Abstract: In one example embodiment, a transmitter module includes a header electrically coupled to a chassis ground. First and second input nodes are configured to receive a differential data signal. A buffer stage has a first node coupled to the first input node and a second node coupled to the second input node. An amplifier stage has a fifth node coupled to a third node of the buffer stage and a sixth node coupled to a signal ground that is not coupled to the chassis ground. An optical transmitter has an eighth node coupled to a seventh node of the amplifier stage and a ninth node configured to be coupled to a voltage source. A bias circuit is configured to couple a fourth node of the buffer stage to a bias current source.

Abstract: Ligand compositions for use in preparing discrete coated nanostructures are provided, as well as the coated nanostructures themselves and devices incorporating same. Methods for post-deposition shell formation on a nanostructure, for reversibly modifying nanostructures, and for manipulating the electronic properties of nanostructures are also provided. The ligands and coated nanostructures of the present invention are particularly useful for close packed nanostructure compositions, which can have improved quantum confinement and/or reduced cross-talk between nanostructures. Ligands of the present invention are also useful for manipulating the electronic properties of nanostructure compositions (e.g., by modulating energy levels, creating internal bias fields, reducing charge transfer or leakage, etc.).

Abstract: A modular device for an optical communication module configured to be coupled to an optical transmission medium. The modular device may include a first edge and a second edge and N number of electrical circuit channels between the first and second edges. Each electrical circuit channel may include at least one element configured to provide functionality for communicating optical signals through the optical transmission medium. The modular device may also have a width between the first and second edges so that each of the N number of electrical circuit channels of C number of modular devices aligns with one of P number of interface channels of an opto-electrical interface configured to be coupled to the optical transmission medium when C equals P/N and C is a whole number greater than zero.

Abstract: Systems and methods for displaying content pre-delivered to a user device, playing back content pre-delivered to a user device, and/or pre-delivering content to a user device during concurrent content playback, are described. In some embodiments, the systems and methods include or interact with a mobile application that displays descriptions of content available for playback via the mobile application along with indicators that represent a state of delivery (e.g., a state of pre-delivery) for the content items.

Abstract: A method of compensating for electromagnetic radiation. The method may include measuring electromagnetic radiation emanating from circuitry at a first frequency and adjusting at least one of the electrical settings of the circuitry based on the measurement of the electromagnetic radiation to reduce the electromagnetic radiation at the first frequency emanating from the circuitry.

Abstract: The present disclosure relates to a suture anchor inserter. The suture anchor inserter includes a handle having a proximal component, a central component coupled to the proximal component, and a distal component coupled to the proximal component and the central component, the central component capable of rotating relative to the proximal component; and a shaft comprising a proximal end and a distal end, the proximal end coupled to the handle. A method of inserting a suture anchor into bone is also disclosed.

Abstract: A circuit may include a photodiode configured to receive an optical signal and convert the optical signal to a current signal. The circuit may also include a transimpedance amplifier coupled to the photodiode and configured to convert the current signal to a voltage signal. The circuit may also include an equalizer coupled to the transimpedance amplifier and configured to equalize the voltage signal to at least partially compensate for a loss of a high frequency component of the optical signal. The equalizer and the transimpedance amplifier may be housed within a single integrated circuit.

Abstract: The present disclosure relates to a suture anchor inserter. The suture anchor inserter includes a handle having a proximal component, a central component coupled to the proximal component, and a distal component coupled to the proximal component and the central component, the central component capable of rotating relative to the proximal component; and a shaft comprising a proximal end and a distal end, the proximal end coupled to the handle. A method of inserting a suture anchor into bone is also disclosed.

Abstract: In one example embodiment, a transmitter module includes a header electrically coupled to a chassis ground. First and second input nodes are configured to receive a differential data signal. A buffer stage has a first node coupled to the first input node and a second node coupled to the second input node. An amplifier stage has a fifth node coupled to a third node of the buffer stage and a sixth node coupled to a signal ground that is not coupled to the chassis ground. An optical transmitter has an eighth node coupled to a seventh node of the amplifier stage and a ninth node configured to be coupled to a voltage source. A bias circuit is configured to couple a fourth node of the buffer stage to a bias current source.

Abstract: A serializer circuit may include a recovery circuit, an adjusting circuit, and a multiplexer circuit. The recovery circuit may be configured to receive a first data signal at a first frequency, to generate a first clock signal at the first frequency using the first data signal, and to retime the first data signal based on the first clock signal to generate a retimed first data signal. The adjusting circuit may be configured to receive a second data signal and retime the second data signal based on the first clock signal to generate a retimed second data signal. The multiplexer circuit may be configured to multiplex the retimed first data signal and the retimed second data signal.

Abstract: The present disclosure relates to a suture anchor inserter. The suture anchor inserter includes a handle having a proximal component, a central component coupled to the proximal component, and a distal component coupled to the proximal component and the central component, the central component capable of rotating relative to the proximal component; and a shaft comprising a proximal end and a distal end, the proximal end coupled to the handle. A method of inserting a suture anchor into bone is also disclosed.

Abstract: In an example embodiment, a phase-locked loop circuit may include a first circuitry to receive a reference signal and a source signal. The first circuitry may generate a correction signal for demonstrating a difference in phase between the reference signal and the source signal. The phase-locked loop may include a second circuitry to receive the correction signal. The second circuitry may generate a digital signal for demonstrating a phase-to-digital conversion of the correction signal. The phase-locked loop may include a third circuitry to receive the digital signal. The third circuitry may generate a control signal for demonstrating a converted voltage of the digital signal. The phase-locked loop may include a fourth circuitry to receive the control signal. The fourth circuitry may generate the source signal in response to the control signal.

Abstract: An optically enabled multi-chip module has an optical engine transceiver and a host system chip. The optical engine transceiver has an optical engine front-end and an optical engine macro. The optical engine front-end has multiple laser diodes, laser driver circuitry electrically interfaced with each of the laser diodes, multiple photodiodes, amplifier circuitry electrically interfaced with each of the photodiodes, and at least one optical element optically positioned between the laser diodes and at least one optical fiber and between the photodiodes and the at least one optical fiber. The at least one optical element optically interfaces the laser diodes and photodiodes with the optical fiber. The optical engine macro is both electrically interfaced with and physically segregated from the optical engine front-end. The optical engine macro provides a subset of optical transceiver functionality to the optical engine front-end. The host system chip is electrically interfaced with the optical engine transceiver.

Abstract: A circuit may include a photodiode configured to receive an optical signal and convert the optical signal to a current signal. The circuit may also include a transimpedance amplifier coupled to the photodiode and configured to convert the current signal to a voltage signal. The circuit may also include an equalizer coupled to the transimpedance amplifier and configured to equalize the voltage signal to at least partially compensate for a loss of a high frequency component of the optical signal. The equalizer and the transimpedance amplifier may be housed within a single integrated circuit.

Abstract: Systems and methods for delivering content to user devices before the content is selected or requested (e.g., a pre-delivery of content) are described. In some embodiments, the system and methods receive, from a content server, information associated with content items available for retrieval from the content server and associated with one or more applications resident on a user device, select a subset of content items from the content items available for retrieval to deliver to the user device based on content usage information associated with the user device, and cause the user device to retrieve at least a portion of the selected subset of content items from the content server.

Abstract: Systems and methods for delivering content to user devices before the content is selected or requested (e.g., a pre-delivery of content) are described. In some embodiments, the system and methods receive, from a content server, information associated with content items available for retrieval from the content server and associated with one or more applications resident on a user device, select a subset of content items from the content items available for retrieval to deliver to the user device based on content usage information associated with the user device, and cause the user device to retrieve at least a portion of the selected subset of content items from the content server.

Abstract: In one example embodiment, a transmitter module includes a header electrically coupled to a chassis ground. First and second input nodes are configured to receive a differential data signal. A buffer stage has a first node coupled to the first input node and a second node coupled to the second input node. An amplifier stage has a fifth node coupled to a third node of the buffer stage and a sixth node coupled to a signal ground that is not coupled to the chassis ground. An optical transmitter has an eighth node coupled to a seventh node of the amplifier stage and a ninth node configured to be coupled to a voltage source. A bias circuit is configured to couple a fourth node of the buffer stage to a bias current source.

Abstract: Systems and methods for discovering content sources and/or delivering content to applications resident on mobile devices are described. In some embodiments, the systems and methods transmit information identifying one or more applications resident on a mobile device to a server, receive, from the server, information associated with content items available for retrieval from a content server and associated with the identified one or more applications, and cause the mobile device to retrieve at least one of the content items available for retrieval from the content server.

Abstract: An eye safety mechanism for use with a bi-directional data cable having an electrical interface at at least one (but potentially both) ends, despite the fact that the cable communicates over much of its length using a bi-directional optical channel. Upon power-up, the eye safety mechanism determines whether or not a loss of signal condition is present on an optical receive channel of the bi-directional data cable. If the loss of signal is present, the mechanism intermittently disables the optical transmit channel of the bi-directional data cable. On the other hand, if the loss of signal is not present, the mechanism enables the optical transmit channel of the bi-directional data cable without intermittently disabling transmission at least for most of the time until the next time a loss of signal is detected on the optical receive channel.

Abstract: A method and an apparatus for propagating a message in a social network are disclosed. A method for propagating a message in a social network according to an embodiment of the invention can include: calculating a degree of connectivity of each user; calculating a propagation capability of each user by using the calculated degree of connectivity and a probability of distribution; choosing target users for propagating a message by using the propagation capability of each user; and propagating the message to nodes of the chosen target users.