Abstract: Embodiments of the invention are generally directed to identification and handling of data streams using coded preambles. An embodiment of an apparatus includes an interface with a communication channel, transmitter coupled with the interface to transmit one or more data streams via the interface, and a processing element, the processing element to receive one or more data streams for transmission. Upon receiving multiple data streams for transmission of a first type of data, including a first data stream and a second data stream for transmission of the first type of data, the processing element is to select a first preamble for the first data stream and a second preamble for the second data stream, where the first preamble is distinguishable from the second preamble.

Abstract: Embodiments of the invention are generally directed to partial encryption of data stream. An embodiment of a method includes receiving, at a data transmitting device, a data stream having content including one or more of audio content, video content, and control content, determining one or more content that are to be encrypted. The method further includes partially encrypting the data stream by encrypting the one or more content, and leaving other content unencrypted, and transmitting, from the data transmitting device, the partially encrypted data stream to a data receiving device.

Abstract: Embodiments of the invention are generally directed to performing processing of content through partial authentication of secondary channel. An embodiment of a method includes performing a first authentication between a source transmitting device and a sink receiving device for communication of data streams, and performing a second authentication between the source transmitting device and a bridge device such that the second authentication is independent of the first authentication and the sink receiving device remains uninfluenced by the second authentication. The bridge device includes an intermediate carrier device coupled to the source transmitting device and the sink receiving device. The method further includes transmitting a data stream having encrypted content from the source transmitting device to the bridge device.

Abstract: An optical system has an optical component with a curved surface and zero optical power. The optical system is configured so that the optical component is the first optical structure encountered by radiation entering the optical system from externally thereof. According to a different aspect, a method is provided for making an optical system that has an optical component with a surface, where the optical component is the first optical structure encountered by radiation entering the optical system from externally thereof. The method includes configuring the surface to be curved, and configuring the optical component to have zero optical power.

Abstract: Embodiments of the invention are generally directed to video frame synchronization. An embodiment of a method includes receiving a first video data stream from a first source at a first port of a multi-port device, a first video frame of the first video data stream arriving at the first port at a first arrival time, and receiving a second video data stream from a second source at a second port of the multi-port device, a second video frame of the second video data stream arriving at the second port at a second arrival time. The method further includes determining an offset between the first arrival time and the second arrival time, determining one or more correction factors based at least in part on the offset, the one or more correction factors including a first correction factor for the first source, and sending a first command to the first source to modify a time of transmission by the first source of a third video frame following the first frame using the correction factor.

Abstract: Embodiments of the invention are generally directed to messaging to provide data link integrity. An embodiment of a method includes transmitting a data stream over a data link from a first device to a second device, the data stream including multiple frames, the data stream being transmitted in a first mode. The method further includes determining a data transmission mode change from the first mode to a second mode for the transmission of the data stream from the first device to the second device, generating mode packets, each mode packet including fields to define a plurality of mode elements, the fields of the mode packet being set to indicate the data transmission mode change, and transmitting the mode packets to the second device prior to implementing the data transmission mode change.

Abstract: A wavelength-conversion system includes a wavelength-conversion target that radiates an energy output when an energy input of a different wavelength is incident upon the wavelength-conversion target. An input structure directs the energy input of the input-energy wavelength to be incident upon the wavelength-conversion target. A target baseline temperature modifier either controllably heats or controllably cools the wavelength-conversion target independently of any heating or cooling effect of the energy input or the energy output. A detector is positioned so that the energy output of the output-energy wavelength emitted from the wavelength-conversion target is incident upon the detector.

Abstract: Embodiments of the invention are generally directed to signaling for transitions between modes of data transmission. A embodiment of a method includes transmitting a data stream over a data link from a first device to a second device, the data stream operating in a first mode; determining that the data stream is to be changed from the first mode to a second mode; and transmitting a message from the first device to the receiver over a control link, the message indicating that the first device will change the data stream from the first mode to the second mode, the message being sent prior to the change to the second mode.

Abstract: A weapon sight has an optical system that causes first radiation to propagate along a path of travel within the sight, and has a reticle generating portion that causes second radiation representing a reticle to propagate along the path of travel with the first radiation. The reticle generating portion includes a reticle illuminating portion that illuminates the reticle. The reticle illuminating portion includes a first light source having thereon a surface, light from the first light source passing through the surface and then illuminating the reticle. The reticle illuminating portion also includes a second light source spaced from the first light source, light from the second light source traveling toward the surface, being reflected and then illuminating the reticle.

Abstract: Embodiments of the invention are generally directed detection of encryption utilizing error detection for received data. An embodiment of a method includes selecting a first port for foreground processing of a stream of data received at the first port, the stream of data including content data, and sampling a set of data received at a second port, the second port being not selected for foreground processing, the set of data including a data packet and error correction data. The method further includes performing background processing of the set of data, wherein the background processing includes decrypting data of the data packet and utilizing the error correction data to determine whether the data packet contains an error, and determining whether data received at the second port is encrypted based at least in part on the determination whether the data packet contains an error.

Abstract: An optical system has an optical component with a curved surface and zero optical power. The optical system is configured so that the optical component is the first optical structure encountered by radiation entering the optical system from externally thereof. According to a different aspect, a method is provided for making an optical system that has an optical component with a surface, where the optical component is the first optical structure encountered by radiation entering the optical system from externally thereof. The method includes configuring the surface to be curved, and configuring the optical component to have zero optical power.

Abstract: A method and apparatus involve: using beam influencing structure to cause a converging beam of radiation to propagate along a first portion of a path of travel; supporting an optical part so that the path of travel extends through the optical part, the converging beam arriving at the optical part along the first portion of the path of travel, and the path of travel having a second portion along which the converging beam travels away from the optical part; and selectively tilting the optical part about a pivot axis lying in an imaginary plane extending transversely to the first portion of the path of travel, pivotal movement of the optical part about the pivot axis causing a change in the orientation of the second portion of the path of travel with respect to the first portion thereof.

Abstract: A path of travel for radiation extends to one optical element, then to another optical element, and then away from the latter. One of the optical elements is respectively reflective and non-reflective to radiation above and below a first wavelength, and the other is respectively reflective and non-reflective to radiation below and above a second wavelength. According to a different aspect, a path of travel for radiation extends to one of first and second optical elements, then to the other optical element, and then away from the latter. The first optical element is reflective and non-reflective to radiation on respective sides of a first wavelength, and the second optical element is reflective and non-reflective to radiation on respective sides of a second wavelength. The first optical element can tilt in relation to the path of travel to change the first wavelength.

Abstract: A method and apparatus involve an optical element having a passband with a center wavelength, and filtering radiation having first and second portions that arrive along a path of travel extending to the optical element. The first portion includes radiation inside the passband, and the second portion includes radiation above and below the passband. The optical element transmits one of the first and second portions of the radiation therethrough, and reflects the other of the first and second portions of the radiation therefrom. The optical element is supported for a range of movement relative to the path of travel. As the optical element moves through the range of movement, the center wavelength changes.

Abstract: According to one aspect, a part has two reflective surfaces, one being a conic surface portion having an axis with a focus thereon, and the other being part of a spherical surface with a centerpoint at the focus. According to a different aspect, a method includes fabricating a part with first and second reflective surfaces, the first being a conic surface portion with an axis and a focus on the axis, and the second being a spherical surface portion with a centerpoint at the focus. The second surface is used to position the part so that the focus coincides with the centerpoint of a spherical wave from an interferometer. Then, a reflective further spherical surface portion on a member is used with the interferometer to position a centerpoint of the further surface at the focus. The interferometer then evaluates the first surface for accuracy.

Abstract: A method and apparatus involve: supporting an optical part for movement in relation to a first path of travel of radiation; moving the part successively to first and second positions in which radiation arriving along the first path of travel passes respectively through first and second sections of the part that provide respective different levels of refraction, the first and second sections causing radiation to thereafter travel along respective second and third paths of travel; and receiving at an output first and second portions of radiation respectively propagating along the second and third paths of travel, the first and second portions containing different amounts of optical energy.

Abstract: A path of travel for radiation extends to one optical element, then to another optical element, and then away from the latter. One of the optical elements is respectively reflective and non-reflective to radiation above and below a first wavelength, and the other is respectively reflective and non-reflective to radiation below and above a second wavelength. According to a different aspect, a path of travel for radiation extends to one of first and second optical elements, then to the other optical element, and then away from the latter. The first optical element is reflective and non-reflective to radiation on respective sides of a first wavelength, and the second optical element is reflective and non-reflective to radiation on respective sides of a second wavelength. The first optical element can tilt in relation to the path of travel to change the first wavelength.

Abstract: A method and apparatus involve: using beam influencing structure to cause a converging beam of radiation to propagate along a first portion of a path of travel; supporting an optical part so that the path of travel extends through the optical part, the converging beam arriving at the optical part along the first portion of the path of travel, and the path of travel having a second portion along which the converging beam travels away from the optical part; and selectively tilting the optical part about a pivot axis lying in an imaginary plane extending transversely to the first portion of the path of travel, pivotal movement of the optical part about the pivot axis causing a change in the orientation of the second portion of the path of travel with respect to the first portion thereof.

Abstract: A system and apparatus are described in which modular receptacles are filled and transported to automated dispensing machines for later retrieval and distribution. A system of the present invention includes the loading, refilling, and replacement of the modular receptacles at various stages in the process of the invention. The present invention results in a more efficient and easier to manage system for distribution of such items as medical supplies and drugs.

Abstract: An optical structure routes radiation from an optical input to an optical output, the radiation being successively reflected by orthogonal first, second and third reflective surfaces of a linearly movable section, and departing the section in a departure direction substantially opposite its arrival direction. The section can move approximately parallel to the arrival direction with respect to at least one of the optical input and optical output. A different aspect involves: routing radiation from an optical input to an optical output, including reflecting this radiation successively from orthogonal first, second and third reflective surfaces of a section of the structure, the radiation departing the section in a departure direction substantially opposite its arrival direction; and supporting the section for approximately linear movement approximately parallel to the arrival direction with respect to at least one of the optical input and optical output.