A docking station includes a network interface controller (NIC), a dock-side controller and a dock-side connector interface. The NIC is configured to transmit one or more management component transport protocol (MCTP) packets via a system management bus (SMbus). The dock-side controller is electrically coupled to the SMbus, and configured to encode the one or more MCTP packets to one or more vendor specific protocol (VSP) packets. The dock-side connector interface is electrically coupled to the dock-side controller, and configured to transmit the one or more VSP packets to an electrical device to control a basic input output system (BIOS) of the electrical device on the condition that the electrical device is connected to the docking station via the dock-side connector interface.

An information input device includes: a communication interface configured to communicate with each of a first external apparatus that operates using a first operating system and a second external apparatus that operates using a second operating system; and a controller configured to operate in a first mode corresponding to a first driver used by the first external apparatus when transferring data to the first external apparatus, and operate in a second mode corresponding to a second driver different from the first driver and used by the second external apparatus when transferring data to the second external apparatus.

Systems and methods for fast activation of slaves during wake up in an audio system allow a master device in an audio system such as a SOUNDWIRE audio system to send system and/or topology information to capable slave devices during a wake up window so that the slaves may start in an active mode rather than a safe mode. In the most recent proposed versions of SOUNDWIRE, there is a check PHY_Num phase. The systems for fast activation of slaves cause a negative differential line to be driven with an encoded signal by the master during a check PHY_Num phase where the encoded signal indicates a fast mode speed. Capable slaves may then begin in a fast mode rather than a safe (and slow) mode. Latency may be reduced by starting in a fast mode, which may improve the user's audio experience.

A data transmission system and an operation method thereof are provided. The data transmission system includes a host, a first device and a second device. The host is configured to set a voltage base of a transmission signal, and configured to pull down or up the transmission signal based on the voltage base of the transmission signal to form a plurality of glitches. The first device is connected to the host to receive the transmission signal. The first device obtains a digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a first base. The second device is connected to the host to receive the transmission signal. The second device obtains the digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a second base.

A receive module. The receive module has a first voltage divider for adjusting a first receive threshold; a first comparator, connected to the first voltage divider, for evaluating differential signals received from a bus of the bus system using the first receive threshold; a second voltage divider for adjusting a second receive threshold or a third receive threshold; a second comparator, connected to the second voltage divider, for evaluating the differential signals using the second or third receive threshold adjusted by the second voltage divider; and a switching unit for the switchover between the second and third receive threshold as a function of an operating mode of the receive module, to which the receive module is to be switched for a first or second communications phase of a communication on the bus, the first and second voltage dividers being connected to the bus in each case.

An event recorder for a power supply and a method thereof are provided. The event recorder method includes: selecting an event combination; based on the selected event combination, performing a setting step to set a trigger source combination and a record data combination, wherein the setting step further comprises any combination of the following: setting a record data type combination, setting a trigger type combination, setting a resolution combination, and setting a logic combination; and in response to a logic combination result of the trigger source combination, storing the record data combination in a storage unit.

The present disclosure provides a system and method for reception of BMC data in USB PD communication. The system comprises an analog block and a digital block with the digital block further comprising an idle detection mechanism, and a digital controller for rejecting noise and auto correcting of received BMC signal. The BMC data is typically processed by means of varied functions such as comparison by a threshold comparator on the analog block with programmable reference, and other components of the digital block so as to realize aspects such as noise filtering of BMC data by changing the reference dynamically based on comparison of the width of threshold comparator output signal with average signal widths which is computed during the preamble phase of USB PD communications.

A CAN circuit structure and a vehicle diagnostic device are provided. The CAN circuit structure includes: a pair of data buses on which differential signals are transmitted; a CAN transceiver operating in a first voltage domain; a clamp circuit disposed between the CAN transceiver and the data buses for clamping a high level or a low level of the differential signals; a CAN controller operating in a second voltage domain; and a signal isolation circuit disposed between the CAN transceiver and the CAN controller for isolating the first voltage domain from the second voltage domain. The circuit allows for the use of a standard CAN transceiver chip that meets a general standard in a special CAN circuit structure, thus effectively reducing manufacturing costs of related devices.

A storage device includes NVM package and a controller connected to the NVM package through a channel and controlling operation of the NVM package. The NVM package includes an interface chip, first NVM devices connected to the interface chip through a first internal channel and second NVM devices connected to the interface chip through a second internal channel. The interface chip selects the first internal channel in response to an operation request received from the controller and connects the first internal channel to the channel. The interface chip also determines whether retraining is necessary in relation to the second internal channel and transmits a retraining request to the controller when retraining is necessary.

A low voltage drive circuit includes a transmit digital to analog circuit that converts transmit digital data into analog outbound data by: generating a DC component; generating a first oscillation at a first frequency; generating a second oscillation at the first frequency; and outputting the first oscillation or the second oscillation on a bit-by-bit basis in accordance with the transmit digital data to produce an oscillating component, wherein the DC component is combined with the oscillating component to produce the analog outbound data, and wherein the oscillating component and the DC component are combined to produce the analog outbound data. A drive sense circuit drives an analog transmit signal onto a bus, wherein the analog outbound data is represented within the analog transmit signal as variances in loading of the bus at the first frequency and wherein analog inbound data is represented within an analog receive signal as variances in loading of the bus at a second frequency.