US20190018590A1 - Control circuit programming levels of pins and operating system utilizing the same - Google Patents
Control circuit programming levels of pins and operating system utilizing the same Download PDFInfo
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- US20190018590A1 US20190018590A1 US15/870,892 US201815870892A US2019018590A1 US 20190018590 A1 US20190018590 A1 US 20190018590A1 US 201815870892 A US201815870892 A US 201815870892A US 2019018590 A1 US2019018590 A1 US 2019018590A1
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/04—Programme control other than numerical control, i.e. in sequence controllers or logic controllers
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/06—Digital input from, or digital output to, record carriers, e.g. RAID, emulated record carriers or networked record carriers
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F13/00—Interconnection of, or transfer of information or other signals between, memories, input/output devices or central processing units
- G06F13/38—Information transfer, e.g. on bus
- G06F13/382—Information transfer, e.g. on bus using universal interface adapter
- G06F13/385—Information transfer, e.g. on bus using universal interface adapter for adaptation of a particular data processing system to different peripheral devices
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- G06F2003/0691—
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/06—Digital input from, or digital output to, record carriers, e.g. RAID, emulated record carriers or networked record carriers
- G06F3/0601—Interfaces specially adapted for storage systems
- G06F3/0628—Interfaces specially adapted for storage systems making use of a particular technique
- G06F3/0655—Vertical data movement, i.e. input-output transfer; data movement between one or more hosts and one or more storage devices
- G06F3/0656—Data buffering arrangements
Definitions
- the invention relates to a control circuit, and more particularly to a control circuit which is capable of programming the levels of pins.
- an operating system comprises an integrated circuit and a control circuit.
- the control circuit is coupled to the integrated circuit via a first pin and comprises a first slot, a timer controller, an input/output buffer, a buffer controller and a pin controller.
- the first slot is configured to adjust a first count value according to a clock signal.
- the timer controller is configured to generate a first trigger signal when the first count value is equal to a first predetermined value.
- the buffer controller is configured to access the input/output buffer.
- the pin controller is coupled to the first pin, the timer controller and the buffer controller. In an input mode, the pin controller detects a voltage level of the first pin according to the first trigger signal to generate a plurality of detection results. In the input mode, the pin controller stores the plurality of detection results to the input/output buffer via the buffer controller. In an output mode, the pin controller generates an output signal to the integrated circuit according to the first trigger signal and output data stored in the input/output buffer.
- FIG. 1 is a schematic diagram of an exemplary embodiment of an operating system according to various aspects of the present disclosure.
- FIG. 2 is a schematic diagram of another exemplary embodiment of the operating system according to various aspects of the present disclosure.
- FIG. 3 is a schematic diagram of another exemplary embodiment of an operating system according to various aspects of the present disclosure.
- FIG. 4A is a schematic diagram of the voltage level of a pin in an input mode according to various aspects of the present disclosure.
- FIG. 4B is a schematic diagram of the voltage level of the pin in an output mode according to various aspects of the present disclosure.
- FIG. 4C is a schematic diagram of a pulse width modulation (PWM) signal generated by a pin controller of the present disclosure.
- PWM pulse width modulation
- FIG. 1 is a schematic diagram of an exemplary embodiment of an operating system, according to various aspects of the present disclosure.
- the operating system 100 comprises a control circuit 110 and an integrated circuit 120 .
- the control circuit 110 communicates with the integrated circuit 120 via the pins PN 1 ⁇ PN 4 , but the disclosure is not limited thereto. In other embodiments, the control circuit 110 may utilize more or fewer than four pins to provide information to the integrated circuit 120 or to receive information from the integrated circuit 120 .
- the control circuit 110 when the control circuit 110 executes a programmed code (not shown) stored in itself, the control circuit 110 programs the voltage level of at least one of the pins PN 1 ⁇ PN 4 such that the communication between the control circuit 110 and the integrated circuit 120 conforms with a communication protocol.
- control circuit 110 simulates a serial communication protocol, but the disclosure is not limited thereto. In another embodiment, the control circuit 110 simulates a parallel communication protocol. In some embodiments, when the control circuit 110 executes the programmed code (not shown) stored in itself, the control circuit 110 receives the information provided from the integrated circuit 120 according to the voltage level of at least one of the pins PN 1 ⁇ PN 4 . In other embodiments, the control circuit 110 serves as a clock generator. In this case, when the control circuit 110 executes a programmed code (not shown) stored in itself, the control circuit 110 outputs a pulse width modulation (PWM) signal to the integrated circuit 120 .
- PWM pulse width modulation
- each of the pins PN 1 ⁇ PN 4 performs different roles to transmit different signals in different times.
- the control circuit 110 may serve the pin PN 1 as a clock pin to transmit a clock signal to the integrated circuit 120 or receive a clock signal from the integrated circuit 120 after the control circuit 110 executes an internal programmed code.
- the control circuit 110 may transmit data to the integrated circuit 120 or receive data from the integrated circuit 120 via the pin PN 1 .
- the pin PN 1 may serve as an input/output pin. Since each of the pins PN 1 ⁇ PN 4 is capable of transmitting signals, which have different types, the utility rate of the pins PN 1 ⁇ PN 4 is increased and the number of pins between the control circuit 110 and the integrated circuit 120 is not too high.
- control circuit 110 is configured to program the voltage levels of the pins PN 1 ⁇ PN 4 and at least comprises an input/output buffer 111 , timers 112 and 113 , a buffer controller 114 , a timer controller 115 and a pin controller 116 .
- FIG. 1 shows the elements related to the invention that are discussed, but the invention is not limited thereto.
- the control circuit 110 still may comprise other hardware devices, firmware or software, which are not discussed for brevity.
- the input/output buffer 111 is configured to store data.
- the control circuit 110 stores the data received from the integrated circuit 120 to the input/output buffer 111 .
- the control circuit 110 reads the data stored in the input/output buffer 111 and provides the stored data to the integrated circuit 120 .
- the circuit structure of the input/output buffer 111 is not limited. Any circuit can serve as an input/output buffer 111 , as long as the circuit is capable of storing data.
- the input/output buffer 111 comprises an output buffer BFO, an input buffer FGI and a status buffer BFS.
- the output buffer BFO is configured to store the output data to be provided to the integrated circuit 120 .
- a central processing unit (CPU) writes the output data into the output buffer BFO.
- the input buffer BFI is configured to store the input data received by the control circuit 110 .
- the status buffer BFS is configured to store the status data received by the control circuit 110 .
- the control circuit 110 receives input information which has a plurality of bits.
- the bits of the input information comprise at least one start bit, at least one data bit and at least one stop bit.
- the control circuit 110 stores the value of the start bit and the value of the stop bit into the status buffer BFS and stores the value of the data bit into the input buffer BFI.
- the buffer controller 114 is coupled between the pin controller 116 and the input/output buffer 111 to access the input/output buffer 111 .
- the buffer controller 114 reads the output data stored in the output buffer BFO and provides the stored output data to the pin controller 116 .
- the pin controller 116 outputs the stored output data to the integrated circuit 120 via at least one of the pins PN 1 ⁇ PN 4 .
- the pin controller 116 provides the input information received by at least one of the pins PN 1 ⁇ PN 4 to the buffer controller 114 .
- the input information comprises initial data, stop data and input data.
- the buffer controller 114 stores the initial data and the stop data into the status buffer BFS and stores the input data into the input buffer BFI.
- the internal circuit of the buffer controller 114 is not limited in the present disclosure. Any circuit can serve as a buffer controller 114 , as long as the circuit is capable of accessing buffers.
- the timer controller 115 is coupled to the timers 112 and 113 , but the disclosure is not limited thereto. In other embodiments, the timer controller 115 is coupled to more timers or fewer timers.
- the timer 112 comprises slots ST 1 and ST 2 , but the disclosure is not limited thereto. In other embodiments, the timer 112 comprises more or fewer than two slots. In this embodiment, the timer 113 comprises slots ST 3 and ST 4 , but the disclosure is not limited thereto. In other embodiments, the timer 113 comprises more or fewer than two slots. In this embodiment, the number of slots of the timer 112 is the same as the number of slots of the timer 113 , but the disclosure is not limited thereto.
- the number of slots of the timer 112 may be more than or less than the number of slots of the timer 113 . Since the feature of the timer 112 is the same as the feature of the timer 113 , the timer 112 is given as an example.
- the slot ST 1 has a count value VL 1
- the slot ST 2 has a count value VL 2 .
- the slot ST 1 increases or reduces the count value VL 1 according to a first clock signal.
- the slot ST 2 increases or reduces the count value VL 2 according to a second clock signal.
- the frequency of the first clock signal may be the same as or different from the frequency of the second clock signal.
- first and second clock signals may be provided from a single clock source or provided from different clock sources. In one embodiment, the first and second clock signals are the same clock signal.
- the slot ST 1 may be directly coupled to a first clock source to receive the first clock signal. In other embodiments, the slot ST 1 may be indirectly coupled to the first clock source. For example, at least one prescaler is disposed between the slot ST 1 and the first clock source.
- the slot ST 2 may be directly coupled to a second clock source to receive the second clock signal. In other embodiments, the slot ST 2 may be indirectly coupled to the second clock source. For example, at least one prescaler is disposed between the slot ST 2 and the second clock source. In some embodiments, one of the slots ST 1 and ST 2 is directly coupled to the corresponding clock source and the other is indirectly coupled to the corresponding clock source.
- the timer controller 115 is coupled to the timers 112 and 113 and outputs a plurality of trigger signals to the pin controller 116 according to the count values VL 1 ⁇ VL 4 of the slots ST 1 ⁇ ST 4 . For example, when the count value VL 1 is equal to a first predetermined value, the timer controller 115 generates a first trigger signal to the pin controller 116 . Similarly, when the count value VL 2 is equal to a second predetermined value, the timer controller 115 generates a second trigger signal to the pin controller 116 . When the count value VL 3 is equal to a third predetermined value, the timer controller 115 generates a third trigger signal to the pin controller 116 .
- the timer controller 115 When the count value VL 4 is equal to a fourth predetermined value, the timer controller 115 generates a fourth trigger signal to the pin controller 116 .
- the first, second, third and fourth predetermined values are different. In one embodiment, the first predetermined value is less than the second predetermined value, the second predetermined value is less than the third predetermined value, the third predetermined value is less than the fourth predetermined value. In other embodiments, one of the first, second, third and fourth predetermined values is equal to another of the first, second, third and fourth predetermined values.
- the first, second, third and fourth predetermined values may be set by the timer controller 115 . In other embodiments, the first, second, third and fourth predetermined values are set by another controller (not shown) disposed in the control circuit 110 .
- the slots ST 1 ⁇ ST 4 are controlled by the timer controller 115 . For example, the timer controller 115 activates the slots ST 1 ⁇ ST 4 . When the slots ST 1 ⁇ ST 4 are activated, the slots ST 1 ⁇ ST 4 increase or reduce the count values VL 1 ⁇ VL 4 respectively. In another embodiment, the timer controller 115 resets the count values VL 1 ⁇ VL 4 such that the count values VL 1 ⁇ VL 4 are equal to an initial value. In other embodiments, the slots ST 1 ⁇ ST 4 are controlled by another controller (not shown) disposed in the control circuit 110 . In this case, the another controller of the control circuit 110 activates or resets the slots ST 1 ⁇ ST 4 .
- the timer controller 115 when the count value VL 1 is equal to the first predetermined value, the timer controller 115 resets the slot ST 1 such that the count value VL 1 is equal to an initial value.
- the timer controller 115 resets the slot ST 2 such that the count value VL 2 is equal to an initial value.
- the timer controller 115 resets the slot ST 3 such that the count value VL 3 is equal to an initial value.
- the timer controller 115 resets the slot ST 4 such that the count value VL 4 is equal to an initial value.
- the timer controller 115 activates the corresponding slot among the slots ST 1 ⁇ ST 4 such that the corresponding slot performs a counting operation, for example, the corresponding slot may adjust the corresponding count value again.
- the invention does not limit the number that each of slot ST 1 ⁇ ST 4 performs the counting operation. In one embodiment, the number of times the counting operation is performed by each of slots ST 1 ⁇ ST 4 is controlled by the timer controller 115 .
- the pin controller 116 is coupled to the timer controller 115 and the buffer controller 114 and is coupled to the integrated circuit 120 via the pins PN 1 ⁇ PN 4 .
- the pin controller 116 controls or detects the voltage level of at least one of the pins PN 1 ⁇ PN 4 according to the time points when the timer controller 115 generates the trigger signals. Therefore, the time points when the timer controller 115 generates the trigger signals are referred to as checkpoints.
- the pin controller 116 controls or detects the voltage level of at least one of the pins PN 1 ⁇ PN 4 at the checkpoints.
- the timer controller 115 Assume that when the count value VL 1 of the slot ST 1 is equal to a first predetermined value, the timer controller 115 generates a first trigger signal. In this case, the time point when the timer controller 115 generates the first trigger signal is referred to as a first checkpoint. Assume that when the count value VL 2 of the slot ST 2 is equal to a second predetermined value, the timer controller 115 generates a second trigger signal. In this case, the time point when the timer controller 115 generates the second trigger signal is referred to as a second checkpoint. Assume that when the count value VL 3 of the slot ST 3 is equal to a third predetermined value, the timer controller 115 generates a third trigger signal.
- the time point when the timer controller 115 generates the third trigger signal is referred to as a third checkpoint.
- the timer controller 115 generates a fourth trigger signal.
- the time point when the timer controller 115 generates the fourth trigger signal is referred to as a fourth checkpoint.
- the pin controller 116 detects the voltage level of the pin PN 1 at the first, second, third and fourth checkpoints to generate many detection results. In one embodiment, the pin controller 116 immediately detects the voltage level of the pin PN 1 at the first, second, third and fourth checkpoints. In other words, each when the pin controller 116 receives the trigger signals generated by the timer controller 115 , the pin controller 116 immediately detects the voltage level of the pin PN 1 . In another embodiment, the pin controller 116 detects the voltage level of the pin PN 1 between two checkpoints (e.g. the first and second checkpoints).
- the pin controller 116 waits a predetermined time and then detects the voltage level of the pin PN 1 , wherein the predetermined time is shorter than the time between the first and second checkpoints.
- the pin controller 116 stores the detection results to the input/output buffer 111 via the buffer controller 114 .
- the pin controller 116 reads the output data stored in the input/output buffer 111 via the buffer controller 114 at the first, second, third and fourth checkpoints and generates an output signal to the integrated circuit 120 according to the stored output data.
- the pin controller 116 may immediately read the output data stored in the input/output buffer 111 at the first checkpoint or may wait a predetermined time after the first checkpoint and then read the output data stored in the input/output buffer 111 .
- the pin controller 116 outputs the output signal via at least one of the pins PN 1 ⁇ PN 4 .
- the pin controller 116 detects the voltage level of the pin PN 1 in the input mode.
- the pin controller 116 may utilize the pin PN 1 to output the output signal in the output mode.
- the pin controller 116 utilizes the pin PN 2 to output the output signal.
- the pin controller 116 when the control circuit 110 operates in the output mode, maintains or changes the voltage level of at least one of the pins PN 1 ⁇ PN 4 at the first, second, third and fourth checkpoints to generate a PWM signal to the integrated circuit 120 .
- the pin controller 116 sets the voltage level of the pin PN 1 at a high level at the first checkpoint.
- the pin controller 116 sets the voltage level of the pin PN 1 at a low level at the second checkpoint.
- the pin controller 116 sets the voltage level of the pin PN 1 at the high level at the third checkpoint.
- the pin controller 116 sets the voltage level of the pin PN 1 at the low level at the fourth checkpoint.
- the timer controller 115 generates many trigger signals according to the count values of different slots, but the disclosure is not limited thereto. In other embodiments, the timer controller 115 generates many trigger signals according to the count values of a slot. For example, when the count value VL 1 of the slot ST 1 is equal to a predetermined value, the timer controller 115 generates a trigger signal to the pin controller 116 . Next, the timer controller 115 first resets the slot ST 1 and then activates the slot ST 1 such that the slot ST 1 increases or reduces the count value VL 1 again. When the count value VL 1 of the slot ST 1 is equal to the predetermined value again, the timer controller 115 generates the trigger signal to the pin controller 116 again. Therefore, the timer controller 115 is capable of generating a plurality of trigger signals according to the count values of a single slot.
- FIG. 4A is a schematic diagram of the voltage level of the pin PN 1 in an input mode according to various aspects of the present disclosure.
- the pin controller 116 reads the voltage level of the pin PN 1 and stores the voltage level of the pin PN 1 .
- the symbol CLK represents a clock signal, wherein the slots ST 1 ⁇ ST 4 adjusts the count values VL 1 ⁇ VL 4 according to the clock signal CLK.
- the symbol T SR represents a start time point of input data.
- the start time point of the input data is an end time point of initial data.
- the voltage level (e.g. a low level) before the start time point T SR is stored in the status buffer BFS.
- the symbol T CP1 is a first checkpoint.
- the first checkpoint is a time point when the timer controller 115 sends a first trigger signal. In one embodiment, when the count value VL 1 is equal to a first predetermined value, the timer controller 115 sends the first trigger signal.
- the pin controller 116 determines that the voltage level of the pin PN 1 is a high level such that the pin controller 116 writes the value “1” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [1].
- the symbol T CP2 is a second checkpoint.
- the second checkpoint is a time point when the timer controller 115 sends a second trigger signal. In one embodiment, when the count value VL 2 is equal to a second predetermined value, the timer controller 115 sends the second trigger signal.
- the pin controller 116 determines that the voltage level of the pin PN 1 is a low level such that the pin controller 116 writes the value “0” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [10].
- the symbol T CP3 is a third checkpoint.
- the third checkpoint is a time point at which the timer controller 115 sends a third trigger signal.
- the timer controller 115 sends the third trigger signal.
- the pin controller 116 determines that the voltage level of the pin PN 3 is the high level such that the pin controller 116 writes the value “1” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [101].
- the symbol T CP4 is a fourth checkpoint.
- the fourth checkpoint is a time point at which the timer controller 115 sends a fourth trigger signal. In one embodiment, when the count value VL 4 is equal to a fourth predetermined value, the timer controller 115 sends the fourth trigger signal.
- the pin controller 116 determines that the voltage level of the pin PN 1 is a low level such that the pin controller 116 writes the value “0” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is
- the fourth checkpoint T CP4 is also an end time point T SP . Therefore, the pin controller 116 detects and stores the voltage level (e.g. a high level) to the status buffer BFS, wherein the stored voltage level occurs after the end time point T SP .
- the voltage level e.g. a high level
- FIG. 4B is a schematic diagram of the voltage level of the pin PN 1 in an output mode according to various aspects of the present disclosure.
- the pin controller 116 reads the output data stored in the input/output buffer 111 and controls the voltage level of the pin PN 1 according to the stored output data.
- the symbol CLK represents a clock signal, wherein the slots ST 1 ⁇ ST 4 adjust the count values VL 1 ⁇ VL 4 according to the clock signal CLK.
- the symbol T SR represents a start time point. Before the start time point T SR , the voltage level of the pin PN 1 is a predetermined voltage level, such as a low level.
- the pin controller 116 reads output data stored in the output buffer BFO. Assume that the value of the output data is [ 1110 ].
- the output buffer BFO outputs the most significant bit (MSB) of the output data to the pin controller 116 . Since the value of the MSB of the output data is “1”, the pin controller 116 sets and maintains the voltage level of the pin PN 1 at a high level between the start time point T SR and the first checkpoint T CP1 . At this time, the value stored in the output buffer BFO is [110].
- the pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [ 110 ].
- the output buffer BFO outputs the MSB of the output data to the pin controller 116 . Since the value of the MSB of the output data is “1”, the pin controller 116 sets and maintains the voltage level of the pin PN 1 to the high level between the first checkpoint T CP1 and the second checkpoint T CP2 . At this time, the value stored in the output buffer BFO is [10].
- the pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [ 10 ].
- the output buffer BFO outputs the MSB of the output data to the pin controller 116 . Since the value of the MSB of the output data is “1”, the pin controller 116 sets and maintains the voltage level of the pin PN 1 to the high level between the second checkpoint T CP2 and the third checkpoint T CP3 . At this time, the value stored in the output buffer BFO is [0].
- the pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [0].
- the output buffer BFO outputs the MSB of the output data to the pin controller 116 . Since the value of the MSB of the output data is “0”, the pin controller 116 sets and maintains the voltage level of the pin PN 1 to a low level between the third checkpoint T CP3 and the fourth checkpoint T CP4 . At this time, the value stored in the output buffer BFO has been output to the pin controller 116 . Therefore, the slots ST 1 ⁇ ST 4 stops adjusting the count values VL 1 ⁇ VL 4 . After the end time point T SP , the voltage level of the pin PN 1 is maintained to a final level, such as a high level.
- FIG. 4C is a schematic diagram of an exemplary embodiment of a PWM signal generated by the pin controller 116 .
- the pin controller 116 changes the voltage level of the pin PN 1 at each checkpoint to generate a PWM signal. Assume that before the checkpoint P 0 , the voltage level of the pin PN 1 is an initial level, such as a low level.
- the pin controller 116 controls the voltage level of the pin PN 1 at the low level.
- the pin controller 116 changes the voltage level of the pin PN 1 from the low level to a high level.
- the voltage level of the pin PN 1 is a final level, such as the low level.
- the checkpoint P 0 represents a time point at which the timer controller 115 sends a trigger signal when the count value VL 1 of the slot ST 1 is equal to a first predetermined value.
- the checkpoint P 1 represents another time point at which the timer controller 115 sends another trigger signal when the count value VL 2 of the slot ST 2 is equal to a second predetermined value.
- the timer controller 115 controls the number of times the slots ST 1 and ST 2 perform a counting operation and generates a PWM signal having many pulses according to the number of executions of the counting operation.
- FIG. 2 is a schematic diagram of another exemplary embodiment of the operating system, according to various aspects of the present disclosure.
- FIG. 2 is similar to FIG. 1 exception that the control circuit 210 of the operating system 200 shown in FIG. 2 further comprises an interrupt controller 217 and a controller 218 . Since the features of the input/output buffer 211 , the times 212 and 213 , the buffer controller 214 , the timer controller 215 and the pin controller 216 are the same as the features of the input/output buffer 111 , the times 112 and 113 , the buffer controller 114 , the timer controller 115 and the pin controller 116 shown in FIG. 1 , the descriptions of the features of the input/output buffer 211 , the times 212 and 213 , the buffer controller 214 , the timer controller 215 and the pin controller 216 are omitted.
- the pin controller 216 when the pin controller 216 receives the trigger signal sent from the timer controller 215 , the pin controller 216 activates the interrupt controller 217 . Therefore, the interrupt controller 217 sends an interruption signal to the controller 218 .
- the controller 218 executes a predetermined programmed code according to the interruption signal.
- the predetermined programmed code is stored in a memory.
- FIG. 3 is a schematic diagram of another exemplary embodiment of an operating system, according to various aspects of the present disclosure.
- FIG. 3 is similar to FIG. 1 exception that the control circuit 310 of the operating system 300 further comprises a general controller 319 . Since the features of the input/output buffer 311 , the times 312 and 313 , the buffer controller 314 , the timer controller 315 and the pin controller 316 are the same as the features of the input/output buffer 111 , the times 112 and 113 , the buffer controller 114 , the timer controller 115 and the pin controller 116 shown in FIG. 1 , the descriptions of the features of the input/output buffer 311 , the times 312 and 313 , the buffer controller 314 , the timer controller 315 and the pin controller 316 are omitted.
- the general controller 319 when the pin controller 316 operates in the input mode or the output mode, the general controller 319 is configured to set initial voltage levels of the pins PN 1 ⁇ PN 4 and final voltage levels of the pins PN 1 ⁇ PN 4 .
- the general controller 319 sets the initial voltage level of the pin PN 1 at a low level before the checkpoint P 0 and sets the final voltage level of the pin PN 1 at the low level after the checkpoint P 1 .
- the general controller 319 can be applied in the control circuit 210 shown in FIG. 2 .
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Abstract
Description
- This Application claims priority of Taiwan Patent Application No. 106123180, filed on Jul. 11, 2017, the entirety of which is incorporated by reference herein.
- The invention relates to a control circuit, and more particularly to a control circuit which is capable of programming the levels of pins.
- With the development of technology, the sizes of integrated circuits (ICs) have been reduced and the circuit structures of ICs have become increasingly complex. Taking VLSI (very large scale integration) as an example, the number of elements has increased.
- In accordance with an embodiment, a control circuit programs levels of pins and comprises a first slot, a timer controller, an input/output buffer, a buffer controller and a pin controller. The first slot is configured to adjust a first count value according to a clock signal. The timer controller is configured to determine whether the first count value is equal to a first predetermined value. When the first count value is equal to the first predetermined value, the timer controller generates a first trigger signal. The buffer controller is configured to access the input/output buffer. The pin controller is coupled to a first pin, the timer controller and the buffer controller. In an input mode, the pin controller detects a voltage level of the first pin according to the first trigger signal to generate a plurality of detection results. In the input mode, the pin controller stores the plurality of detection results into the input/output buffer via the buffer controller. In an output mode, the pin controller generates an output signal according to the first trigger signal and output data stored in the input/output buffer.
- In accordance with another embodiment, an operating system comprises an integrated circuit and a control circuit. The control circuit is coupled to the integrated circuit via a first pin and comprises a first slot, a timer controller, an input/output buffer, a buffer controller and a pin controller. The first slot is configured to adjust a first count value according to a clock signal. The timer controller is configured to generate a first trigger signal when the first count value is equal to a first predetermined value. The buffer controller is configured to access the input/output buffer. The pin controller is coupled to the first pin, the timer controller and the buffer controller. In an input mode, the pin controller detects a voltage level of the first pin according to the first trigger signal to generate a plurality of detection results. In the input mode, the pin controller stores the plurality of detection results to the input/output buffer via the buffer controller. In an output mode, the pin controller generates an output signal to the integrated circuit according to the first trigger signal and output data stored in the input/output buffer.
- The invention can be more fully understood by referring to the following detailed description and examples with references made to the accompanying drawings, wherein:
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FIG. 1 is a schematic diagram of an exemplary embodiment of an operating system according to various aspects of the present disclosure. -
FIG. 2 is a schematic diagram of another exemplary embodiment of the operating system according to various aspects of the present disclosure. -
FIG. 3 is a schematic diagram of another exemplary embodiment of an operating system according to various aspects of the present disclosure. -
FIG. 4A is a schematic diagram of the voltage level of a pin in an input mode according to various aspects of the present disclosure. -
FIG. 4B is a schematic diagram of the voltage level of the pin in an output mode according to various aspects of the present disclosure. -
FIG. 4C is a schematic diagram of a pulse width modulation (PWM) signal generated by a pin controller of the present disclosure. - The present invention will be described with respect to particular embodiments and with reference to certain drawings, but the invention is not limited thereto and is only limited by the claims. The drawings described are only schematic and are non-limiting. In the drawings, the size of some of the elements may be exaggerated for illustrative purposes and not drawn to scale. The dimensions and the relative dimensions do not correspond to actual dimensions in the practice of the invention.
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FIG. 1 is a schematic diagram of an exemplary embodiment of an operating system, according to various aspects of the present disclosure. Theoperating system 100 comprises acontrol circuit 110 and anintegrated circuit 120. Thecontrol circuit 110 communicates with theintegrated circuit 120 via the pins PN1˜PN4, but the disclosure is not limited thereto. In other embodiments, thecontrol circuit 110 may utilize more or fewer than four pins to provide information to the integratedcircuit 120 or to receive information from the integratedcircuit 120. In this embodiment, when thecontrol circuit 110 executes a programmed code (not shown) stored in itself, thecontrol circuit 110 programs the voltage level of at least one of the pins PN1˜PN4 such that the communication between thecontrol circuit 110 and theintegrated circuit 120 conforms with a communication protocol. In one embodiment, thecontrol circuit 110 simulates a serial communication protocol, but the disclosure is not limited thereto. In another embodiment, thecontrol circuit 110 simulates a parallel communication protocol. In some embodiments, when thecontrol circuit 110 executes the programmed code (not shown) stored in itself, thecontrol circuit 110 receives the information provided from the integratedcircuit 120 according to the voltage level of at least one of the pins PN1˜PN4. In other embodiments, thecontrol circuit 110 serves as a clock generator. In this case, when thecontrol circuit 110 executes a programmed code (not shown) stored in itself, thecontrol circuit 110 outputs a pulse width modulation (PWM) signal to the integratedcircuit 120. - In this embodiment, each of the pins PN1˜PN4 performs different roles to transmit different signals in different times. Taking the pin PN1 as an example, during a first work period, the
control circuit 110 may serve the pin PN1 as a clock pin to transmit a clock signal to the integratedcircuit 120 or receive a clock signal from the integratedcircuit 120 after thecontrol circuit 110 executes an internal programmed code. During a second work period, thecontrol circuit 110 may transmit data to the integratedcircuit 120 or receive data from the integratedcircuit 120 via the pin PN1. During a third work period, the pin PN1 may serve as an input/output pin. Since each of the pins PN1˜PN4 is capable of transmitting signals, which have different types, the utility rate of the pins PN1˜PN4 is increased and the number of pins between thecontrol circuit 110 and the integratedcircuit 120 is not too high. - In this embodiment, the
control circuit 110 is configured to program the voltage levels of the pins PN1˜PN4 and at least comprises an input/output buffer 111,timers buffer controller 114, atimer controller 115 and apin controller 116.FIG. 1 shows the elements related to the invention that are discussed, but the invention is not limited thereto. Thecontrol circuit 110 still may comprise other hardware devices, firmware or software, which are not discussed for brevity. - The input/
output buffer 111 is configured to store data. In one embodiment, thecontrol circuit 110 stores the data received from the integratedcircuit 120 to the input/output buffer 111. In another embodiment, thecontrol circuit 110 reads the data stored in the input/output buffer 111 and provides the stored data to the integratedcircuit 120. In the disclosure, the circuit structure of the input/output buffer 111 is not limited. Any circuit can serve as an input/output buffer 111, as long as the circuit is capable of storing data. In this embodiment, the input/output buffer 111 comprises an output buffer BFO, an input buffer FGI and a status buffer BFS. - The output buffer BFO is configured to store the output data to be provided to the
integrated circuit 120. In one embodiment, a central processing unit (CPU) writes the output data into the output buffer BFO. The input buffer BFI is configured to store the input data received by thecontrol circuit 110. The status buffer BFS is configured to store the status data received by thecontrol circuit 110. For example, assume that thecontrol circuit 110 receives input information which has a plurality of bits. The bits of the input information comprise at least one start bit, at least one data bit and at least one stop bit. In one embodiment, thecontrol circuit 110 stores the value of the start bit and the value of the stop bit into the status buffer BFS and stores the value of the data bit into the input buffer BFI. - The
buffer controller 114 is coupled between thepin controller 116 and the input/output buffer 111 to access the input/output buffer 111. For example, when thecontrol circuit 110 operates in an output mode, thebuffer controller 114 reads the output data stored in the output buffer BFO and provides the stored output data to thepin controller 116. Thepin controller 116 outputs the stored output data to theintegrated circuit 120 via at least one of the pins PN1˜PN4. When thecontrol circuit 110 operates in an input mode, thepin controller 116 provides the input information received by at least one of the pins PN1˜PN4 to thebuffer controller 114. The input information comprises initial data, stop data and input data. Then, thebuffer controller 114 stores the initial data and the stop data into the status buffer BFS and stores the input data into the input buffer BFI. The internal circuit of thebuffer controller 114 is not limited in the present disclosure. Any circuit can serve as abuffer controller 114, as long as the circuit is capable of accessing buffers. - In this embodiment, the
timer controller 115 is coupled to thetimers timer controller 115 is coupled to more timers or fewer timers. Thetimer 112 comprises slots ST1 and ST2, but the disclosure is not limited thereto. In other embodiments, thetimer 112 comprises more or fewer than two slots. In this embodiment, thetimer 113 comprises slots ST3 and ST4, but the disclosure is not limited thereto. In other embodiments, thetimer 113 comprises more or fewer than two slots. In this embodiment, the number of slots of thetimer 112 is the same as the number of slots of thetimer 113, but the disclosure is not limited thereto. In other embodiments, the number of slots of thetimer 112 may be more than or less than the number of slots of thetimer 113. Since the feature of thetimer 112 is the same as the feature of thetimer 113, thetimer 112 is given as an example. - As shown in
FIG. 1 , the slot ST1 has a count value VL1, and the slot ST2 has a count value VL2. When the slot ST1 is activated, the slot ST1 increases or reduces the count value VL1 according to a first clock signal. Similarly, when the slot ST2 is activated, the slot ST2 increases or reduces the count value VL2 according to a second clock signal. In this case, the frequency of the first clock signal may be the same as or different from the frequency of the second clock signal. - Additionally, the first and second clock signals may be provided from a single clock source or provided from different clock sources. In one embodiment, the first and second clock signals are the same clock signal. Furthermore, the slot ST1 may be directly coupled to a first clock source to receive the first clock signal. In other embodiments, the slot ST1 may be indirectly coupled to the first clock source. For example, at least one prescaler is disposed between the slot ST1 and the first clock source. Similarly, the slot ST2 may be directly coupled to a second clock source to receive the second clock signal. In other embodiments, the slot ST2 may be indirectly coupled to the second clock source. For example, at least one prescaler is disposed between the slot ST2 and the second clock source. In some embodiments, one of the slots ST1 and ST2 is directly coupled to the corresponding clock source and the other is indirectly coupled to the corresponding clock source.
- The
timer controller 115 is coupled to thetimers pin controller 116 according to the count values VL1˜VL4 of the slots ST1˜ST4. For example, when the count value VL1 is equal to a first predetermined value, thetimer controller 115 generates a first trigger signal to thepin controller 116. Similarly, when the count value VL2 is equal to a second predetermined value, thetimer controller 115 generates a second trigger signal to thepin controller 116. When the count value VL3 is equal to a third predetermined value, thetimer controller 115 generates a third trigger signal to thepin controller 116. When the count value VL4 is equal to a fourth predetermined value, thetimer controller 115 generates a fourth trigger signal to thepin controller 116. The first, second, third and fourth predetermined values are different. In one embodiment, the first predetermined value is less than the second predetermined value, the second predetermined value is less than the third predetermined value, the third predetermined value is less than the fourth predetermined value. In other embodiments, one of the first, second, third and fourth predetermined values is equal to another of the first, second, third and fourth predetermined values. - In one embodiment, the first, second, third and fourth predetermined values may be set by the
timer controller 115. In other embodiments, the first, second, third and fourth predetermined values are set by another controller (not shown) disposed in thecontrol circuit 110. In some embodiments, the slots ST1˜ST4 are controlled by thetimer controller 115. For example, thetimer controller 115 activates the slots ST1˜ST4. When the slots ST1˜ST4 are activated, the slots ST1˜ST4 increase or reduce the count values VL1˜VL4 respectively. In another embodiment, thetimer controller 115 resets the count values VL1˜VL4 such that the count values VL1˜VL4 are equal to an initial value. In other embodiments, the slots ST1˜ST4 are controlled by another controller (not shown) disposed in thecontrol circuit 110. In this case, the another controller of thecontrol circuit 110 activates or resets the slots ST1˜ST4. - In this embodiment, when the count value VL1 is equal to the first predetermined value, the
timer controller 115 resets the slot ST1 such that the count value VL1 is equal to an initial value. When the count value VL2 is equal to the second predetermined value, thetimer controller 115 resets the slot ST2 such that the count value VL2 is equal to an initial value. When the count value VL3 is equal to the third predetermined value, thetimer controller 115 resets the slot ST3 such that the count value VL3 is equal to an initial value. When the count value VL4 is equal to the third predetermined value, thetimer controller 115 resets the slot ST4 such that the count value VL4 is equal to an initial value. In one embodiment, when one of the count values VL1˜VL4 is equal to the corresponding initial value, thetimer controller 115 activates the corresponding slot among the slots ST1˜ST4 such that the corresponding slot performs a counting operation, for example, the corresponding slot may adjust the corresponding count value again. The invention does not limit the number that each of slot ST1˜ST4 performs the counting operation. In one embodiment, the number of times the counting operation is performed by each of slots ST1˜ST4 is controlled by thetimer controller 115. - The
pin controller 116 is coupled to thetimer controller 115 and thebuffer controller 114 and is coupled to theintegrated circuit 120 via the pins PN1˜PN4. In this embodiment, thepin controller 116 controls or detects the voltage level of at least one of the pins PN1˜PN4 according to the time points when thetimer controller 115 generates the trigger signals. Therefore, the time points when thetimer controller 115 generates the trigger signals are referred to as checkpoints. Thepin controller 116 controls or detects the voltage level of at least one of the pins PN1˜PN4 at the checkpoints. - Assume that when the count value VL1 of the slot ST1 is equal to a first predetermined value, the
timer controller 115 generates a first trigger signal. In this case, the time point when thetimer controller 115 generates the first trigger signal is referred to as a first checkpoint. Assume that when the count value VL2 of the slot ST2 is equal to a second predetermined value, thetimer controller 115 generates a second trigger signal. In this case, the time point when thetimer controller 115 generates the second trigger signal is referred to as a second checkpoint. Assume that when the count value VL3 of the slot ST3 is equal to a third predetermined value, thetimer controller 115 generates a third trigger signal. In this case, the time point when thetimer controller 115 generates the third trigger signal is referred to as a third checkpoint. Assume that when the count value VL4 of the slot ST4 is equal to a fourth predetermined value, thetimer controller 115 generates a fourth trigger signal. In this case, the time point when thetimer controller 115 generates the fourth trigger signal is referred to as a fourth checkpoint. - Taking the pin PN1 as an example, during an input mode, the
pin controller 116 detects the voltage level of the pin PN1 at the first, second, third and fourth checkpoints to generate many detection results. In one embodiment, thepin controller 116 immediately detects the voltage level of the pin PN1 at the first, second, third and fourth checkpoints. In other words, each when thepin controller 116 receives the trigger signals generated by thetimer controller 115, thepin controller 116 immediately detects the voltage level of the pin PN1. In another embodiment, thepin controller 116 detects the voltage level of the pin PN1 between two checkpoints (e.g. the first and second checkpoints). For example, after the first checkpoint, thepin controller 116 waits a predetermined time and then detects the voltage level of the pin PN1, wherein the predetermined time is shorter than the time between the first and second checkpoints. In this embodiment, thepin controller 116 stores the detection results to the input/output buffer 111 via thebuffer controller 114. In an output mode, thepin controller 116 reads the output data stored in the input/output buffer 111 via thebuffer controller 114 at the first, second, third and fourth checkpoints and generates an output signal to theintegrated circuit 120 according to the stored output data. Taking the first checkpoint as an example, thepin controller 116 may immediately read the output data stored in the input/output buffer 111 at the first checkpoint or may wait a predetermined time after the first checkpoint and then read the output data stored in the input/output buffer 111. In one embodiment, thepin controller 116 outputs the output signal via at least one of the pins PN1˜PN4. For example, assume that thepin controller 116 detects the voltage level of the pin PN1 in the input mode. In this case, thepin controller 116 may utilize the pin PN1 to output the output signal in the output mode. In another embodiment, thepin controller 116 utilizes the pin PN2 to output the output signal. - In some embodiments, when the
control circuit 110 operates in the output mode, thepin controller 116 maintains or changes the voltage level of at least one of the pins PN1˜PN4 at the first, second, third and fourth checkpoints to generate a PWM signal to theintegrated circuit 120. Taking the pin PN1 as an example, thepin controller 116 sets the voltage level of the pin PN1 at a high level at the first checkpoint. Thepin controller 116 sets the voltage level of the pin PN1 at a low level at the second checkpoint. Thepin controller 116 sets the voltage level of the pin PN1 at the high level at the third checkpoint. Thepin controller 116 sets the voltage level of the pin PN1 at the low level at the fourth checkpoint. - In the above embodiments, the
timer controller 115 generates many trigger signals according to the count values of different slots, but the disclosure is not limited thereto. In other embodiments, thetimer controller 115 generates many trigger signals according to the count values of a slot. For example, when the count value VL1 of the slot ST1 is equal to a predetermined value, thetimer controller 115 generates a trigger signal to thepin controller 116. Next, thetimer controller 115 first resets the slot ST1 and then activates the slot ST1 such that the slot ST1 increases or reduces the count value VL1 again. When the count value VL1 of the slot ST1 is equal to the predetermined value again, thetimer controller 115 generates the trigger signal to thepin controller 116 again. Therefore, thetimer controller 115 is capable of generating a plurality of trigger signals according to the count values of a single slot. -
FIG. 4A is a schematic diagram of the voltage level of the pin PN1 in an input mode according to various aspects of the present disclosure. In the input mode, when thetimer controller 115 sends a trigger signal, thepin controller 116 reads the voltage level of the pin PN1 and stores the voltage level of the pin PN1. In this embodiment, the symbol CLK represents a clock signal, wherein the slots ST1˜ST4 adjusts the count values VL1˜VL4 according to the clock signal CLK. - The symbol TSR represents a start time point of input data. The start time point of the input data is an end time point of initial data. In one embodiment, the voltage level (e.g. a low level) before the start time point TSR is stored in the status buffer BFS.
- The symbol TCP1 is a first checkpoint. The first checkpoint is a time point when the
timer controller 115 sends a first trigger signal. In one embodiment, when the count value VL1 is equal to a first predetermined value, thetimer controller 115 sends the first trigger signal. At the first checkpoint Tap′, thepin controller 116 determines that the voltage level of the pin PN1 is a high level such that thepin controller 116 writes the value “1” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [1]. - The symbol TCP2 is a second checkpoint. The second checkpoint is a time point when the
timer controller 115 sends a second trigger signal. In one embodiment, when the count value VL2 is equal to a second predetermined value, thetimer controller 115 sends the second trigger signal. At the second checkpoint TCP2, thepin controller 116 determines that the voltage level of the pin PN1 is a low level such that thepin controller 116 writes the value “0” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [10]. - The symbol TCP3 is a third checkpoint. The third checkpoint is a time point at which the
timer controller 115 sends a third trigger signal. In one embodiment, when the count value VL3 is equal to a third predetermined value, thetimer controller 115 sends the third trigger signal. At the third checkpoint TCP3, thepin controller 116 determines that the voltage level of the pin PN3 is the high level such that thepin controller 116 writes the value “1” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is [101]. - The symbol TCP4 is a fourth checkpoint. The fourth checkpoint is a time point at which the
timer controller 115 sends a fourth trigger signal. In one embodiment, when the count value VL4 is equal to a fourth predetermined value, thetimer controller 115 sends the fourth trigger signal. At the fourth checkpoint TCP4, thepin controller 116 determines that the voltage level of the pin PN1 is a low level such that thepin controller 116 writes the value “0” into the input buffer BFI. Therefore, the value stored in the input buffer BFI is - Furthermore, the fourth checkpoint TCP4 is also an end time point TSP. Therefore, the
pin controller 116 detects and stores the voltage level (e.g. a high level) to the status buffer BFS, wherein the stored voltage level occurs after the end time point TSP. -
FIG. 4B is a schematic diagram of the voltage level of the pin PN1 in an output mode according to various aspects of the present disclosure. In the output mode, when thetimer controller 115 sends a trigger signal, thepin controller 116 reads the output data stored in the input/output buffer 111 and controls the voltage level of the pin PN1 according to the stored output data. In this embodiment, the symbol CLK represents a clock signal, wherein the slots ST1˜ST4 adjust the count values VL1˜VL4 according to the clock signal CLK. The symbol TSR represents a start time point. Before the start time point TSR, the voltage level of the pin PN1 is a predetermined voltage level, such as a low level. - At the first checkpoint TCP1, the
pin controller 116 reads output data stored in the output buffer BFO. Assume that the value of the output data is [1110]. The output buffer BFO outputs the most significant bit (MSB) of the output data to thepin controller 116. Since the value of the MSB of the output data is “1”, thepin controller 116 sets and maintains the voltage level of the pin PN1 at a high level between the start time point TSR and the first checkpoint TCP1. At this time, the value stored in the output buffer BFO is [110]. - At the second checkpoint TCP2, the
pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [110]. The output buffer BFO outputs the MSB of the output data to thepin controller 116. Since the value of the MSB of the output data is “1”, thepin controller 116 sets and maintains the voltage level of the pin PN1 to the high level between the first checkpoint TCP1 and the second checkpoint TCP2. At this time, the value stored in the output buffer BFO is [10]. - At the third checkpoint TCP3, the
pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [10]. The output buffer BFO outputs the MSB of the output data to thepin controller 116. Since the value of the MSB of the output data is “1”, thepin controller 116 sets and maintains the voltage level of the pin PN1 to the high level between the second checkpoint TCP2 and the third checkpoint TCP3. At this time, the value stored in the output buffer BFO is [0]. - At the fourth checkpoint TCP4, the
pin controller 116 reads the output data stored in the output buffer BFO. At this time, the value of the output data is [0]. The output buffer BFO outputs the MSB of the output data to thepin controller 116. Since the value of the MSB of the output data is “0”, thepin controller 116 sets and maintains the voltage level of the pin PN1 to a low level between the third checkpoint TCP3 and the fourth checkpoint TCP4. At this time, the value stored in the output buffer BFO has been output to thepin controller 116. Therefore, the slots ST1˜ST4 stops adjusting the count values VL1˜VL4. After the end time point TSP, the voltage level of the pin PN1 is maintained to a final level, such as a high level. -
FIG. 4C is a schematic diagram of an exemplary embodiment of a PWM signal generated by thepin controller 116. In the output mode, thepin controller 116 changes the voltage level of the pin PN1 at each checkpoint to generate a PWM signal. Assume that before the checkpoint P0, the voltage level of the pin PN1 is an initial level, such as a low level. - In the checkpoint P0, the
pin controller 116 controls the voltage level of the pin PN1 at the low level. In the checkpoint P1, thepin controller 116 changes the voltage level of the pin PN1 from the low level to a high level. After the checkpoint P1, the voltage level of the pin PN1 is a final level, such as the low level. In this embodiment, the checkpoint P0 represents a time point at which thetimer controller 115 sends a trigger signal when the count value VL1 of the slot ST1 is equal to a first predetermined value. The checkpoint P1 represents another time point at which thetimer controller 115 sends another trigger signal when the count value VL2 of the slot ST2 is equal to a second predetermined value. In this case, thetimer controller 115 controls the number of times the slots ST1 and ST2 perform a counting operation and generates a PWM signal having many pulses according to the number of executions of the counting operation. -
FIG. 2 is a schematic diagram of another exemplary embodiment of the operating system, according to various aspects of the present disclosure.FIG. 2 is similar toFIG. 1 exception that thecontrol circuit 210 of theoperating system 200 shown inFIG. 2 further comprises an interruptcontroller 217 and acontroller 218. Since the features of the input/output buffer 211, thetimes buffer controller 214, thetimer controller 215 and thepin controller 216 are the same as the features of the input/output buffer 111, thetimes buffer controller 114, thetimer controller 115 and thepin controller 116 shown inFIG. 1 , the descriptions of the features of the input/output buffer 211, thetimes buffer controller 214, thetimer controller 215 and thepin controller 216 are omitted. - In this embodiment, when the
pin controller 216 receives the trigger signal sent from thetimer controller 215, thepin controller 216 activates the interruptcontroller 217. Therefore, the interruptcontroller 217 sends an interruption signal to thecontroller 218. Thecontroller 218 executes a predetermined programmed code according to the interruption signal. In one embodiment, the predetermined programmed code is stored in a memory. -
FIG. 3 is a schematic diagram of another exemplary embodiment of an operating system, according to various aspects of the present disclosure.FIG. 3 is similar toFIG. 1 exception that thecontrol circuit 310 of theoperating system 300 further comprises ageneral controller 319. Since the features of the input/output buffer 311, thetimes buffer controller 314, thetimer controller 315 and thepin controller 316 are the same as the features of the input/output buffer 111, thetimes buffer controller 114, thetimer controller 115 and thepin controller 116 shown inFIG. 1 , the descriptions of the features of the input/output buffer 311, thetimes buffer controller 314, thetimer controller 315 and thepin controller 316 are omitted. - In this embodiment, when the
pin controller 316 operates in the input mode or the output mode, thegeneral controller 319 is configured to set initial voltage levels of the pins PN1˜PN4 and final voltage levels of the pins PN1˜PN4. TakingFIG. 4C as an example, thegeneral controller 319 sets the initial voltage level of the pin PN1 at a low level before the checkpoint P0 and sets the final voltage level of the pin PN1 at the low level after the checkpoint P1. In other embodiment, thegeneral controller 319 can be applied in thecontrol circuit 210 shown inFIG. 2 . - Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.
- While the invention has been described by way of example and in terms of the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. On the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). For example, it should be understood that the system, device and method may be realized in software, hardware, firmware, or any combination thereof. Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.
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