Configuration devices in a module. In some embodiments a radio-frequency module includes a serial bus including a first serial data line and a second serial data line. The radio-frequency module also includes a control component coupled to the serial bus and the first switch, the control component configured to determine whether first data is detected on the first serial data line, determine whether second data is detected on the second serial data line, and decode a command based on the first data and second data when the first data is detected on the first serial data line and when the second data is detected on the second serial data line.

Configuration devices in a module. In some embodiments a radio-frequency module includes a serial bus including a first serial data line and a second serial data line. The radio-frequency module also includes a control component coupled to the serial bus and the first switch, the control component configured to determine whether first data is detected on the first serial data line, determine whether second data is detected on the second serial data line, and decode a command based on the first data and second data when the first data is detected on the first serial data line and when the second data is detected on the second serial data line.

A chip-to-chip interface of a multi-chip module (MCM), including: bidirectional data links for transmitting data signals and a direction indicator bit, wherein the direction indicator bit switches a direction of the bidirectional data links in real-time; a clock link for transmitting a clock signal common to the bidirectional data links, wherein the data and clock links are comprised of conductive traces between the chips and laid out to be of substantially equal length; and a clock driver means having a digitally programmable clock signal delay.

A chip-to-chip interface of a multi-chip module (MCM), including: bidirectional data links for transmitting data signals and a direction indicator bit, wherein the direction indicator bit switches a direction of the bidirectional data links in real-time; a clock link for transmitting a clock signal common to the bidirectional data links, wherein the data and clock links are comprised of conductive traces between the chips and laid out to be of substantially equal length; and a clock driver means having a digitally programmable clock signal delay.

One embodiment is directed to a multi-rack rack controller for an automated infrastructure management (AIM) system comprising a plurality of independent patching equipment bus interfaces. Another embodiment is directed to a rack controller comprising at least one rack controller interface configured to connect the rack controller to another rack controller. Each rack controller interface comprises a respective termination circuit. The rack controller is configured to determine whether each rack controller interface is connected to another rack controller as a function of a respective sense signal developed by the termination circuit associated with said rack controller interface. Another embodiment is directed to a rack controller comprising a base unit having a locate button disposed on the front of the base unit. Other embodiments are disclosed.

Provided are embodiments for operating a high-speed deserializer. Embodiments can include receiving a clock slip signal to enable operation of the slip pulse generation circuit, and generating a slip pulse signal using the slip pulse-controlled clock generation circuit, wherein the slip pulse signal is programmable to slip one or more bits of a serial input data. Embodiments can also include generating a plurality of deserialization clocks for sampling the serial input data using the slip pulse-controlled clock generation circuit, wherein the plurality of deserialization clocks are generated simultaneously with each other, and providing the plurality of deserialization clocks to the deserializer to selectively sample the serial input data.

Provided are embodiments for operating a high-speed deserializer. Embodiments can include receiving a clock slip signal to enable operation of the slip pulse generation circuit, and generating a slip pulse signal using the slip pulse-controlled clock generation circuit, wherein the slip pulse signal is programmable to slip one or more bits of a serial input data. Embodiments can also include generating a plurality of deserialization clocks for sampling the serial input data using the slip pulse-controlled clock generation circuit, wherein the plurality of deserialization clocks are generated simultaneously with each other, and providing the plurality of deserialization clocks to the deserializer to selectively sample the serial input data.

The present invention provides a frequency-halving latch circuit for deterministic field bus network data forwarding and application thereof. The frequency-halving latch circuit includes a data buffer equipped with two buffer units; a frequency-halving enable latch signal generation module for generating a first frequency-halving latch signal and a second frequency-halving latch signal with opposite levels, and selecting data buffer units of the data buffer based on the first frequency-halving latch signal, the second frequency-halving latch signal and a receiving enable signal; and a shift register including a first trigger and a second trigger which are initialized to opposite output states, the first trigger and the second trigger is connected to realize a shift operation, and data stored in the data buffer units is finally selected and read based on a low order in the shift register composed of the two triggers and a read enable signal. The frequency-halving latch circuit can be applied to a scenario of deterministic field bus network data forwarding as a same-frequency out-of-phase data cross-clock domain circuit, with high resource utilization rate and stability.

The present invention provides a frequency-halving latch circuit for deterministic field bus network data forwarding and application thereof. The frequency-halving latch circuit includes a data buffer equipped with two buffer units; a frequency-halving enable latch signal generation module for generating a first frequency-halving latch signal and a second frequency-halving latch signal with opposite levels, and selecting data buffer units of the data buffer based on the first frequency-halving latch signal, the second frequency-halving latch signal and a receiving enable signal; and a shift register including a first trigger and a second trigger which are initialized to opposite output states, the first trigger and the second trigger is connected to realize a shift operation, and data stored in the data buffer units is finally selected and read based on a low order in the shift register composed of the two triggers and a read enable signal. The frequency-halving latch circuit can be applied to a scenario of deterministic field bus network data forwarding as a same-frequency out-of-phase data cross-clock domain circuit, with high resource utilization rate and stability.

The invention relates to a method for communicating data between communication equipments, where the first communication equipment (EqptN) is put into the emission mode (Xmit) for the frame (TrN) containing its identification (D_PID), while each second communication equipment (Eqpt1, EqptN+1, EqptN+x) is put into the receiving mode (Rcv), then the equipment (EqptN) is put into the receiving mode (Rcv), each equipment (Eqpt1, EqptN+1, EqptN+x) prescribes its local emission window (Ftle1, FtleN+1, FtleN+x), which is associated with its identification, during which it is put into the emission mode (Xmit) for its frame, a time of beginning (IDF1, IDFN+1, IDFN+X) of the window being a determined function, increasing with respect to a difference equal to its identification from which the identification (D_PID) is subtracted, each equipment is put into the emission mode, during which it emits its frame containing its identification during its window starting at the beginning time.