including an audible alert, a visible alert, a vibrating alert, an email message, an SMS message, an instant message, a pager message, a telephone call, etc.

Abstract: A hand-held remote locator (RL) device is used to locate a transponder or micro-transponder (MT). The user activates the RL to transmit a multi-frame ping to the MT in a slow ping mode, where the MT transmits reply messages when the multi-frame ping is received The RL calculates a distance between the RL and the MT using the time-of-flight (TOF) between the transmission of a ping and the receipt of a reply. The user can then engage a fast ping mode, where the RL transmits the multi-frame ping at an increased rate. The user then extends the RL device away from their body and turns through at least a partial arc length about their center line such that data is collected including compass readings, Doppler information, and distance calculations. The directional location for the MT is determined by the RL using the collected data.

Abstract: An implantable device and a wireless communication integrated circuit (IC) implementable in the implantable device for communicating with a remote unit, wherein the communication IC is capable of self-initializing, namely initial booting without requiring an external general booting program to force the booting process. Moreover, the implantable device and the communication IC provide for checking of the validity and integrity of any program instructions received from the remote unit for the desired operation of the implantable device. The implantable device and the communication IC therein have power-saving capability in order to extend the operation of the implantable device between battery charges. A further embodiment provides a robust communication IC, whereby signal distortion or interference between the analog and digital components collectively residing on the same communication IC is minimized or eliminated.

Abstract: Described is a system and method related to the synchronization of a communication stream between two devices. A broadcast signal is a segmented information signal that includes a distributed synchronization pattern and a distributed frame index. Each segment of the segmented information signal further includes a header portion and a payload portion. The header portion of the segmented information signal includes a portion of the distributed synchronization pattern and a portion of the distributed frame index. The method includes generating the distributed synchronization pattern and the distributed frame index, distributing the synchronization pattern and frame index throughout the signal, and transmitting the signal.

Abstract: Described is a system and method for providing a synchronization pattern in a communication system. The method includes generating a synchronization pattern with good randomness properties; packing a signal for transmission with m headers, each header consisting of the synchronization pattern 1/m symbol-time shifted from the previous header; and transmitting the signal. A further method provides for the sampling the transmitted signal with m headers of symbol-time shifted synchronization patterns; and determining symbol timing offset by computing and reordering correlation peaks from the synchronization patterns. A system includes a transmitting system, a receiving system, and a data channel. The transmitted signal includes m headers with 1/m symbol-time shifted synchronization patterns. The receiving system undersamples the transmitted signal with m synchronization patterns to simulate an oversampled synchronization pattern.

Abstract: An apparatus and method is related to providing sensing functions that are similar to “human touch” when located in a prosthetic device such as a BION microstimulator that is implanted in a patient. The apparatus includes a power circuit, a communication circuit, and a sensor circuit. The power circuit provides power to the communication circuit and the sensor circuit. The sensor cooperates with the communication circuit, which communicates to the brain. The sensor uses various techniques to detect changes in the environment for the surrounding tissue using criteria such as reflectivity, impedance, conductivity, return signal spectrum, return signal rate, and return signal phase to name a few. For example, the impedance observed by the sensor changes when: the skin tissue is deformed around the sensor, or when the skin is surrounded by water. The sensory information is interpreted by the brain as an analog of touch or feel.

Abstract: An apparatus and method is related to wireless communication devices with a reduced-noise recording receiver. The recording receiver receives a transmitted signal, converts the received signal to a digital base-band signal and stores the digitized base-band signal in a buffer for subsequent processing. The stored digital signals are subsequently processed to recover the transmitted data signal. The overall signal integrity in the receiver is improved by performing signal processing after reception is complete. The IF processing section of the receiver includes a frequency band translation section. The frequency band translation section translates the frequency band of the IF signal into a non-harmonically related frequency band. Since the IF signal is in an unrelated frequency band, data can be recovered from the transmission signal with improved signal-to-noise characteristics.

Abstract: A system and method that facilitates multiple systems of communicating devices, i.e., a master device and one or more implantable slave devices, to coexist on a common, e.g., RF, communication channel having a limited temporal bandwidth while maintaining the required update rate between each master device and its associated slave devices. In embodiments of the present invention, master devices periodically transmit one or more beacon messages that are suitable for identification by other such master devices at a communication range greater than the communication range that may cause interference between systems and thus enabling one or more systems to cause the position of its frame periods to be interleaved with the frame periods of other such systems in anticipation of systems moving in closer proximity and actually interfering with each other.

Abstract: Described is a system and method for providing a synchronization pattern in a communication system. The method includes generating a synchronization pattern with good randomness properties; packing a signal for transmission with m headers, each header consisting of the synchronization pattern 1/m symbol-time shifted from the previous header; and transmitting the signal. A further method provides for the sampling the transmitted signal with m headers of symbol-time shifted synchronization patterns; and determining symbol timing offset by computing and reordering correlation peaks from the synchronization patterns. A system includes a transmitting system, a receiving system, and a data channel. The transmitted signal includes m headers with 1/m symbol-time shifted synchronization patterns. The receiving system undersamples the transmitted signal with m synchronization patterns to simulate an oversampled synchronization pattern.

Abstract: Described is a system and method for providing a synchronization pattern in a communication system. The method includes generating a synchronization pattern with good randomness properties; packing a signal for transmission with m headers, each header consisting of the synchronization pattern 1/m symbol-time shifted from the previous header; and transmitting the signal. A further method provides for the sampling the transmitted signal with m headers of symbol-time shifted synchronization patterns; and determining symbol timing offset by computing and reordering correlation peaks from the synchronization patterns. A system includes a transmitting system, a receiving system, and a data channel. The transmitted signal includes m headers with 1/m symbol-time shifted synchronization patterns. The receiving system undersamples the transmitted signal with m synchronization patterns to simulate an oversampled synchronization pattern.

Abstract: Systems and method utilizing microelectronic devices for determining relative positions such as distances and/or angles between at least two points is described. The points may be locations of parts of the body such as the fingers on a person's hand. A first microelectronic device is adapted to emit magnetic signals and at least a second microelectronic device is adapted to receive the magnetic signals, wherein a controller is adapted to communicate with the first and second microelectronic devices. The second microelectronic device and/or the controller are adapted to determine a distance and angle between the first and the second microelectronic devices based on the strength of the magnetic signals received by the second microelectronic device.

Abstract: A facsimile system is explained on the basis of a single unit which is connected to a video pick-up device and to a facsimile reconstruction device. The video signal is converted into a two level signal and the lengths of runs of the same level are metered by counting increments of such run lengths and converted the count numbers into a stream of ternary digits to distinguish length numbers for the runs of different signal levels by digit notation. These ternary encoded run length numbers pass through a buffer for storage on tape. Upon retrieval they pass again through the buffer and are converted in groups of one or two ternary digits into seven symbols, used to phase and amplitude modulate a carrier for transmission. Carrier signals when received are demodulated and converted into ternary code signals, which are buffered and stored. Upon image reconstruction, the stored, ternary encoded run length numbers are retrieved, pass through the buffer and are used to re-establish a two level signal.