Abstract: Apparatus, methods, and systems for centrally and uniformly controlling the operation of a variety of devices, such as communication, consumer electronic, audio-video, analog, digital, 1394, and the like, over a variety of protocols within a network system and, more particularly, a control system and uniform user interface for centrally controlling these devices in a manner that appears seamless and transparent to the user. In a one embodiment, the control system will detect sync/digital video signals from an IR controlled device coupled to an input port of a primary display and control unit of the system. By testing IR power command codes, the control system can automatically identify which power commands will cause a change in input at the input port and, thus, automatically configure the control of the IR controlled device coupled to the input port.

Abstract: A system and method for controlling a remote vehicle comprises a hand-held controller including a laser generator for generating a laser beam. The hand-held controller is manipulable to aim and actuate the laser beam to designate a destination for the remote vehicle. The remote vehicle senses a reflection of the laser beam and moves toward the designated destination. The hand-held controller allows single-handed control of the remote vehicle and one or more of its payloads. A method for controlling a remote vehicle via a laser beam comprises encoding control signals for a remote vehicle into a laser beam that is aimed and sent to a designated destination for the remote vehicle, and sensing a reflection of the laser beam, decoding the control signals for the remote vehicle, and moving toward the designated destination.

Abstract: A system and method for wirelessly transmitting both real-time data streams and remote control signals is described. A first transceiver can be used for detecting remote control signals associated with an end device (e.g. a television), transforming these remote control signals into wireless signals, and transmitting the wireless signals. A second transceiver can be used for receiving the wireless signals and transforming the wireless signals into the recreated remote control signals. The recreated remote control signals can then be sent to a source device (e.g. a DVD player). Because wireless signals are used (instead of infrared (IR) signals, for example), the source device can be outside the line of sight of the end device and still respond to the remote control signals.

Abstract: Light emitting diodes are placed side by side at a front end of the remote control transmitter in a manner that their maximum radiation directions, i.e. radiation directions each giving a maximum radiation intensity, are each inclined at an angle within a range no larger than 5 degrees outwardly of the remote control transmitter 1 and symmetrically with respect to a bisector of a line segment which connects center points of the light emitting diodes. The inclination, within a range no larger than 5 degrees, of each of the light emitting diodes used as light sources for remote control does not cause significant reduction in the radiation intensity. Accordingly, it is possible to widen the transmittable angle within a range no larger than 10 degrees without significantly reducing the radiation intensity at a central portion of the radiation range.

Abstract: Described herein are technologies directed towards IR-to-network conversion. With the described technology, a system may convert an infrared (IR) control signal from an IR remote controller into a network-transmittable message package and transmit that package via a communications network, such as the Internet (or a network compatible therewith). The IR control signal is destined for a to-be-controlled audio/visual (AV) device. The transmitted network message packet is received at the location of the to-be-controlled AV device and converted back into its original IR control signal. The signal is transmitted to the AV device; thereby effecting control of that device.

Abstract: In each of a plurality of submarine observation apparatus (1 to n), a branching unit (63) branches fixed-wavelength light (?1) from an incoming wavelength-multiplexed light signal. An observation signal modulating unit (64) modulates the intensity of the branched fixed-wavelength light (?1) with observation information multiplexed by an observation signal multiplex unit (61). A combining unit (65) combines light signals (?2) to (?n) passing through the branching unit (63) and the fixed-wavelength light (?1a) modulated by the observation signal modulating unit (64) into a composite light signal, and outputs it to an optical fiber (12a). Therefore, in each of the plurality of submarine observation apparatus (1 to n), there is no necessity for providing a wavelength-division-multiplexing-transmission optical transmitter which requires high wavelength stability.

Abstract: An electricity meter includes an input circuit operable to generate signals representative of a line voltage waveform and a line current waveform. A processing circuit is connected to the input circuit and is operable to generate energy consumption data based on the input signals. A communications circuit is also connected to the processing circuit. The communications circuit includes an optical receiver having a single photo-transistor, a single capacitor and two resistors. The photo-transistor is operable to act as a switching device that allows varying amounts of current to pass in association with received light pulses. This action allows light signals received by the photo-transistor to be converted into electrical signals. The electrical signals are passed across the first resistor. These electrical signals are differentiated by the capacitor and the second resistor to filter out low frequency signals created by ambient light.

Abstract: An Infrared (IR) receiver includes a programmable decoder having a normal mode of operation and a proprietary mode of operation. When the programmable decoder is in the normal mode of operation, the programmable decoder decodes frames of an IR data transmission to produce decoded data. When the programmable decoder is in the proprietary mode of operation, the programmable decoder passes data of the IR data transmission during a time out period to produce raw data. The IR receiver also includes a pulse detection circuit that generates a pulse detection signal in response to detecting the IR data transmission. The IR receiver further includes a timer circuit that generates the timeout period in response to the pulse detection signal.

Abstract: An infrared remote control module (10) includes an infrared detecting module (11) configured for receiving optical signals and converting the optical signals into digital signals, a signal processing module (12) communicating with the infrared detecting module; and a controlling feedback module (13) communicating with the signal processing module. The infrared detecting module includes a lens barrel (110), an infrared band-pass filter (112) arranged in the lens barrel, a lens assembly (113) arranged in the lens barrel, an image pickup module (114) arranged in the lens barrel, and a collimator device (116) selectably moveable into or out from the lens barrel. By being moveable in such a fashion, the collimator device is configured for selectively collimating the optical signals, and, thus, the remote control module can be used for shooting or motion-based actions.

Abstract: Infrared control signals are repeated and communicated in a system including a source device and a sink device that are communicatively coupled by a serial communication link that includes a forward channel and a backward channel. Modulated infrared remote control data is detected by an infrared detector without de-modulation, and sampled in modulated form. Sampled data corresponding to the modulated remote control signal is transmitted from the sink device to the source device over the serial communication link, which in one example is a single optical fiber. The source device receives the sampled data and regenerates the infrared control data, which is then used to control the operation of the source device.

Abstract: Control systems and methods are disclosed for controlling operation of movable systems in an automated process with a stationary system having a first control system component and at least one movable system having a second control system component, in which optical or other non-contacting signaling between the stationary and movable systems is used to ascertain whether a movable system is proximate the stationary system, and wireless communications is used to transfer control data between the systems while the non-contacting signal link is maintained.

Abstract: A system for indicating a past state of an apparatus through the use of a remote device by indicating the state with the remote device whether or not the remote device is still within communications range of the apparatus. In one embodiment, an indication can be made as to whether or not a vehicle door has been locked by providing such an indication at a remote keyless entry key remote control.

Abstract: A data link system comprising a shelter housing sensitive radio frequency equipment and an antenna located apart from the shelter. A single fiber, bi-directional fiber optic link couples the antenna to the shelter. Both RF signals and data signals are sent across the data link.

Abstract: A communication system includes an optical “LAN” (50) interconnecting a plurality of information sources (16a) and sinks (22a) with a light-to-electrical converter (36a) associated with an electrical RF transmitters (32a) and an RF-to-light converter (38a) to a receiver (34a). The transmitter is coupled by way of electrical-to-light converter (46a), and the receiver is coupled by way of light-to-electrical converter (44a), and by way of a directional coupler (76a), to an end of an optical bus (74a), so that light signals representing signals to be transmitted flow in one direction, and light signals representing received signals flow in the other direction through the bus. A directional coupler (72a) at the other end of the optical bus routes the transmit light signals to a light-to-RF converter (47a) which feeds a sink or antenna (12a), and received signals from a source or antenna are routed by way of an RF-to-light converter (40a) and the directional coupler (72a) onto the optical bus (74a).

Abstract: A set of interactive toys that perform a sequence of actions in response to one another without external activation other than an initial actuation to begin the sequence of actions. Preferably, each toy has an activation switch and/or a receiver for a wireless signal such as an infrared signal which activates the toy. Upon activation, the toy performs a desired action, such as the enunciation of a speech pattern, and signals another toy to perform a responsive action. Preferably, the toy are capable of performing several different action sequences, such as the enunciation of different conversations, the performance of different movements, etc. Additionally, the toys are programmable by a remote control device. The remote control device either functions as an activation switch, initiating a random or predetermined (yet not user determined) sequence of interactions, or as an interaction selector, such that a desired sequence of actions may be selected.

Abstract: An addressable system for light fixtures is described wherein a plurality of light fixture modules is individually or collectively addressable for programming by remote control. The remote control may individually select each of the track control modules through visible and narrowly defined selected light followed by transmission of programming commands for programming of pre-defined scenes, functions or other user defined and desired effects. Each of the track fixture modules may be selected or de-selected through the use of laser light and a plurality of track control modules may be collectively programmed through the use of a track repeater module, all of the modules communicatively connected to each other and selectable by a visible narrow light source such that the user may readily activate or de-activate programming sequences.

Abstract: An addressable light fixture is described wherein a light fixture module is individually addressable for programming by remote control. The remote control may individually select each light fixture module through visible and narrowly defined selected light followed by transmission of programming commands for programming of pre-defined scenes, functions or other user defined and desired effects. Each of the fixture modules may be selected or de-selected through the use of laser light and a plurality of track control modules may be collectively programmed through the use of a repeater module, all of the modules communicatively connected to each other and selectable by a visible narrow light source such that the user may readily activate or de-activate programming sequences.

Abstract: A remote control for controlling consumer electronic devices and/or PC's. The remote control including a progress/status indicator for indicating the status of a download process or the status of an e-wallet.

Abstract: Universal remote control device database is updated through television video blanking interval (TV VBI) or sub-picture signal processing. As relayed through TV receiver, remote control database(s) is placed in VBI or sub-picture of video signal of specialized program. Data is decoded by VBI slicer or controller (e.g., MPEG decoder), then extracted and stored temporarily in memory. Upon request, data is transmitted via infra-red (IR) or radio-frequency (RF) emitter to learning remote control device, which downloads data to update remote programming protocol.

Abstract: An intelligent sensor platform is provided with an architecture that takes advantage of a low cost microcontroller for overall sensor control. Outputs are all controlled directly by the microcontroller as are gains of signal processing amplifiers and thresholds for threshold detectors. The sensor can be remotely programmed using a remote control device or simple. push button programming can be implemented.

Abstract: Circuitry using infra-red (IR) diodes in remote control units. In one embodiment an IR LED is used both as a transmitter diode and also as a receiver diode responsive to light to thereby develop photocurrents and/or voltages for use by external circuitry. In a second embodiment an improved amplifier circuit is provided for an IR LED and IR photo detector diode which is mounted behind, and receives light through, the transmitter IR LED.

Abstract: An architecture for use in controlling and managing optical functions and optical devices. A common microprocessor based control layer coordinates commands between optical devices and a user station. The control layer executes an operating system which handles data flow in the control layer. Generic commands from the user station causes the operating system to call specific subroutines the produce digital commands. These digital commands are then passed to a digital layer that interfaces with an analog layer. The analog layer is specifically developed to interface and work with a specific optical device. The analog layer thus directly controls the optical device including changing its settings based on input from the digital layer.

Abstract: A method and system for the remote controlling of appliances includes an adaptive remote controller that adapts itself automatically to its environment so as to remotely control a plurality of appliances. The adaptive remote controller is RF based and has the capability of two way communication with appliances. The adaptive remote controller provides information, alerts and help to a user.

Abstract: A four fiber ring network optical switching circuit capable of realizing the bridge function at times of the span switching and the ring switching economically by a very compact structure is disclosed. A four fiber ring network optical switching circuit is formed by a 10×8 optical matrix switch having ten input ports and eight output ports, and two branching elements adapted to branch each one of two optical signals among eight optical signals that are inputs of the four fiber ring network optical switching circuit, into two identical optical signals, and to enter the two identical optical signals into two input ports of the 10×8 optical matrix switch such that the eight optical signals are entered into the ten input ports of the 10×8 optical matrix switch as ten optical signals.

Abstract: A wireless communication device (10) includes a radio frequency transceiver (22) adapted for burst transmission responsive to a control signal in accordance with at least one communication protocol and an infrared transceiver (24) adapted for asynchronous data communication in coordination. The infrared transceiver (24) is responsive to the control signal to suspend an ongoing data communication for the duration of the burst transmission and to resume the data communication following the burst transmission. A controller (20) is coupled to each of the radio frequency communication module (22) and the infrared communication module (24), and the controller (20) is operable to generate the control signal in accordance with the at least one communication protocol.

Abstract: The present invention is directed to a bi-directional optical monitor interconnect. The bi-directional monitor interconnect of the present invention includes an optical conductor with a first and second end. Disposed on the first end of the optical conductor is a first optical communication device and a first optical receiving device. Disposed on the second end of the optical conductor is a second optical communication device and a second optical receiving device. The first and second optical communication devices are capable of transmitting data over an optical connection. The first optical communication device is suitable for communicating via a first wavelength and the second optical communication device is capable of communicating over a second wavelength. The first receiving device is capable converting the second wavelength into electrical signals and the second receiving device is capable of converting the first wavelength into electrical signals.

Abstract: The present invention relates to a spectrometer module comprising an input, for receiving an incoming optical signal, a variable differential group delay (DGD) element, for applying a variable birefringence retardation to said incoming optical signal, and a detector unit for detecting the power of a signal exiting said variable DGD element, having a defined state of polarization. It also relates to a monitor module, a monitoring unit and a monitoring system, comprising such a spectrometer module for use in monitoring an optical network. Further, the invention relates to a spectrometer device, for spectrometry purposes, comprising a spectrometer module as stated above.

Abstract: An optical communication system wherein a light emission circuit operates with reduced power consumption. The optical communication system is used in a communication network wherein communication is had between a control node and plural controlled nodes using light rays amplitude-modulated with carrier modulation signals over 6 MHz. The control node transmits a transmission permission signal to each controlled node, which starts or interrupts light emission with desired transient characteristics by having reference to the transmission permission signal. For example, the amplitude of the infrared light rays is increased or decreased over e.g., a period as indicated at I1.

Abstract: The invention relates to a router which may be used for amplification of a bidirectional optical signal using a single optical amplifier. An advantageous embodiment of the invention comprises two 3 dB couplers which are serially connected via a delay element. According to the embodiment, the delay element comprises a difference in distance &Dgr;L between the two optical branches which connect the two 3 dB couplers.

Abstract: The invention concerns a method of establishing and/or maintaining a wake mode in an electrical installation, which in addition to at least one receiving device has at least one transmitting device that is connected through an optical bus system. So as not to always have to operate the different devices in the stand-by mode when no data traffic takes place through the optical bus system, the state of the art proposes activating the receiving device only part of the time. If during that time the receiving device receives a corresponding signal from the transmitting device, the stand-by mode is ended in order to establish the data exchange. However this operating mode is also disadvantageous because of the power consumption.

Abstract: A multi-user remote control device characterised by comprising:

Abstract: Circuitry using infra-red (IR) diodes in remote control units. In one embodiment an IR LED is used both as a transmitter diode and also as a receiver diode responsive to light to thereby develop photocurrents and/or voltages for use by external circuitry. In a second embodiment an improved amplifier circuit is provided for an IR LED and IR photo detector diode which is mounted behind, and receives light through, the transmitter IR LED.

Abstract: A wake-up circuit for an electronic device comprises an input circuit (1) for receiving infrared signals and an amplifier (2) connected to the input circuit (1), the output of the amplifier being connected to a switching circuit (6) for switching on the device. To improve the signal/noise ratio it is provided that the input circuit (1) includes a parallel arrangement of at least two series arrangements of infrared detectors (7 to 10) as well as a parallel resonant circuit (11), and that the amplifier is a bandpass amplifier (2) the output of which is connected to a signal detector to which the switching circuit (6) is connected.

Abstract: An apparatus includes a controller for controlling operation of an appliance, an indicator light coupled to the controller to provide a visible indication of an operator selection in response to the controller energizing the indicator light, and a driver coupled to the controller and the indicator light so that the controller may communicate data through the indicator light by controlling the driver. The indicator light may be a light emitting diode or a segment of an alphanumeric display of an appliance control panel. A detector LED may also be coupled to the controller so the controller may receive data from an external device that communicates by flashing light on the detector LED. A terminal for communicating with the appliance may include a detector LED and a conductor that couples the detector LED to a diagnostic tool. The detector LED may receive data from an optical transmitter of the appliance control panel.

Abstract: An infrared communication module with remote control function includes a PD chip for IrDA data, an IC chip, an LED chip for IrDA data, and an LED chip for remote control transmission that are mounted on a PWB. The PD chip, IC chip and LED chips are sealed by a resin. The resin forms a light-receiving lens for infrared communication surrounding the PD chip, a light-emitting lens for infrared communication surrounding the LED chip for IrDA data, and a light-emitting lens for remote control surrounding the LED chip for remote control transmission. Such a structure allows an infrared communication module with remote control transmission function having a structure that can prevent increase in the cost of production and a mounting space.

Abstract: Disclosed are an interfacing system for stream source apparatus and display apparatus and an interfacing method thereof. The present invention includes a stream source apparatus receiving an analog or a digital signal from an external analog or digital equipment to generate a transmission packet stream corresponding to the analog or digital signal, the stream source apparatus formatting to transform the transmission packet stream into an optical signal form to transmit, and a display apparatus receiving the transmission packet stream transmitted from the stream source apparatus, the display apparatus formatting or decoding the transmission packet stream to separate into a video signal and an audio signal to output through a display screen and a speaker, respectively.

Abstract: A remote control system invention converts an infrared ray signal transmitted from an exclusive remote control transmitter of an electronic apparatus into a transmissive data by a signal analyzing/writing device, and writes the transmissive data in a nonvolatile memory, which is subsequently mounted on other remote control transmitter. A microcomputer in the remote control transmitter reads the transmissive data in the nonvolatile memory, and remote controls the electronic apparatus. Adoption of the present system enables a single unit of the remote control transmitter to remote control a plurality of electronic apparatuses by storing in the remote control transmitter transmissive data of different formats for the plurality of electronic apparatuses.

Abstract: The system for browsing objects in reality that enables a user to obtain information via a wireless browser-enabled device. The browser-enabled device includes a modulated laser that is directed toward target sensors located on or near objects for which information is sought by a user. The target sensors, in turn, relay information as well as information received from the modulated laser via Internet to a wireless network that serves the browser-enabled device of the user. Information concerning the object of interest is then relayed to the browser-enabled device allowing the user to view information concerning the object.