In one example, a system includes an oscillator adapted to provide an oscillator signal, a frequency divider adapted to divide the oscillator signal to provide a divided oscillator signal, and a phase-frequency detector adapted to provide phase-frequency detection signals in response to a reference clock signal and the divided oscillator signal. The system also includes a charge pump adapted to provide first output signals in response to the phase-frequency detection signals, a phase detector adapted provide second output signals in response to an incoming data signal and the oscillator signal, and one or more switches adapted to pass the first output signals during a frequency acquisition mode and pass the second output signals during a phase lock mode. The system also includes an active filter adapted to filter the passed first or second output signals. The oscillator is adapted to adjust a frequency of the oscillator signal in response to the filtered first or second output signals.
Systems and methods are provided to calibrate and compensate for signal impairments from the use of cables in data communication devices. Signal impairments such as intra-pair skew of differential signals and frequency dependent insertion loss are measured during a calibration phase. One end of the cable is connected to a communication device. The other end of the cable is configured to loop back calibration signals transmitted from the communication device. The calibration signals looped back from the communication device are received and measured by the communication device. The measured impairments are used to determine transmit and receive impairment compensation settings to compensate for impairments caused by the cable. These settings are stored and used to adjust signals transmitted from the communication device to compensate for the transmit impairment. These setting are also used to adjust signals received by the communication device to compensate for the receive impairment.
Various techniques are provided to support efficient data transfers over serial data streams. In one example, a serial device may be used to efficiently transfer data between a host device and the serial device over a data stream of a serial interface. A data stream value identifying the data stream may be stored in a register indexed by a tag associated with a command received from the host device. The command may be passed to a storage media device, wherein the passing is controlled by a processor of the serial device. The tag may be extracted from an address value received from the storage media device in response to execution of the command by the storage media device. The data stream value may be retrieved from the register using the extracted tag as an index without requiring an interrupt to the processor to determine the data stream value.
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
G06F 13/00 - Interconnexion ou transfert d'information ou d'autres signaux entre mémoires, dispositifs d'entrée/sortie ou unités de traitement
G06F 13/12 - Commande par programme pour dispositifs périphériques utilisant des matériels indépendants du processeur central, p. ex. canal ou processeur périphérique
4.
OVERCOMING LIMITED COMMON-MODE RANGE FOR USB SYTEMS
An intelligent level shifter may be added to adjust the voltage level on the data lines (D+ and D-) used for communications in USB systems, to address the issue of missing negative common-mode range as defined by the USB specification. The level shifter may be part of a port power controller that allows adaptive shifting of the signal level in accordance with the current levels drawn on the supply line by a device, for example during charging. The port power controller may be operated in systems enabled for battery charging, and may combine overcurrent sensing (current meter for VBus) and the routing of the D+ and D- lines (used for the battery charging protocol) into a single package. By varying the voltage levels on the D+ and D- data lines according to the drawn current levels, the performance of USB Hosts ports and USB Hub ports may be greatly increased.
System and method for generating clock signal for a plurality of communication ports by selectively dividing a reference clock signal with a plurality of ratios
Various techniques are provided to generate a plurality of reference clock signals using a single reference clock signal generator. In one example, a clock signal generation system includes a reference clock signal generator adapted to provide a reference clock signal. The system also includes a plurality of dividers adapted to divide the reference clock signal using different ratios to provide a plurality of communication port clock signals. The system also includes a plurality of different communication ports adapted to receive the communication port clock signals and adapted to operate in accordance with different communication protocols using the communication port clock signals.
Systems and methods are disclosed for improving digital feed-forward data recovery of high speed data from a received data stream in a data transceiver or receiver where the receiver clock is asynchronous to the transmitter clock used to transmit the received data stream. In one example, the received data stream is oversampled using N evenly-spaced multi-phase clocks. The oversampled data are packed into a data block. Data transition edges of the oversampled data in the data blocks with respect to multi-phase clocks are tracked. The tracked data transition edges are used to determine the length of a decision window and to further divide the oversampled data into groups of bits that are hypothesized to be samples of the same received data symbol. Bit mapping is performed on the decision window to recover the received data symbol. By tracking the movement of data transition edges, the technique enhances data recovery capability.
Various techniques are provided for hosting storage media devices using multi-port devices having a plurality of ports. For example, in one embodiment, a method of operating a multi-port device includes detecting whether a host device or a storage media device is connected to a first port of the multi-port device or a second port of the multi-port device. The method also includes, if the host device is connected to the first port, configuring the first port as a slave port and operating the multi-port device as a slave hosted by the host device. The method also includes, if the host device is connected to the second port and the storage media device is connected to the first port, configuring the first port as a host port and hosting the storage media device from the multi-port device.
G06F 13/00 - Interconnexion ou transfert d'information ou d'autres signaux entre mémoires, dispositifs d'entrée/sortie ou unités de traitement
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
8.
Communication system and method for synchronizing a plurality of network nodes after a network lock condition occurs
A communication system and method is provided herein for synchronizing a plurality of network nodes after a network lock condition occurs within a network. According to one embodiment, the method may generate a local trigger signal simultaneously at each of the plurality of network nodes by compensating for unique phase delays attributed to each of the plurality of network nodes. As described herein, the local trigger signals may be used for synchronizing devices, such as multimedia devices, which may be coupled to the network nodes. More specifically, the local trigger signals may be used to synchronize events occurring within devices, which are coupled to different nodes of the network.
System and method for a USB host to determine whether or not a USB device provides power via a USB coupling between the USB host and the USB device. At a first time, it may be determined that the USB device is coupled to the USB host via a USB coupling and does not provide power. Power may be provided to the USB device via the USB coupling. At a second time it may be determined that the USB device does provide power via the USB coupling. Power may no longer be provided to the USB device via the USB coupling after it is determined that the USB device does provide power via the USB coupling. A battery of the USB host may be charged using power provided by the USB device via the USB coupling based on determining that the USB device does provide power via the USB coupling.
A port power switch (PPS) may be used for lead compensation in systems where power is provided to a connected device by a switch-mode power supply (SMPS). The PPS may be designed to co-operate with the SMPS, providing a mechanism for the feedback reference point of the SMPS to be automatically switched, in the event of system fault or some other condition that might result in the PPS entering an “OFF’ operating mode, from the application point of load (POL) to the voltage input pin of the PPS without loss of power path continuity. The switching mechanism and the PPS may be manufactured to reside on the same integrated circuit. The PPS may include a control block that generates a control signal to couple the feedback port of the SMPS to the POL under normal operation, and to the voltage input port of the PPS during a fault condition.
An intelligent level shifter may be added to adjust the voltage level on the data lines (D+ and D−) used for communications in USB systems, to address the issue of missing negative common-mode range as defined by the USB specification. The level shifter may be part of a port power controller that allows adaptive shifting of the signal level in accordance with the current levels drawn on the supply line by a device, for example during charging. The port power controller may be operated in systems enabled for battery charging, and may combine overcurrent sensing (current meter for VBus) and the routing of the D+ and D− lines (used for the battery charging protocol) into a single package. By varying the voltage levels on the D+ and D− data lines according to the drawn current levels, the performance of USB Hosts ports and USB Hub ports may be greatly increased.
Various techniques are provided to facilitate a detection system to detect a presence of an externally coupled receiver device, such as a universal serial bus (USB) device. In one example, the system generates a reference current and passes the reference current via a conductor to a shared buffer circuit. The shared buffer circuit is adapted to selectively pass the reference current or a communication signal to the externally coupled receiver device. The system switches between a detect mode where the reference current is provided to the externally coupled receiver device and between a communicate mode where the reference current is blocked and the communication signal is provided to the externally coupled receiver device. The system monitors a voltage value of the conductor and the system monitors a time for the voltage value to reach a pre-determined threshold value in response to the reference current. The system detects a presence of the externally coupled receiver device based on the monitored time.
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
H02J 7/00 - Circuits pour la charge ou la dépolarisation des batteries ou pour alimenter des charges par des batteries
A circuit that supports multiple monitors, docking functions, and protected content via one cable. The circuit includes a receiver that receives multiple video streams, each including respective video data, a mux/demux, coupled to the receiver, that determines which video stream to display on a monitor, a display interface coupled to the first mux/demux, wherein the display interface is configured to generate output signals based on the video data of the determined video stream to be displayed on the first monitor, a transmitter coupled to the mux/demux, and a transmit physical interface (TPI) coupled to the transmitter. The mux/demux sends at least a remainder of the video streams to the transmitter, which sends them to the TPI, which transmits them as output, useable as input to further instances of the circuit.
G09G 5/00 - Dispositions ou circuits de commande de l'affichage communs à l'affichage utilisant des tubes à rayons cathodiques et à l'affichage utilisant d'autres moyens de visualisation
H04N 9/67 - Circuits pour le traitement de signaux de couleur pour le matriçage
G06F 3/14 - Sortie numérique vers un dispositif de visualisation
Proximity based system and method for detecting user gestures. Each of a plurality of proximity sensing circuits may collect digital data. Each proximity sensing circuit may include an antenna configured to transmit and receive electromagnetic signals and a shield driver configured to shield signals transmitted by the antenna in one or more directions. The digital data may be collected based on electromagnetic signals received from another proximity sensing circuit via the antenna. The received electromagnetic signals may be modified by one or more user proximity gestures. The digital data from each of the plurality of proximity sensing circuits may be received by a coordinating circuit. The coordinating circuit may produce coordinated digital data from the digital data received from each of the plurality of proximity sensing circuits. The coordinated digital data may be configured for use in determining that a user performed the one or more user proximity gestures.
Charging a device using a plurality of handshakes. A first device may provide a first handshake to a second device. A device of a first device type may be configured to charge its battery without further communication based on the first handshake. The first device may monitor a connection to the second device for a second handshake corresponding to a device of a second device type. In response to detecting the second handshake, the first device may provide a response to the second device. Accordingly, the second device of the second device type may be configured to charge its battery based on the second handshake.
Charging a device using a plurality of handshakes. A first device may provide a first handshake to a second device. A device of a first device type may be configured to charge its battery without further communication based on the first handshake. The first device may monitor a connection to the second device for a second handshake corresponding to a device of a second device type. In response to detecting the second handshake, the first device may provide a response to the second device. Accordingly, the second device of the second device type may be configured to charge its battery based on the second handshake.
Various techniques are provided to detect a state of a communication signal. In one example, a method of detecting a state of a signal includes receiving a differential communication signal comprising a positive portion and a complementary negative portion. The method also includes generating a common mode voltage signal from the positive portion and the negative portion of the communication signal. The method also includes rectifying the positive portion and the negative portion of the communication signal to provide a rectified signal. The method also includes comparing the common mode voltage, signal with the rectified signal. The method also includes generating a high frequency detect signal in response to the comparing. The method also includes determining whether the communication signal is in an idle state or a high frequency state based on the high frequency detect signal.
H04K 1/10 - Communications secrètes en utilisant deux signaux transmis simultanément ou successivement
H04M 1/64 - Dispositions automatiques pour répondre aux appelsDispositions automatiques pour enregistrer des messages pour abonnés absentsDispositions pour enregistrer des conversations
H04M 1/00 - Équipement de sous-station, p. ex. pour utilisation par l'abonné
19.
Switching system which allows primary USB connection in response to USB signaling
System and method controlling connectivity within a device. A device may be coupled to a host device. In response to the coupling, low power logic (e.g., an embedded device) of the device may be coupled to the host device. The low power logic may perform enumeration with the host device using only power provided by the host device. The low power logic may also charge a battery of the device using power provided by the host device. Device circuitry of the device may provide a signal for coupling to the host device. In response, the device circuitry may be coupled to the host device and may perform device enumeration with the host device.
G06F 15/177 - Commande d'initialisation ou de configuration
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
H02J 7/00 - Circuits pour la charge ou la dépolarisation des batteries ou pour alimenter des charges par des batteries
G06F 13/42 - Protocole de transfert pour bus, p. ex. liaisonSynchronisation
20.
COMMUNICATING BETWEEN AN OPTICAL RECEIVER AND AN OPTICAL TRANSMITTER USING A SERIAL BUS
An optical receiver, within a first device, may receive first configuration information from an optical transmitter, also within the first device. While receiving the first configuration information, the optical receiver may operate according to a clock. Later, the optical receiver may receive optical data from a second device according to the first configuration. While receiving the optical data from the second device, the optical receiver does not operate according to the clock, wherein the optical receiver not operating according to the clock allows the optical receiver to receive the optical data with greater sensitivity.
An optical receiver, within a first device, may receive first configuration information from an optical transmitter, also within the first device. While receiving the first configuration information, the optical receiver may operate according to a clock. Later, the optical receiver may receive optical data from a second device according to the first configuration. While receiving the optical data from the second device, the optical receiver does not operate according to the clock, wherein the optical receiver not operating according to the clock allows the optical receiver to receive the optical data with greater sensitivity.
Assembling an optical transceiver. A connector housing for a semiconductor package may be received. The connector housing may include a first alignment feature for assembling the optical transceiver. Additionally, a semiconductor package may be received. The semiconductor package may include a leadframe that has a second alignment feature which is complementary to the first alignment feature. The semiconductor package may be attached to the connector housing to form the optical transceiver by aligning the second alignment feature of the leadframe of the semiconductor package with the first alignment feature of the connector housing. This alignment may operate to align an optical axis a fiber optic transmitter and/or a fiber optic receiver with a corresponding fiber optic connector.
Various techniques are provided to detect a state of a communication signal. In one example, a method of detecting a state of a signal includes receiving a differential communication signal comprising a positive portion and a complementary negative portion. The method also includes filtering the positive portion of the communication signal through a first low pass filter to provide a filtered positive portion of the communication signal. The method also includes filtering the negative portion of the communication signal through a second low pass filter to provide a filtered negative portion of the communication signal. The method also includes comparing the filtered positive portion of the communication signal with an internal reference voltage. The method also includes comparing the filtered negative portion of the communication signal with the internal reference voltage. The method also includes generating a low frequency detect signal in response to the comparing operations to indicate whether the communication signal is in a low frequency state.
Various techniques are provided for selectively allocating a buffer adapted to be shared for storage media device data communications and downstream device data communications routed through a hub. For example, in one embodiment, a method includes detecting if one or more downstream devices are connected to one or more downstream device ports of the hub. The method also includes, if any downstream devices are detected: allocating a first portion of the buffer for a storage media device controller, allocating one or more second portions of the buffer for the detected downstream devices, wherein each of the second portions is associated with a corresponding one of the detected downstream devices, and passing the storage media device data communications between a host device and the storage media device controller through the first portion of the buffer and not the second portions of the buffer.
G06F 15/167 - Communication entre processeurs utilisant une mémoire commune, p. ex. boîte aux lettres électronique
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
25.
High speed USB hub with full speed to high speed transaction translator
High speed USB hub with full speed to high speed transaction translator. A USB hub may include an upstream port for coupling to a host and one or more downstream ports for coupling to downstream devices. The downstream devices may operate at USB high speed. The USB hub may support hosts which operate at speeds less than high speed (e.g., full speed). Accordingly, when a host operates at a lower speed, a transaction translator may convert the communications from the host from the lower speed to the high speed. Accordingly, the downstream device may still operate at high speed even when the host operates at a lower speed.
G06F 13/00 - Interconnexion ou transfert d'information ou d'autres signaux entre mémoires, dispositifs d'entrée/sortie ou unités de traitement
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
Systems and methods are provided to permit indirect measurements of sample time errors using multiphase interpolator clocks generated from a local reference clock in clock recovery blocks of high speed data receivers. The multiphase interpolator clocks are adjusted to have substantially evenly spaced phase offsets within a data period of the local reference clock. A small frequency offset between the transmitter clock and the local reference clock causes transition edges of received data to drift slowly across the interpolated clocks. Differences in phase offsets between the interpolated clocks may be determined with high resolution by counting the number of data transitions occurring between pairs of interpolated clocks over a long period of time. Phase offsets are adjusted to make the data transition counts substantially the same for the interpolated clocks. Data recovery may then be facilitated by selecting an interpolated clock with a sampling edge that is closest to the center of a data period to sample the received data.
System and method controlling connectivity within a device. A device may be coupled to a host device. In response to the coupling, low power logic (e.g., an embedded device) of the device may be coupled to the host device. The low power logic may perform enumeration with the host device using only power provided by the host device. The low power logic may also charge a battery of the device using power provided by the host device. Device circuitry of the device may provide a signal for coupling to the host device. In response, the device circuitry may be coupled to the host device and may perform device enumeration with the host device.
G06F 15/177 - Commande d'initialisation ou de configuration
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
G06F 1/26 - Alimentation en énergie électrique, p. ex. régulation à cet effet
Various embodiments of a radio-frequency (RF) transmitter receiver circuit that utilizes an injection locked oscillator may allow for the introduction of a DC offset to correct the RF signal. The DC offset may be adjusted to eliminate (or minimize) even order harmonics to correct for RF effects. The DC offset correction may be performed around the injection locked oscillator to target even order terms.
Transmit power control functionality in wireless audio systems may be implemented by way of a Transmit Power Control (TPC) algorithm devised to control power for both source and sinks in a multi sink session, to reduce power consumption. Information may be passed back and forth between the source and sink devices to adjust power based on the shared information. The TPC algorithm may allow power control on both ends of an RF link, and may have multiple sink devices communicating with a source device. Furthermore, the multiple sink devices and the source device may each be operating at different power levels, and adjust their respective power levels as instructed by the TPC algorithm. Power control is therefore implemented on both ends of the link, where multiple sources and sinks may all operate at different power levels, and all individually adjust their respective power levels.
H04W 52/24 - Commande de puissance d'émission [TPC Transmission power control] le TPC étant effectué selon des paramètres spécifiques utilisant le rapport signal sur parasite [SIR Signal to Interference Ratio] ou d'autres paramètres de trajet sans fil
H04W 52/48 - Commande de puissance d'émission [TPC Transmission power control] le TPC étant effectué dans des situations particulières lors d'une retransmission après erreur ou en l’absence d’accusé de réception
30.
Reducing power consumption in sink devices by having sinks receive only left audio channel or right audio channel
A wireless audio device may realize power savings when processing multi-channel data, e.g. 2-channel stereo audio data, by splitting the multi-channel block data into separate data blocks for each channel, e.g. Left-channel data block and Right-channel data block, and processing each separate data block independently in the source device to generate respective data packets targeting corresponding sink devices, e.g. a Left earphone and a Right earphone. The source device may then transmit each data packet to a different corresponding sink device, e.g. a Left-channel packet to a Left earphone and a Right-channel packet to a Right earphone. The data packets may also include header information indicative of whether a next packet is intended for a given sink device, enabling sink devices to enter sleep mode when the header information indicates that a next packet is not intended for the given sink device, to save power.
H04H 20/47 - Dispositions caractérisées par des circuits ou composants spécialement adaptés à la radiodiffusion spécialement adaptés aux systèmes de radiodiffusion couverts par les groupes spécialement adaptés aux systèmes de radiodiffusion stéréophonique
H04H 20/88 - Systèmes de radiodiffusion stéréophonique
H04H 40/36 - Dispositions caractérisées par des circuits ou composants spécialement adaptés à la réception spécialement adaptés aux systèmes de radiodiffusion couverts par les groupes spécialement adaptés à la réception de la radiodiffusion stéréophonique
31.
Low-power class D amplifier using multistate analog feedback loops
nd order noise shaping may be performed at low power, with an optimized filter included in the feedback loop to achieve the best noise reduction at low power. Operation of the amplifier feedback network may be similar to that of a continuous time, low-pass delta-sigma modulator, but with a PWM loop wrapped around the class-D power amplifier.
Systems and methods are disclosed for improving the accuracy of phase spacing of multiphase clocks. In one example, method includes receiving a reference clock having a first frequency and sampling the reference clock with a plurality of multiphase clocks having a second frequency to generate a plurality of samples. The second frequency is a non-integer multiple of the first frequency. The method also includes detecting transitions of the reference clock occurring between the samples generated from a plurality of pairs of the multiphase clocks and counting the transitions to generate a transition count for each pair of the multiphase clocks. The method also includes summing a set of the transition counts to generate a measured phase for a first multiphase clock, calculating a reference phase for the first multiphase clock, and generating a phase skew value for the first multiphase clock based on the measured phase and the reference phase.
Systems and methods for a mass storage device attached to a host device use speculation about the host command likely to be received next from the host device based on a previously received command to improve throughput of accesses to the mass storage device. Host commands are used to speculatively produce commands for data storage devices of the mass storage device, such that host commands speculated as being likely next can be started during idle time of the data storage devices, based upon the probability that the speculation will be correct some of the time, and otherwise wasted idle time will be more efficiently used. Time taken by the host device to produce successive commands to the mass storage system is monitored, and future speculatively produced commands are parameterized to complete within the observed host time to produce new commands, making more efficient use of the data storage devices.
G06F 3/00 - Dispositions d'entrée pour le transfert de données destinées à être traitées sous une forme maniable par le calculateurDispositions de sortie pour le transfert de données de l'unité de traitement à l'unité de sortie, p. ex. dispositions d'interface
34.
Software controlled power limiting in USB to SATA bridge
A Universal Serial Bus (USB) to Serial ATA (SATA) bridge device and method for operating same in a USB connected mass storage subsystem supports software management of power consumption. The USB to SATA bridge estimates power consumption based on known power consumption characteristics of SATA disk drives when performing commands involved in accessing SATA drive, or takes measurements of power consumption during execution of commands to determine when responses to a USB host device are to be delayed. By selectively delaying responses to the USB host device issuing the commands, the USB to SATA bridge manages the rate at which the host issues commands to the USB mass storage subsystem and is thereby able to automatically limit power consumption of the USB mass storage subsystem to that that available over the USB link.
A circuit that supports multiple monitors, docking functions, and protected content via one cable. The circuit includes a receiver that receives multiple video streams, each including respective video data, a mux/demux, coupled to the receiver, that determines which video stream to display on a monitor, a low-voltage differential signaling (LVDS) converter, coupled to the mux/demux, that generates an LVDS signal based on the video data of the determined video stream, an LVDS serializer/deserializer, coupled to the LVDS converter, that generates a signal based on the LVDS signal and sends the signal to a display panel of the monitor for display, a transmitter coupled to the mux/demux, and a transmit physical interface (TPI) coupled to the transmitter. The mux/demux sends at least a remainder of the video streams to the transmitter, which sends them to the TPI, which transmits them as output, useable as input to further instances of the circuit.
G09G 5/00 - Dispositions ou circuits de commande de l'affichage communs à l'affichage utilisant des tubes à rayons cathodiques et à l'affichage utilisant d'autres moyens de visualisation
A circuit that supports multiple monitors, docking functions, and protected content via one cable. The circuit includes a receiver that receives multiple video streams, each including respective video data, a mux/demux, coupled to the receiver, that determines which video stream to display on a monitor, a low-voltage differential signaling (LVDS) converter, coupled to the mux/demux, that generates an LVDS signal based on the video data of the determined video stream, an LVDS serializer/deserializer, coupled to the LVDS converter, that generates a signal based on the LVDS signal and sends the signal to a display panel of the monitor for display, a transmitter coupled to the mux/demux, and a transmit physical interface (TPI) coupled to the transmitter. The mux/demux sends at least a remainder of the video streams to the transmitter, which sends them to the TPI, which transmits them as output, useable as input to further instances of the circuit.
Various methods, devices, systems, and machine readable mediums are provided which may be used in accordance with a protocol, such as a protocol used to support the transfer of data and commands between a host and a device. In one embodiment, a driver on a host device may be used to implement a protocol to provide support for various features of the universal serial bus (USB) attached storage (UAS) protocol when interfacing the host device with one or more connected devices that are compatible with either the USB 2.0 standard or the USB 3.0 standard. In this regard, a single driver on the host device may be used to support USB 2.0 and USB 3.0 devices. In another embodiment, such a protocol may be used to support USB 3.0 devices without requiring USB 3.0 streaming capabilities to be supported by host devices or connected devices.
G05F 3/16 - Régulation de la tension ou du courant là où la tension ou le courant sont continus utilisant des dispositifs non commandés à caractéristiques non linéaires consistant en des dispositifs à semi-conducteurs
The transfer of media transmitted from a media provider from a first rendering device to a second includes establishing a network connection between the media provider and the second rendering device based on a network location and session context information. A desired transmission duplication of the media is determined such that the duplication will prevent substantial interruption of the rendering of the media as experienced by a user listening to both of the rendering devices, and that desired transmission duplication is sent to both the first rendering device and the second rendering device. The transmission is continued from the media provider to the second rendering device.
A wireless adapter enables communication between a content source and a content player for rendering of content at the content source by the content player, and a remote controller allows for control of the content delivery, and one or more features of the content source, player, or both.
H04N 7/16 - Systèmes à secret analogiquesSystèmes à abonnement analogiques
H04N 7/24 - Systèmes pour la transmission de signaux de télévision utilisant la modulation par impulsions codées
H04N 21/41 - Structure de clientStructure de périphérique de client
H04N 21/422 - Périphériques d'entrée uniquement, p. ex. système de positionnement global [GPS]
H04N 21/436 - Interfaçage d'un réseau de distribution local, p. ex. communication avec un autre STB ou à l'intérieur de la maison
H04N 21/4402 - Traitement de flux élémentaires vidéo, p. ex. raccordement d'un clip vidéo récupéré d'un stockage local avec un flux vidéo en entrée ou rendu de scènes selon des graphes de scène du flux vidéo codé impliquant des opérations de reformatage de signaux vidéo pour la redistribution domestique, le stockage ou l'affichage en temps réel
41.
METHODS AND SYSTEMS FOR WI-FI SETUP AND CONFIGURATION
The present invention relates generally to the configuration of wireless networks and the configuration of electronic devices to connect to wireless networks, especially when those electronic devices have limited user interfaces and/or no display screen. The present invention makes use of devices already connected to a wireless network, previously connected to a wireless network, or capable of acting as an interface to discover the connection settings required to connect to the wireless network. The present invention further uses a shared communication medium between that connected device and an unconnected device in order to share the connection settings needed to connect the unconnected device.
Systems and methods for providing a media profile that is based on receiving data from various content distributors and creating a media profile. The media profile is web-based and accessible via an API. Data can be provided to the media profile host server via the API, and an end-user's media preferences can be stored in the media profile. The media profile is accessed by content distributors such that a customized media experience may be offered to the end-user without the need for the content distributor to gather his own separate data. The media profile can also store billing information for the end-user and act as a single reputable platform to conduct financial transactions.
Techniques are provided to serialize and delay parallel input data signals and are particularly useful for low power applications. In one example, a device includes a plurality of data input ports adapted to receive N parallel single-ended input data signals, and a clock input port adapted to receive a clock signal substantially synchronized with the parallel single-ended input data signals. The device also includes a cell adapted to serialize the parallel single-ended input data signals to provide N/2 first serial differential output data signals in response to the clock signal, delay the parallel single-ended input data signals, and serialize the delayed parallel single-ended input data signals to provide N/2 delayed second serial differential output data signals in response to the clock signal. The delayed second serial differential output data signals are delayed relative to the first serial differential output data signals. The device also includes a plurality of output ports.
A data storage device having non-volatile solid state memory permits efficient access by permitting multiple pending commands from a host device. A controller in the data storage device stores information about each command from the host device, and determines which stored command, if any, is presently able to be performed based on the portion of the non-volatile memory and the type of access of the command. The data storage device provides reduced access delays, improves read/write throughput, and avoids the cost of additional memory in the data storage device, by allowing accesses to idle portions of memory to proceed, and by signaling the host device when the data storage device is able to accept data to be written to portions of the non-volatile memory already active due to a previous command.
A wireless communications system and channel-switching method are disclosed herein. A source device and multiple sink devices independently maintain respective counters which track data packet errors. Each device independently switches channels only after its counter reaches a channel-switching threshold. The new channel switched-to is either determined by an indexed ordering of the available channels or by reference to a global clock maintained by each of the devices. Accordingly, all devices quickly arrive at a common channel. The system switches channels only when necessary and resolves quickly to a mutually acceptable channel. Therefore, unnecessary channel switching is minimized and data throughput is optimized.
A wireless communications system and channel-switching method are disclosed herein. A source device and multiple sink devices independently maintain respective counters which track data packet errors. Each device independently switches channels only after its counter reaches a channel-switching threshold. The new channel switched-to is either determined by an indexed ordering of the available channels or by reference to a global clock maintained by each of the devices. Accordingly, all devices quickly arrive at a common channel. The system switches channels only when necessary and resolves quickly to a mutually acceptable channel. Therefore, unnecessary channel switching is minimized and data throughput is optimized.
09 - Appareils et instruments scientifiques et électriques
Produits et services
Signalling apparatus and instruments; electronic apparatus; apparatus for recording, transmission or reproduction of sound or images; magnetic data carriers, recording discs; data processing equipment; computers and peripherals and accessories therefor; computer appliances; computer software; network interface processors, namely, chips, and relevant embedded software for use in connecting home audio electronics systems and portable audio devices with public and private computer networks.
The invention relates to the field of wireless communications and more specifically to an high quality, low power wireless audio system. More specifically, the invention comprises an audio source for receiving audio signals (e.g. music) and audio status information (e.g. song title) from a first external device (e.g. an MP3 player) and transmitting the audio signals and the audio status information over a wireless connection; and at least one audio sink for receiving the audio signals and said audio status information from the audio source and communicating the audio signals and the audio status information to a second external device (e.g. headphones), wherein a specified one of the at least one audio sink receives audio control information (e.g. pause) from the second external device and transmits said audio control information to said audio source via said wireless connection. Among other features, the wireless audio system of the present invention incorporates dynamic channel selection as well as dynamic adjustment of the transmission interval to ensure enhanced audio quality using the lowest possible power.
H04B 1/38 - Émetteurs-récepteurs, c.-à-d. dispositifs dans lesquels l'émetteur et le récepteur forment un ensemble structural et dans lesquels au moins une partie est utilisée pour des fonctions d'émission et de réception
H04B 7/00 - Systèmes de transmission radio, c.-à-d. utilisant un champ de rayonnement
H04M 1/00 - Équipement de sous-station, p. ex. pour utilisation par l'abonné
H04H 20/47 - Dispositions caractérisées par des circuits ou composants spécialement adaptés à la radiodiffusion spécialement adaptés aux systèmes de radiodiffusion couverts par les groupes spécialement adaptés aux systèmes de radiodiffusion stéréophonique
