A method of scheduling a system-on-chip (SoC) by a scheduler, located between a plurality of masters and a slave, includes receiving a plurality of access requests from the plurality of masters, setting the plurality of access requests in a plurality of registers, and scheduling the plurality of access requests based on the plurality of access requests.

A system on chip (SoC) is present that includes a plurality of master interfaces, a plurality of slave interfaces, and an interface circuit which is connected between the plurality of master interfaces and the plurality of slave interfaces and includes a plurality of components. When a first master interface among the plurality of master interfaces and a first slave interface among the plurality of slave interfaces are paired, a first group of the components which forms a first signal path between the first master interface and the first slave interface among the plurality of components is enabled according to a control of the first master interface.

A system on chip (SoC) is present that includes a plurality of master interfaces, a plurality of slave interfaces, and an interface circuit which is connected between the plurality of master interfaces and the plurality of slave interfaces and includes a plurality of components. When a first master interface among the plurality of master interfaces and a first slave interface among the plurality of slave interfaces are paired, a first group of the components which forms a first signal path between the first master interface and the first slave interface among the plurality of components is enabled according to a control of the first master interface.

A system on chip (SoC) is present that includes a plurality of master interfaces, a plurality of slave interfaces, and an interface circuit which is connected between the plurality of master interfaces and the plurality of slave interfaces and includes a plurality of components. When a first master interface among the plurality of master interfaces and a first slave interface among the plurality of slave interfaces are paired, a first group of the components which forms a first signal path between the first master interface and the first slave interface among the plurality of components is enabled according to a control of the first master interface.

A system on chip (SoC) is present that includes a plurality of master interfaces, a plurality of slave interfaces, and an interface circuit which is connected between the plurality of master interfaces and the plurality of slave interfaces and includes a plurality of components. When a first master interface among the plurality of master interfaces and a first slave interface among the plurality of slave interfaces are paired, a first group of the components which forms a first signal path between the first master interface and the first slave interface among the plurality of components is enabled according to a control of the first master interface.

An inter-integrated circuit bus arbitration system includes a first master circuit, a second master circuit, an analog switch circuit, an initial state identification circuit, and a selection control circuit. When the first master circuit is initiated to transmit data, the initial state identification circuit generates a first initial pulse signal. When the second master circuit is initiated to transmit data, the initial state identification circuit generates a second initial pulse signal. If the first initial pulse signal leads the second initial pulse signal, the selection control circuit generates a first control signal to make the analog switch circuit establish electrical connections between the first master circuit and an external data line and an external clock line when receiving the first control signal.

An inter-integrated circuit bus arbitration system includes a first master circuit, a second master circuit, an analog switch circuit, an initial state identification circuit, and a selection control circuit. When the first master circuit is initiated to transmit data, the initial state identification circuit generates a first initial pulse signal. When the second master circuit is initiated to transmit data, the initial state identification circuit generates a second initial pulse signal. If the first initial pulse signal leads the second initial pulse signal, the selection control circuit generates a first control signal to make the analog switch circuit establish electrical connections between the first master circuit and an external data line and an external clock line when receiving the first control signal.

Systems and methods for bus clock line handover are disclosed. In one aspect, a clock line in a bus is driven continuously during bus handover without having contentious or contradictory drive signals being provided. After arbitration, an original bus master will drive the clock line to a predetermined value until detecting a state change on a data line. An incoming bus master will begin driving the clock line to the predetermined value and then drive a state change on the data line. This state change is the state change detected by the original bus master that causes the original bus master to stop driving the clock line.

A main board slot power control circuit will select a lowest priority interface card from a plurality of interface cards to reduce operation frequency, when the system power consumption is found to be too large. The main board slot power control circuit includes a power supply module, a control module, and a plurality of slots. The plurality of interface cards is plugged into the plurality of slots. The control module applies different priorities to the plurality of interface cards. The power supply module detects and determines when the system power consumption is greater than a predetermined value, and the power supply module outputs a control signal to the control module accordingly. The control module selects the lowest priority interface card to reduce operation frequency according to the control signal, and then the next lowest and so on until power consumption is found to be sufficiently reduced.

A main board slot power control circuit will select a lowest priority interface card from a plurality of interface cards to reduce operation frequency, when the system power consumption is found to be too large. The main board slot power control circuit includes a power supply module, a control module, and a plurality of slots. The plurality of interface cards is plugged into the plurality of slots. The control module applies different priorities to the plurality of interface cards. The power supply module detects and determines when the system power consumption is greater than a predetermined value, and the power supply module outputs a control signal to the control module accordingly. The control module selects the lowest priority interface card to reduce operation frequency according to the control signal, and then the next lowest and so on until power consumption is found to be sufficiently reduced.