A dynamically addressable master-slave system and a method for dynamically addressing slave units includes a master unit and a plurality of slave units, such that the slave units are interconnected with the master unit via a bus system. The respective network addresses of the slave units are assigned to the respective serial numbers of these slave units in a table in the master unit according to the position thereof in the system according to a determined order. Upon replacement of slave units, a list of serial numbers of the units to be replaced is transferred to the master unit in the sequence of the acquisition of the serial numbers, which master unit replaces these serial numbers in the table with the serial numbers of the replaced slave units transmitted to the master unit.

A dynamically addressable master-slave system and a method for dynamically addressing slave units includes a master unit and a plurality of slave units, such that the slave units are interconnected with the master unit via a bus system. The respective network addresses of the slave units are assigned to the respective serial numbers of these slave units in a table in the master unit according to the position thereof in the system according to a determined order. Upon replacement of slave units, a list of serial numbers of the units to be replaced is transferred to the master unit in the sequence of the acquisition of the serial numbers, which master unit replaces these serial numbers in the table with the serial numbers of the replaced slave units transmitted to the master unit.

Aspects of the invention include computer-implemented methods, systems, and computer program products that assign a centralized event tag to each communication interface of a plurality of communication interfaces of a chip interconnected in a hierarchy through the communication interfaces to a plurality of chips in a multiprocessing system. A determination is performed of whether to accept or drop a message associated with an event received at one of the communication interfaces of the chip based on comparing a local centralized event tag with a received centralized event tag. The local centralized event tag is updated based on one or more advancing rules to maintain event synchronization between the chip and the plurality of chips.

Aspects of the invention include computer-implemented methods, systems, and computer program products that assign a centralized event tag to each communication interface of a plurality of communication interfaces of a chip interconnected in a hierarchy through the communication interfaces to a plurality of chips in a multiprocessing system. A determination is performed of whether to accept or drop a message associated with an event received at one of the communication interfaces of the chip based on comparing a local centralized event tag with a received centralized event tag. The local centralized event tag is updated based on one or more advancing rules to maintain event synchronization between the chip and the plurality of chips.

A data communication device includes: a fixed value memory that stores a fixed value; a received data memory that stores received data inputted through a bus; an output data memory that stores output data; a comparison determination unit that outputs a comparison determination result signal indicating a determination result of comparing the fixed value and a value of the received data; a data output unit that has a first state of outputting the output data to the bus and a second state of not outputting the output data to the bus; a command analyzing unit that outputs a data output control signal based on a command; and an output controller that outputs a control signal for controlling the data output unit to enter the first state or the second state based on the comparison determination result signal and the data output control signal.

A data communication device includes: a fixed value memory that stores a fixed value; a received data memory that stores received data inputted through a bus; an output data memory that stores output data; a comparison determination unit that outputs a comparison determination result signal indicating a determination result of comparing the fixed value and a value of the received data; a data output unit that has a first state of outputting the output data to the bus and a second state of not outputting the output data to the bus; a command analyzing unit that outputs a data output control signal based on a command; and an output controller that outputs a control signal for controlling the data output unit to enter the first state or the second state based on the comparison determination result signal and the data output control signal.

The present invention provides a data transmission system and resource allocation method thereof. The data transmission system is configured to: retrieve master device resource information and slave device performance information; based on a neural network model, determine at least one arbiter setting parameter according to the master device resource information and the slave device performance information; and determine resource allocation setting of at least one master device according to the at least one arbiter setting parameter.

The present invention provides a data transmission system and resource allocation method thereof. The data transmission system is configured to: retrieve master device resource information and slave device performance information; based on a neural network model, determine at least one arbiter setting parameter according to the master device resource information and the slave device performance information; and determine resource allocation setting of at least one master device according to the at least one arbiter setting parameter.

Disclosed are a data transmission apparatus and method, used for transmitting data between a transmitter and a receiver connected by N data lines, N being an integer greater than 1. The method comprises: sending a plurality of data units one by one; on each transmission signal, inverting the level of one and only one data line corresponding to the currently sent data unit; extracting the transmission signal, and decoding the data unit corresponding to the data line according to the data line of which level is inverted among the N data lines; and sampling the data unit and then outputting.

Provisioning an orchestration platform is provided. A pre-application programming interface (API) server hook is used to preprocess a request to generate a custom resource in the orchestration platform. The pre-API server hook generates a custom resource definition corresponding to the custom resource and generates the custom resource based on the custom resource definition. A custom resource definition generation event is monitored for, using a custom resource definition (CRD) meta-controller, to manage a custom resource definition controller corresponding to the custom resource definition. The CRD meta-controller retrieves the custom resource definition controller from a CRD controller configuration repository to deploy the custom resource definition controller on a worker node in the orchestration platform. Data is distributed, using a data partition proxy, to the custom resource definition controller running the custom resource on the worker node to ensure that no overlapping of data processing tasks exists in the orchestration platform.