TWI787893B - Functional device and method for controlling variable physical parameter - Google Patents

Abstract

A functional device for controlling a variable physical parameter includes an input unit, a storage unit and a processing unit. The variable physical parameter is characterized based on a physical parameter target state represented by a physical parameter target state code. The storage unit stores a variable physical parameter state code representing a variable physical parameter state being one in which the variable physical parameter is expected to be within a target time interval. The processing unit is configured to change the variable physical parameter state code into the physical parameter target state code by means of the input unit, and causes the variable physical parameter state to be equal to the physical parameter target state within the target time interval based on the changed variable physical parameter state code being equal to the physical parameter target state code.

Description

Functional device and method for controlling variable physical parameters

The present disclosure relates to a functional device, and more particularly to functional devices and methods for controlling a variable physical parameter.

A control device can generate a control signal to control a physical parameter application unit included in a functional device. The functional device uses the control signal to control the physical parameter application unit. The physical parameter application unit can use at least one of a mechanical energy, an electric energy and a light energy, and can be a motor for an access control, a relay for an electric control, and an energy conversion One of the energy converters. In order to effectively control the physical parameter application unit, the functional device can obtain a physical parameter status code representing a physical parameter status. The functional device may need an improved mechanism to effectively use the physical parameter status code and thereby effectively control the physical parameter application unit.

US Publication No. 2015/0357887 A1 discloses a product specification setting device and a fan motor equipped with it. US Patent Publication No. 7,411,505 B2 discloses a switch status and radio frequency identification tag.

One purpose of this disclosure is to provide a A physical parameter target status code is used in the interval to effectively control a functional device with a variable physical parameter.

An embodiment of the present disclosure is to provide a functional device for controlling a variable physical parameter, wherein the variable physical parameter is characterized based on a physical parameter target state represented by a physical parameter target state code. The functional device includes an input unit, a storage unit and a processing unit. The storage unit stores a variable physical parameter state code representing a variable physical parameter state, wherein the variable physical parameter state is a state that the variable physical parameter is expected to be in within a target time interval. The processing unit is coupled to the input unit and the storage unit, and is configured to change the variable physical parameter status code into the physical parameter target status code by means of the input unit, and based on the physical parameter being equal to the physical parameter within the target time interval The variable physical parameter status code of the target status code is changed to make the variable physical parameter status equal to the physical parameter target status.

Another embodiment of the present disclosure is to provide a method for controlling a variable physical parameter, wherein the variable physical parameter is characterized based on a physical parameter target state represented by a physical parameter target state code. The method comprises the following steps: storing a variable physical parameter state code representing a variable physical parameter state, wherein the variable physical parameter state is a state that the variable physical parameter is expected to be in within a target time interval; The variable physical parameter status code is changed to the physical parameter target status code; and during the target time interval, the variable physical parameter is made based on the changed variable physical parameter status code equal to the physical parameter target status code The state is equal to the physical parameter target state.

Another embodiment of the present disclosure is to provide a method for a Functional means of variable physical parameters, wherein the variable physical parameters are characterized based on a physical parameter target state represented by a physical parameter target state code. The functional device includes a light-emitting diode matrix and a processing unit. The LED matrix includes an LED associated with a target time interval. The processing unit is coupled to the light emitting diode matrix, configured to obtain the physical parameter target state code within the target time interval, and make the light emitting diode display a state based on the obtained physical parameter target state code instruct. The state indication is used to indicate that the variable physical parameter is configured to be in a specific state of the physical parameter target state within the target time interval.

Another embodiment of the present disclosure is to provide a method for a variable physical parameter characterized based on a physical parameter target state represented by a physical parameter target state code. The method comprises the steps of: providing an LED matrix including an LED, wherein the LED is associated with a target time interval; obtaining the physical parameter target status code within the target time interval; and making the light-emitting diode display a state indication based on the obtained physical parameter target state code, the state indication being used to indicate that the variable physical parameter is configured to be in the physical parameter target state within the target time interval specific state.

130: Functional device

331: processing unit

332: storage unit

335:Physical Parameter Application Unit

3357: input part

3358: output section

342, 343, 346, 34A: timer

380: input unit

3801: button

3805, 3807, 380A, 380B: push button switch

380Z: Silicon film

382: display unit

385:Light Emitting Diode Matrix

3851, 3852, 3853: light emitting diodes

385A: Substrate

387:Trigger application unit

395: user

581: first light-emitting diode column

582: second light emitting diode column

921, 931: control system

9211, 9212, 9213, 9214, 9215, 9216, 9217, 9218, 9219, 9220, 9221, 922, 9223, 9224, 9225, 9226, 9227, 9228, 9229, 9230, 9231, 9232, 9233, 9234, 9311, 9312: Implementation structure

A1, A2: Silicone part

AK81: The first data confirms the operation

AK82: The second data confirms the operation

AK8A: The data is confirmed

AS81, AS82, AS8T, AS8U: memory address

AU11: Physical parameter formation area

B1, B2: Conductive adhesive layer

BB8C, BB8H, BB8F, BQ82, JS81, JS82, JS83, JS86: user input action

BD81: Counting operation

CF81: Data Comparison

CG81: Control Data

DG81, DG83: code difference

DJ1U: application range limit value pair

DP1A: Rated range limit value pair

DQ13, DQ14: specified range limit value

DQ15: First application range limit value

DQ16: second application range limit value

DQ1T: Specified range limit value pair

DQ1U: application range limit value pair

DT81, DT8T: Physical parameter status difference

EB1T: specific range code

EF1U: Measuring value application range code

EG11, EG12, EG1A, EG1D: variable physical parameter status code

EG1B, EG1E: Physical parameter application status code

EG1C, EG1E, EG1P: physical parameter target status code

EGAA: variable physical parameter status code array

EL11, EL12: Measured value reference range code

EL14: specific measurement value range code

EL1T: Specified range code for measured value

EL1U: Measuring value application range code

EM11, EM12: measurement value reference range code

EM1T, EM1U: Measured value target range code

EW11, EW12: physical parameters reference status code

EW1T: Physical parameter application status code

EW1U: physical parameter target status code

FA81: Measurement Application Functions

FJ8E, FK8E: full range of measured value representation

FT21, FT31: Timer specification

GA8HE: Rated clock time interval representation

GA8HR: clock time reference interval representation

GA8HT: clock time specified interval representation

GA8HU: clock time application range representation

GA8TR: clock time display

GAL8: Measurement Application Functional Specification

GD81: Time Control

GM8T, GM8U, GN8U: data storage control operation

GX8T, GX8U: physical parameter relationship check control

GY81, GY85: signal generation control

HH95, HH97: Specifies the measured value format

HJ1ET: Remaining time specified interval

HJ1EU: Remaining time application interval

HR1E: Rated clock time interval

HR1E1, HR1E2: clock time reference interval

HR1E4: specific clock time interval

HR1ET: clock time specified interval

HR1ET1: start boundary time

HR1ET2: End Boundary Time

HR1EU: clock time application interval

HR1N: Rated measurement range

HS81: physical parameter specified range code type identifier

HV1T, HV1U, HV1V, HY1U: target time interval

JE11, JE12: Reference status of physical parameters

JE16: Specific Physical Parameter Status

JE1L, JE1T, JG1B, JG1E: Application status of physical parameters

JE1U, JG1C, JG1F, JG1P: physical parameter target state

JG11, JG12, JG1A, JG1D: variable physical parameter status

JQ81: trigger event

KB81, KQ61, KQ81: Mathematical Relations

KC81: Time relationship

KD9T, KD9U: physical parameter relationship

KT81: Time relationship

LE81: relative interval position

LH8T: specify the length of time

LH8U: Application time length

LL72, LL81, LL82, LL83, LL84: status indication

MC81: First Scientific Computing

MD81: Second Scientific Computing

ME81, ME85, MH81, MH85: Scientific Computing

MM80, MM82: Methods

NJ81, NY61, NY80, NY81: measured value

NK8A: Document determination procedure

NR81: clock reference time value

NY8A: variable count value

PQ81: Logical decision

QB81: Preset time reference interval sequence

QJ8E, QK8E: full range of measured values

QU1A: variable physical parameters

RD1E1, RD1E2: Reference range of physical parameters

RD1ET, RD1EU: physical parameter target range

RN11, RN12, RQ11, RQ12: Reference range of measured values

RN1T, RN1U, RQ3V: Measured value target range

RJ1U, RQ1U: application range of measured values

RQ1T: Specified range of measured value

SA81, SA82, SA87, SH81, SH82, SH86, SJ81: operation request signal

SG67, SG81, SG85, SG87, SG8K: Operation signal

ST81, SY61, SY80, SY81: sensing signal

TA1A: variable remaining time

TC1A: Variable application time

TF61, TY81: Operating time

TH1A: clock time

TQ11: clock time type

TQ21: Remaining time type

TR81: clock reference time

TU11: Physical parameter type

TS81: physical parameter specified range code type

TT82: start time

UC81, UC82: Setting stage

UD81: Timing stage

UF8A: variable clock time interval code

UF8T, UF8U: clock time application interval code

UG8U: Use interval code for remaining time

UN8A: variable physical parameter range code

UQ11, UQ12: Physical parameter specified range code

UQ1T, UQ1U: physical parameter target range code

UY95: specify the number of bits

VH8T, VH8U: Measurement time length value

VL81: Relative value

WX8HE: First Data Encoding Rules

WX8HR: data encoding rules

WX8HU: Second Data Encoding Rules

XE72, XE81, XE82, XE83, XE84: specific state

XS81: Specific empirical formulas

XV81: Operation reference code

YS81, YS82, YS8T, YS8U: memory location

ZD1U1, ZD1U2: preset physical parameter target range limit

ZF81: Subtraction operation

ZJ82: display operation

ZT81: Sensing operation

ZX8HE, ZX8HR, ZX8HT, ZX8HU, ZX8TR: data encoding operation

This disclosure can be understood more deeply through the detailed description of the following diagrams:

FIG. 1 : is a schematic diagram of a control system in various embodiments of the present disclosure.

FIG. 2 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 3 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 4 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 5 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 6 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 7 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 8 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 9 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 10 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 11 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 12 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 13 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

Figure 14: An implementation structure for the control system shown in Figure 1 schematic diagram.

FIG. 15 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 16 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 17 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 18 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 19 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 20 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 21 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 22 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 23 is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 24 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 25 : is a schematic diagram of an implementation structure of the control system shown in FIG. 1 .

FIG. 26 : is a schematic diagram of a control system in various embodiments of the present disclosure.

FIG. 27 : is a schematic diagram of an implementation structure of the control system shown in FIG. 26 .

FIG. 28 : is a schematic diagram of an implementation structure of the control system shown in FIG. 26 .

Please refer to FIG. 1 , which is a schematic diagram of a control system 921 in various embodiments of the present disclosure. The control system 921 comprises a functional device 130 for controlling a variable physical parameter QU1A. For example, the variable physical parameter QU1A is characterized based on a physical parameter target state JG1C represented by a physical parameter target state code EG1C. The functional device 130 includes an input unit 380 , a storage unit 332 and a processing unit 331 .

The storage unit 332 stores a variable physical parameter state code EG1A representing a variable physical parameter state JG1A. For example, the variable physical parameter state JG1A is a state that the variable physical parameter QU1A is expected to be in within a target time interval HV1U. The processing unit 331 is coupled to the input unit 380 and the storage unit 332, configured to rely on the input unit 380 to change the variable physical parameter state code EG1A into the physical parameter target state code EG1C, and in the target time interval HV1U makes the variable physical parameter state JG1A equal to the physical parameter target state JG1C based on the changed variable physical parameter state code EG1A equal to the physical parameter target state code EG1C. For example, the target time interval HV1U is related to the stored variable physical parameter status code EG1A.

Please refer to Figure 2 and Figure 3. FIG. 2 is a schematic diagram of an implementation structure 9211 of the control system 921 shown in FIG. 1 . Figure 3 shows the A schematic diagram of an implementation structure 9212 of the control system 921 is shown in FIG. 1 . As shown in FIG. 2 and FIG. 3 , each structure of the implementation structure 9211 and the implementation structure 9212 includes the functional device 130 . In some embodiments, the functional device 130 further includes an LED matrix 385 coupled to the processing unit 331 .

The variable physical parameter QU1A is related to a variable application time TC1A. The variable application time TC1A is characterized based on the target time interval HV1U and is one of a clock time TH1A and a variable remaining time TA1A. For example, the target time interval HV1U is one of a clock time target interval and a remaining time target interval. The LED matrix 385 includes an LED 3852 associated with the target time interval HV1U.

Under the condition that the variable physical parameter state code EG1A is equal to the physical parameter target state code EG1C and the processing unit 331 determines that the variable application time TC1A is currently in the target time interval HV1U, the processing unit 331 accesses the stored The physical parameter target status code EG1C is accessed, and the light emitting diode 3852 displays a status indication LL82 based on the accessed physical parameter target status code EG1C. The state indicator LL82 is used to indicate that the variable physical parameter QU1A is configured to be in a specific state XE82 of the physical parameter target state JG1C within the target time interval HV1U. For example, the status indicator LL82 has a blink.

The processing unit 331 is coupled to a physical parameter application unit 335 having the variable physical parameter QU1A, and transmits an operation signal SG85 to the physical parameter application unit 335 based on the accessed physical parameter target state code EG1C. The operation signal SG85 is used to cause the physical parameter The data application unit 335 makes the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

In some embodiments, the variable physical parameter QU1A is further characterized based on a physical parameter application state JG1B different from the physical parameter target state JG1C. The physical parameter application status JG1B is represented by a physical parameter application status code EG1B. Under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the processing unit 331 relies on the input unit 380 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to The physical parameter target status code EG1C.

The input unit 380 includes a button switch 3805 . Under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the button switch 3805 receives a user input operation BB8C for selecting the button switch 3805, and responds to the user input operation BB8C to Make the processing unit 331 receive an operation request signal SA81. The processing unit 331 responds to the operation request signal SA81 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter target status code EG1C. For example, the button switch 3805 is coupled to the processing unit 331 . For example, the processing unit 331 relies on the button switch 3805 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter target status code EG1C.

See Figure 1, Figure 2, and Figure 3. A method MM80 for controlling a variable physical parameter QU1A is disclosed. For example, the variable physical parameter QU1A is based on a physical parameter target state code EG1C A physical parameter target state JG1C of the table is characterized.

The method MM80 comprises the following steps: storing a variable physical parameter state code EG1A representing a variable physical parameter state JG1A, wherein the variable physical parameter state JG1A is the variable physical parameter QU1A expected within a target time interval HV1U in a state; change the variable physical parameter status code EG1A to the physical parameter target status code EG1C; and within the target time interval HV1U, based on the changed physical parameter status code equal to the physical parameter target status code EG1C parameter state code EG1A to make the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

In some embodiments, the variable physical parameter QU1A is related to a variable application time TC1A. The variable application time TC1A is characterized based on the target time interval HV1U and is one of a clock time TH1A and a variable remaining time TA1A. The method MM80 further comprises the steps of: providing an LED matrix 385 comprising an LED 3852, wherein the LED 3852 is associated with the target time interval HV1U; providing an LED with the variable physical parameter QU1A The physical parameter application unit 335; and under the condition that the variable physical parameter state code EG1A is equal to the physical parameter target state code EG1C and the target time interval HV1U where the variable application time TC1A is currently located is determined, access the stored The physical parameter target status code EG1C.

The method MM80 further includes the following steps: based on the accessed physical parameter target status code EG1C, making the LED 3852 display a status indication LL82, the status indication LL82 is used to indicate that the variable physical parameter QU1A is in the target The time interval HV1U is configured to Be in a specific state XE82 of the physical parameter target state JG1C; and transmit an operation signal SG85 to the physical parameter application unit 335 based on the accessed physical parameter target state code EG1C, and the operation signal SG85 is used to cause the physical parameter The application unit 335 makes the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

In some embodiments, the variable physical parameter QU1A is further characterized based on a physical parameter application state JG1B different from the physical parameter target state JG1C. The physical parameter application status JG1B is represented by a physical parameter application status code EG1B. On the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the variable physical parameter status code EG1A is changed from the physical parameter application status code EG1B to the physical parameter target status code EG1C. The method MM80 further includes a step of providing a button switch 3805 .

The step of changing the variable physical parameter state code EG1A into the physical parameter target state code EG1C includes the following sub-steps: under the condition that the variable physical parameter state code EG1A is equal to the physical parameter application state code EG1B, make the button switch 3805 receives a user input operation BB8C for selecting the button switch 3805; in response to the user input operation BB8C, receives an operation request signal SA81; and in response to the operation request signal SA81, changes the variable physical parameter status code EG1A from The physical parameter application status code EG1B is changed to the physical parameter target status code EG1C

See Figure 4. FIG. 4 is a schematic diagram of an implementation structure 9213 of the control system 921 shown in FIG. 1 . As shown in FIG. 4 , the implementation structure 9213 includes the functional device 130 . In some embodiments, the variable physical parameter QU1A is characterized based on a physical parameter target state JE1U change. For example, the physical parameter target state JG1C is or is the same as the physical parameter target state JE1U. The functional device 130 further includes a timer 342 coupled to the processing unit 331 .

The timer 342 senses a clock time TH1A to generate a sensing signal SY81. For example, the clock time TH1A is characterized based on a clock time application interval HR1EU represented by a measurement value application range RQ1U. For example, the target time interval HV1U is or is the same as the clock time application interval HR1EU. The processing unit 331 obtains a measurement value NY81 in response to the sensing signal SY81, and the processing unit 331 determines the clock time TH1A by checking a mathematical relationship KQ81 between the measurement value NY81 and the measurement value application range RQ1U. Under the condition of the clock time application interval HR1EU currently in, the variable physical parameter QU1A is in the physical parameter target state JE1U.

Please refer to Figure 5 and Figure 6. FIG. 5 is a schematic diagram of an implementation structure 9214 of the control system 921 shown in FIG. 1 . FIG. 6 is a schematic diagram of an implementation structure 9215 of the control system 921 shown in FIG. 1 . As shown in FIG. 5 and FIG. 6 , each structure of the implementation structure 9214 and the implementation structure 9215 includes the functional device 130 . In some embodiments, the functional device 130 further includes a physical parameter application unit 335 coupled to the processing unit 331 . For example, the functional device 130 is a control target device. The physical parameter application unit 335 is a functional object. The input unit 380 further includes a button switch 380A coupled to the processing unit 331 .

The clock time TH1A is further characterized based on a clock time designation interval HR1ET different from the clock time application interval HR1EU. For example, this clock time specifies interval HR1ET earlier than this clock Time application interval HR1EU. Before the clock time TH1A enters the clock time application interval HR1EU, the input unit 380 receives a user input operation JS81, and makes the processing unit 331 receive an operation request signal SH81 in response to the user input operation JS81. The processing unit 331 determines a specific range code EB1T in response to the operation request signal SH81. The specific range code EB1T indicates the clock time designation interval HR1ET.

For example, the processing unit 331 determines the specific range code EB1T in response to the user input operation JS81. Before the clock time TH1A enters the clock time application interval HR1EU, the button switch 380A receives the user input operation JS81 for selecting the button switch 380A, and makes the processing unit 331 receive the user input operation JS81 in response to the user input operation JS81. Operation request signal SH81. For example, the user input operation BB8C occurs before the user input operation JS81. The processing unit 331 starts the timer 342 in response to one of the user input operation JS81 and the operation request signal SH81. For example, the processing unit 331 activates the timer 342 by means of the button switch 380A.

The processing unit 331 obtains the measurement value NY81 in response to the sensing signal SY81 due to the operation request signal SH81. For example, the operation request signal SH81 is used to determine the specified interval HR1ET of the clock time. The functional device 130 uses the timer 342 to check a time relationship KT81 between the clock time TH1A and the clock time application interval HR1EU based on the operation request signal SH81. For example, the sensing signal SY81 is a clock time signal. The measured value NY81 is a specific count value. For example, the sensing signal SY81 is a digital signal.

The timer 342 conforms to a timer specification FT21. example For example, the measurement value application range RQ1U is preset based on the timer specification FT21. The timer specification FT21 contains a full measured value range representation FK8E for representing a full measured value range QK8E. For example, the measured value application range RQ1U is equal to a part of the full measured value range QK8E. The measured value NY81 is obtained in a specified measured value format HH95. The measurement value application range RQ1U is preset with the designated measurement value format HH95 based on the timer specification FT21. For example, the clock time application interval HR1EU is a clock time candidate interval. The measurement value application range RQ1U is a measurement time value candidate range. The clock time designation interval HR1ET is a clock time target interval. The designated measurement value format HH95 is a designated count value format.

The measurement value application range RQ1U has an application range limit value pair DQ1U, and is represented by a measurement value application range code EL1U. For example, the application range limit value is preset for DQ1U. The processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to obtain the application range limit value pair DQ1U and the measurement value application range code EL1U, and compare the measurement value NY81 with the obtained The application range limit value to DQ1U to check the mathematical relationship KQ81. The physical parameter target state JE1U is represented by a physical parameter target state code EW1U. The physical parameter application unit 335 has the variable physical parameter QU1A. For example, the variable physical parameter QU1A is currently in a physical parameter application state JE1T. The applied range limit pair DQ1U is a candidate range limit pair. The measurement value application range code EL1U is a measurement time value candidate range code. The physical parameter target status code EG1C is or is the same as the physical parameter target status code EW1U.

In some embodiments, under the condition that the processing unit 331 determines that the clock time TH1A is currently in the clock time application interval HR1EU by checking the mathematical relationship KQ81, the processing unit 331 applies Range code EL1U to obtain the physical parameter target state code EW1U, and based on the obtained physical parameter target state code EW1U to perform a physical parameter relationship between the variable physical parameter QU1A and the physical parameter target state JE1U A physical parameter relation check of KD9U controls GX8U.

When the physical parameter application state JE1T is different from the physical parameter target state JE1U and the processing unit 331 determines a physical relationship between the physical parameter target state JE1U and the physical parameter application state JE1T by executing the physical parameter relationship check control GX8U Under the condition of the parameter state difference DT81, the processing unit 331 executes a signal generation control GY85 based on the obtained physical parameter target state code EW1U to generate an operation signal SG85, and transmits the operation signal SG85 to the physical parameter application unit 335 . For example, the operation signal SG85 is one of a function signal and a control signal.

The physical parameter application unit 335 responds to the operation signal SG85 to make the variable physical parameter QU1A enter the physical parameter target state JE1U from the physical parameter application state JE1T. Under the condition that the processing unit 331 determines that the clock time TH1A is currently in the clock time application interval HR1EU by checking the mathematical relationship KQ81, the processing unit 331 executes a data storage control operation GM8U, the data storage control operation GM8U A clock time application interval code UF8U for causing the determined clock time application interval HR1EU to be stored. The variable physical parameter QU1A and the clock time TH1A belong to a physical parameter type TU11 and a clock time type TQ11 respectively. For example, the physical parameter type TU11 is different from the clock time type TQ11. The data storage control operation GM8U causes the clock time application interval code UF8U to be stored by the storage unit 332 .

See Figure 7, Figure 8, and Figure 9. FIG. 7 is a schematic diagram of an implementation structure 9216 of the control system 921 shown in FIG. 1 . FIG. 8 is a schematic diagram of an implementation structure 9217 of the control system 921 shown in FIG. 1 . FIG. 9 is a schematic diagram of an implementation structure 9218 of the control system 921 shown in FIG. 1 . As shown in FIG. 7 , FIG. 8 and FIG. 9 , each structure of the implementation structure 9216 , the implementation structure 9217 and the implementation structure 9218 includes the functional device 130 . The functional device 130 includes the processing unit 331, the timer 342 coupled to the processing unit 331, the storage unit 332 coupled to the processing unit 331, the input unit 380 coupled to the processing unit 331, and the input unit 380 coupled to the processing unit 331. The physical parameter application unit 335 of the processing unit 331 .

In some embodiments, the timer 342 complies with a timer specification FT21. For example, the measurement value application range RQ1U is preset based on the timer specification FT21. The timer specification FT21 contains a full measured value range representation FK8E for representing a full measured value range QK8E. For example, the measured value application range RQ1U is equal to a first part of the full measured value range QK8E. The processing unit 331 is configured to execute a measurement application function FA81 related to the clock time application interval HR1EU. The measurement application function FA81 complies with a measurement application function specification GAL8 related to the clock time application interval HR1EU. For example, the measurement application function FA81 is a physical parameter control function. The measurement application functional specification GAL8 is a Physical parameters control functional specifications.

The processing unit 331 responds to the sensing signal SY81 to obtain the measurement value NY81 in a specified measurement value format HH95. For example, the specified measurement value format HH95 is characterized based on a specified bit number UY95. The clock time TH1A is further characterized based on a nominal clock time interval HR1E. For example, the rated clock time interval HR1E is represented by a rated measurement value range HR1N, and includes a plurality of different clock time reference intervals HR1E1, HR1E2, . . . represented by a plurality of different measurement value reference ranges RQ11, RQ12, . For example, the nominal clock time interval HR1E is evenly divided to form the plurality of different clock time reference intervals HR1E1, HR1E2, . . . The setpoint measured value range HR1N is a setpoint measured time value range. The plurality of different measured value reference ranges RQ11 , RQ12 , .

The plurality of different clock time reference intervals HR1E1, HR1E2, . . . include the clock time application interval HR1EU. The measurement application function specification GAL8 includes the timer specification FT21, a rated clock time interval representation GA8HE for representing the rated clock time interval HR1E, and a clock time application interval representation GA8HU for representing the clock time application interval HR1EU.

The nominal measured value range HR1N is equal to at least a second part of the full measured value range QK8E, based on one of the timer specification FT21, the measurement application function specification GAL8 and a first data encoding rule WX8HE to use the specified measurement Value format HH95 is preset, has a nominal range limit value pair DP1A, and contains references from complex different measured values The complex reference ranges RQ11, RQ12, . . . of different measured values represented by the range codes EL11, EL12, .

For example, the rated range limit value pair DP1A is preset with the designated measured value format HH95, and the plurality of different measured value reference ranges RQ11, RQ12, . . . include the measured value application range RQ1U. The first data encoding rule WX8HE is used to convert the rated clock time interval representation GA8HE, and is formulated based on the timer specification FT21. For example, the plural different measured value reference range codes EL11, EL12, . . . are respectively plural measured time value reference range codes.

In some embodiments, the measurement value application range RQ1U is represented by a measurement value application range code EL1U contained in the plurality of different measurement value reference range codes EL11, EL12, ..., has an application range limit value pair DQ1U, and The specific measurement value format HH95 is preset based on one of the timer specification FT21, the measurement application function specification GAL8 and a second data encoding rule WX8HU. For example, the plurality of different measured value reference range codes EL11, EL12, . . . are all preset based on the measurement application function specification GAL8. The second data encoding rule WX8HU is used to convert the clock time application interval representation GA8HU, and is formulated based on the timer specification FT21. The application range limit value pair DQ1U includes a first application range limit value DQ15 and a second application range limit value DQ16 corresponding to the first application range limit value DQ15 .

The functional device 130 further includes a trigger application unit 387 coupled to the processing unit 331 . The storage unit 332 stores the preset rated range limit value pair DP1A and a variable clock time interval code UF8A. When a trigger event JQ81 related to the trigger application unit 387 When occurring, the variable clock time interval code UF8A is equal to a specific measurement range code EL14 selected from the plurality of different measurement value reference range codes EL11, EL12, . . . For example, the specific measurement value range code EL14 indicates a specific clock time interval HR1E4 previously determined based on a sensing operation ZT81. The specific clock time interval HR1E4 is selected from the plurality of different clock time reference intervals HR1E1, HR1E2, . . . The sensing operation ZT81 performed by the timer 342 is used to sense the clock time TH1A.

Before the trigger event JQ81 occurs, the specific measurement value range code EL14 is assigned to the variable clock time interval code UF8A. The trigger application unit 387 makes the processing unit 331 receive an operation request signal SJ81 in response to the trigger event JQ81. Under the condition that the trigger event JQ81 occurs, the processing unit 331 responds to the operation request signal SJ81 to obtain an operation reference data code XV81 from the storage unit 332, and executes using the operation reference data by running a data determination program NK8A A data of code XV81 determines AK8A to determine the measurement value application range code EL1U selected from the plurality of different measurement value reference range codes EL11, EL12, ... in order to select the measurement from the plurality of different measurement value reference ranges RQ11, RQ12, ... Values apply in the range RQ1U. The operation reference code XV81 is the same as an allowable reference code preset based on the measurement application function specification GAL8. The data determination program NK8A is constructed based on the measurement application function specification GAL8.

The data determination AK8A is one of a first data determination operation AK81 and a second data determination operation AK82. In the operation reference code XV81 is obtained by accessing the variable clock time interval code UF8A stored in the storage unit 332 to be identical to the specific measurement Under the condition of the value range code EL14, it is the data determination AK8A of the first data determination operation AK81 to determine the measurement value application range code EL1U based on the obtained specific measurement value range code EL14. For example, the first data determination operation AK81 is a first scientific calculation MC81 using the obtained specific measurement value range code EL14. The measured value application range code EL1U determined is the same as or different from the specific measured value range code EL14 obtained.

On the condition that the operation reference code XV81 is obtained by accessing the pair of rated range limit values DP1A stored in the storage unit 332 to be the same as the preset pair of rated range limit values DP1A, it is the The data determination AK8A of the second data determination operation AK82 references range codes EL11, EL12 from the plurality of different measured values by performing a second scientific calculation MD81 using the measured value NY81 and the obtained pair of nominal range limit values DP1A. , ... to select the application range code EL1U of the measurement value to determine the application range code EL1U of the measurement value. For example, the second scientific calculation MD81 is performed based on a specific empirical formula XS81. The specific empirical formula XS81 is pre-established based on the preset rated range limit value pair DP1A and the plurality of different measured value reference range codes EL11 , EL12 , . . . .

In some embodiments, the processing unit 331 obtains the application range limit value pair DQ1U based on the determined application range code EL1U of the measured value, and based on the measured value NY81 and the obtained application range limit value pair DQ1U A data comparison CF81 checks the mathematical relationship KQ81 to make a logical decision PQ81 whether the measurement value NY81 is within the selected application range RQ1U of the measurement value. Under the condition that the logical decision PQ81 is positive, the processing unit 331 determines the clock time TH1A The current application interval of the clock time is HR1EU.

The specific measurement value range code EL14 is different from the determined measurement value application range code EL1U and the processing unit 331 determines that the clock time TH1A is currently in the clock time application interval HR1EU by making the logic decision PQ81 Conditionally, the processing unit 331 uses the storage unit 332 to use the storage unit 332 based on a code difference DG81 between the variable clock time interval code UF8A equal to the specific measurement value range code EL14 and the determined measurement value application range code EL1U. Assign the determined measurement value application range code EL1U to the variable clock time interval code UF8A.

The input unit 380 includes a button 3801 . The physical parameter application unit 335 has the variable physical parameter QU1A. The variable physical parameter QU1A is further characterized based on a specific physical parameter state JE16 different from the physical parameter target state JE1U. Under the condition that the processing unit 331 causes the variable physical parameter QU1A to be in the physical parameter target state JE1U by checking the first mathematical relationship KQ81, the input unit 380 receives a user input operation for selecting the button 3801 BQ82. The processing unit 331 transmits an operation signal SG87 for causing the variable physical parameter QU1A to leave the physical parameter target state JE1U to enter the specific physical parameter state JE16 to the physical parameter application unit 335 in response to the user input operation BQ82. For example, the button 3801 is a button switch, and is coupled to the processing unit 331 .

See Figure 10 and Figure 11. FIG. 10 is a schematic diagram of an implementation structure 9219 of the control system 921 shown in FIG. 1 . FIG. 11 is a schematic diagram of an implementation structure 9220 of the control system 921 shown in FIG. 1 . As shown in Figure 10 and Figure 11, the implementation structure 9219 and the implementation Each of the structures 9220 includes the functional means 130. The functional device 130 includes the processing unit 331 , the timer 342 , the storage unit 332 , the physical parameter application unit 335 and the input unit 380 . The timer 342 , the storage unit 332 , the physical parameter application unit 335 , the LED matrix 385 and the input unit 380 are all controlled by the processing unit 331 . For example, the physical parameter application unit 335 is located at one of the inside of the functional device 130 and the outside of the functional device 130 . The input unit 380 includes a plurality of push button switches 3805, 380A, . . .

In some embodiments, the input unit 380 receives the user input operation JS81 for selecting the button switch 380A. The processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to make the variable physical parameter QU1A be in the physical parameter application state JE1T. The clock time designation interval HR1ET is adjacent to the clock time application interval HR1EU, and is represented by a measurement value designation range RQ1T, and has a start time limit HR1ET1 and an end time limit HR1ET2 relative to the start time limit HR1ET1. The measured value designated range RQ1T has a designated range limit value pair DQ1T, and is represented by a measured value designated range code EL1T. For example, the measurement value designation range RQ1T is a measurement time value target range. The measured value specifying range code EL1T is a time value target range code. The specified range limit pair DQ1T is a target range limit pair.

The user input operation JS81 is used to make the processing unit 331 determine the clock time specified interval HR1ET. Under the condition that the processing unit 331 determines the specified interval HR1ET of the clock time, the processing unit 331 controls the timer 342 so that the timer 342 HR1ET1 to measure the clock time TH1A. For example, the processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to make the variable physical parameter QU1A be in the physical parameter application state JE1T within the clock time specified interval HR1ET.

In some embodiments, the physical parameter application status JE1T is represented by a physical parameter application status code EW1T. The user input operation JS81 is used to make the processing unit 331 determine one of the physical parameter application status code EW1T and the measurement value target range code EM1T. The processing unit 331 plays the role of indicating the physical parameter application status JE1T by determining the physical parameter application status code EW1T and the measured value target range code EM1T, and by determining the specified range limit value pair DQ1T to determine at least one of the clock time specified interval HR1ET and the measured value specified range RQ1T. The processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to obtain the physical parameter application state code EW1T and the specified range limit value pair DQ1T, and apply the state code based on the obtained physical parameter EW1T to make the variable physical parameter QU1A in the physical parameter application state JE1T within the specified interval HR1ET of the clock time.

The functional device 130 includes the trigger application unit 387 controlled by the processing unit 331 . After the input unit 380 receives the user input operation JS81, the trigger event JQ81 occurs. For example, the trigger event JQ81 occurs in response to one of the user input operation JS81 and the operation request signal SH81. Under the condition that the trigger event JQ81 occurs, the processing unit 331 responds to the trigger event JQ81 to perform a scientific calculation ME81 using the obtained specified range limit value pair DQ1T The application range limit value pair DQ1U is obtained, and the mathematical relationship KQ81 is checked by comparing the measured value NY81 with the obtained application range limit value pair DQ1U.

For example, the trigger event JQ81 is related to the trigger application unit 387 and is one of a trigger event, a user input event, a signal input event, a state change event and an integer overflow event. The trigger application unit 387 generates the operation request signal SJ81 in response to the trigger event JQ81, provides the operation request signal SJ81 to the processing unit 331, and thereby enables the processing unit 331 to receive the operation request signal SJ81. The processing unit 331 executes the scientific calculation ME81 in response to the operation request signal SJ81 to obtain the application range limit value pair DQ1U to check the physical parameter relationship KD9U between the variable physical parameter QU1A and the physical parameter target state JE1U.

In some embodiments, the variable physical parameter QU1A is characterized based on a plurality of different physical parameter reference states JE11, JE12, . . . The plurality of different physical parameter reference states JE11 , JE12 , . For example, the physical parameter target state JE1U is the same as or different from the physical parameter application state JE1T. The physical parameter target state JE1T is predetermined according to a physical parameter target range RD1ET. The physical parameter target state JE1U is predetermined according to a physical parameter target range RD1EU. The plurality of different physical parameter reference states JE11 , JE12 , . . . are predetermined according to the plurality of different physical parameter reference ranges RD1E1 , RD1E2 , . For example, the physical parameter target range RD1EU is a physical parameter candidate range around.

The variable physical parameter QU1A is characterized based on the plurality of different physical parameter reference ranges RD1E1, RD1E2, . . . The plurality of different physical parameter reference ranges RD1E1, RD1E2, . . . are respectively represented by the plurality of different measured value reference ranges RN11, RN12, . The physical parameter target range RD1ET and the physical parameter target range RD1EU are respectively represented by a measured value target range RN1T and a measured value target range RN1U. The plural different measured value reference ranges RN11, RN12, . . . are respectively represented by the plural different measured value reference range codes EM11, EM12, .

The plurality of different measured value reference range codes EM11, EM12, . For example, the plurality of different physical parameter reference status codes EW11, EW12, . . . include the physical parameter application status code EW1T and the physical parameter target status code EW1U, and are preset. For example, the measured value target range code EM1T and the measured value target range code EM1U are respectively the same as the physical parameter application status code EW1T and the physical parameter target status code EW1U.

In some embodiments, the clock time designation interval HR1ET and the clock time application interval HR1EU respectively have a designated time length LH8T and an applied time length LH8U equal to the designated time length LH8T. The designated time length LH8T and the application time length LH8U They are respectively represented by a measurement time length value VH8T and a measurement time length value VH8U. For example, the measurement time length value VH8U is the same as the measurement time length value VH8T. Both the measurement duration value VH8T and the measurement duration value VH8U are preset based on the timer specification FT21 using the designated measurement value format HH95.

The clock time application interval HR1EU has a relative interval position LE81 relative to the clock time designated interval HR1ET. The relative interval position LE81 is represented by a relative value VL81. For example, the relative value VL81 is equal to 1 under the condition that the clock time application interval HR1EU is adjacent to the clock time designation interval HR1ET. The processing unit 331 obtains the relative value VL81 in response to the operation request signal SJ81. The scientific calculation ME81 performs a subtraction operation ZF81 on the obtained specified range limit value to DQ1T to obtain the measured time length value VH8U, and uses the obtained relative value VL81, the obtained measured time length value VH8U and the obtained The specified range limit value pair DQ1T is obtained to obtain the application range limit value pair DQ1U.

For example, the storage unit 332 stores the physical parameter application state code EW1T stored based on the preset measurement value specifying range code EL1T. The processing unit 331 obtains the measured value specified range code EL1T by performing a scientific calculation MH81 using the obtained specified range limit value pair DQ1T, and based on the obtained measured value specified range code EL1T, retrieves the specified range code EL1T from the storage unit. 332 Obtain the application state code EW1T of the stored physical parameter.

See Figure 12, Figure 13, Figure 14 and Figure 15. FIG. 12 is an illustration of an implementation structure 9221 of the control system 921 shown in FIG. 1 intention. FIG. 13 is a schematic diagram of an implementation structure 9222 of the control system 921 shown in FIG. 1 . FIG. 14 is a schematic diagram of an implementation structure 9223 of the control system 921 shown in FIG. 1 . FIG. 15 is a schematic diagram of an implementation structure 9224 of the control system 921 shown in FIG. 1 . As shown in FIG. 12 , FIG. 13 , FIG. 14 and FIG. 15 , each structure of the implementation structure 9221 , the implementation structure 9222 , the implementation structure 9223 and the implementation structure 9224 includes the functional device 130 . The functional device 130 includes the processing unit 331 , the timer 342 , the physical parameter application unit 335 and the storage unit 332 . The timer 342 , the physical parameter application unit 335 and the storage unit 332 are all controlled by the processing unit 331 .

In some embodiments, the timer 342 is controlled by the processing unit 331 and used to measure the clock time TH1A. The timer 342 is configured to comply with the timer specification FT21. The variable physical parameter QU1A is related to the clock time TH1A. The clock time TH1A is characterized based on a plurality of different clock time reference intervals HR1E1 , HR1E2 , . . . . The plurality of different clock time reference intervals HR1E1, HR1E2, . . . are respectively represented by the plurality of different measured value reference ranges RQ11, RQ12, . The plurality of different measured value reference ranges RQ11, RQ12, . . . are arranged based on the preset time reference interval sequence QB81. For example, the complex different measurement value reference ranges RQ11, RQ12, . . . are complex time value reference ranges.

The plurality of different measured value reference ranges RQ11, RQ12, . For example, the specified measurement value format is HH95 is a specified count value format. The complex different measured value reference range codes EL11, EL12, . . . are respectively complex measured time value reference range codes. The storage unit 332 has a plurality of different memory locations YS81, YS82, . For example, the complex physical parameter specified range codes UQ11, UQ12, ... are respectively equal to the complex physical parameter specified status codes. The specified state codes of the complex physical parameters respectively represent the specified states of the complex physical parameters related to the variable physical parameter QU1A. For example, the complex physical parameter specified range codes UQ11, UQ12, . . . are configured to form a physical parameter specified range code array.

The plural different clock time reference intervals HR1E1, HR1E2, . . . are respectively represented by plural clock time reference interval codes. For example, the complex clock time reference interval codes are configured to be equal to the complex different measurement value reference range codes EL11, EL12, . . . respectively. Therefore, the plurality of different measured value reference range codes EL11 , EL12 , . . . are configured to respectively indicate the plurality of different clock time reference intervals HR1E1 , HR1E2 , . . . For example, the specified measurement value format HH95 is characterized based on the specified bit number UY95.

The plurality of different measured value reference range codes EL11, EL12, . . . include a measured value specified range code EL1T and a measured value applied range code EL1U. The plurality of different clock time reference intervals HR1E1, HR1E2, . . . include a clock time designation interval HR1ET and a clock time application interval HR1EU. The measurement value designation range code EL1T and the measurement value application range code EL1U are configured to respectively indicate the clock time designation interval HR1ET and the clock time application interval HR1EU. The complex number differs in measured values The reference ranges RQ11 , RQ12 , . . . include a measured value designation range RQ1T and a measured value application range RQ1U. The clock time designation interval HR1ET and the clock time application interval HR1EU are respectively represented by the measurement value designation range RQ1T and the measurement value application range RQ1U.

In some embodiments, the plurality of different memory locations YS81, YS82, . . . are identified based on the plurality of different measurement value reference range codes EL11, EL12, . . . respectively. For example, the plurality of different memory locations YS81, YS82, . . . are identified based on or identified by the plurality of memory addresses AS81, AS82, . The plurality of memory addresses AS81, AS82, . . . are preset based on the plurality of different measured value reference range codes EL11, EL12, .

For example, the clock time TH1A is further characterized based on a nominal clock time interval HR1E. The rated clock time interval HR1E includes the plurality of different clock time reference intervals HR1E1, HR1E2, . . . and is represented by a rated measurement value range HR1N. The rated measured value range HR1N includes the plurality of different measured value reference ranges RQ11, RQ12, . For example, this nominal clock time interval HR1E is equal to 24 hours. The setpoint measured value range HR1N is a setpoint time value range.

For example, the measurement application function specification GAL8 includes a rated clock time interval representation GA8HE and a clock time reference interval representation GA8HR. The nominal clock time interval representation GA8HE is used to represent the nominal clock time interval HR1E. The clock time reference interval representation GA8HR is used to represent the plurality of different clock time reference intervals HR1E1, HR1E2, . . . The rated measured value range HR1N is equal to at least a second part of the full measured value range QK8E, and is specified based on one of the timer specification FT21, the measurement application function specification GAL8 and the first data encoding rule WX8HE The measured value format is HH95 and is preset. The first data encoding rule WX8HE is used to convert the rated clock time interval representation GA8HE, and is formulated based on the timer specification FT21. For example, the nominal measurement value range HR1N is preset by performing a data encoding operation ZX8HE using the first data encoding rule WX8HE.

The plurality of different measured value reference ranges RQ11, RQ12, . The data encoding rule WX8HR is used to convert the clock time reference interval representation GA8HR, and is formulated based on the timer specification FT21. For example, the plurality of different measured value reference ranges RQ11, RQ12, . . . are preset by performing a data encoding operation ZX8HR using the data encoding rule WX8HR.

In some embodiments, the complex physical parameter designated range codes UQ11, UQ12, ... are configured to be stored based on the plurality of different measured value reference range codes EL11, EL12, ... respectively, and include a physical parameter target range code UQ1T and A physical parameter target range code UQ1U. The specified range codes UQ11, UQ12, . . . of the plurality of physical parameters are all selected from the reference status codes EW11, EW12, . For example, the physical parameter target range code UQ1U is a physical parameter candidate range code.

The physical parameter target range code UQ1T represents that the variable physical parameter QU1A is expected to be within the clock time specified interval HR1ET A physical parameter target range RD1ET is configured to be stored in a memory location YS8T based on the measured value specified range code EL1T. The memory location YS8T is identified based on a memory address AS8T. The plurality of different measurement value reference range codes EL11, EL12, . . . are all preset based on the measurement application function specification GAL8. For example, the physical parameter target range code UQ1T is equal to the preset physical parameter application state code EW1T. The physical parameter target range code UQ1U is the same as the physical parameter application status code EW1U.

The physical parameter target range code UQ1U represents a physical parameter target range RD1EU in which the variable physical parameter QU1A is expected to be within the clock time application interval HR1EU, and is configured to be stored in a Memory location YS8U. The memory location YS8U is identified based on a memory address AS8U. Both the physical parameter target range RD1ET and the physical parameter target range RD1EU are selected from the plurality of different physical parameter reference ranges RD1E1, RD1E2, . . . For example, the clock time application interval HR1EU is adjacent to the clock time designation interval HR1ET. The physical parameter target range code UQ1U is the same as the physical parameter target status code EW1U. The physical parameter target range RD1EU has a predetermined physical parameter target range limit ZD1U1 and a predetermined physical parameter target range limit ZD1U2 relative to the predetermined physical parameter target range limit ZD1U1 .

In some embodiments, when the input unit 380 receives the user input operation JS81, the physical parameter target range code UQ1T is equal to the preset physical parameter application status code EW1T. The processing unit 331 responds to the user input operation JS81 and the operation request signal SH81. One of them is used to determine the specific range code EB1T. The specific range code EB1T indicates the specified interval HR1ET of the clock time, and is equal to the preset measured value specified range code EL1T. Under the condition that the processing unit 331 determines the specific range code EB1T equal to the measured value designated range code EL1T, the processing unit 331 obtains the specific range code EB1T (equal to the measured value designated range code EL1T) based on the determined specific range code EB1T memory address AS8T, and access the physical parameter target range code UQ1T stored in the memory location YS8T based on the obtained memory address AS8T to obtain the physical parameter target range code UQ1T and the preset physical parameter The parameter applies to one of the status codes EW1T. For example, there is a preset time interval between the clock time designation interval HR1ET and the clock time application interval HR1EU.

For example, under the condition that the physical parameter target range code UQ1T is equal to the preset physical parameter application state code EW1T, the user input operation JS81 is used to determine the specific range code EL1T equal to the preset measured value specified range code. Range code EB1T; therefore, the specific range code EB1T that is equal to the preset measurement value designation range code EL1T indirectly serves to indicate the physical parameter application state JE1T. When the input unit 380 receives the user input operation JS81, the variable physical parameter QU1A is in a physical parameter application state JE1L. The processing unit 331 executes a physical parameter relationship check control GX8T for checking a physical parameter relationship KD9T between the variable physical parameter QU1A and the physical parameter application status JE1T based on the obtained physical parameter application status code EW1T.

For example, the user input operation JS81 is used to determine the specific range code EB1T equal to the preset measurement value specified range code EL1T; The specific range code EB1T plays the role of indicating at least one of the specified range HR1ET of the clock time and the specified range RQ1T of the measured value, and indicates the application of the physical parameter by playing the role of indicating the specified range HR1ET of the clock time The role of state JE1T.

In some embodiments, the physical parameter application state JE1L is different from the physical parameter application state JE1T and the processing unit 331 determines the physical parameter application state JE1T and the physical parameter application state by executing the physical parameter relationship check control GX8T Under the condition of a physical parameter state difference DT8T between JE1L, the processing unit 331 executes a signal generation control GY81 based on the obtained physical parameter application status code EW1T to generate an operation signal SG81, and sends the physical parameter application unit 335 transmits the operation signal SG81. The physical parameter application unit 335 responds to the operation signal SG81 to make the variable physical parameter QU1A enter the physical parameter application state JE1T from the physical parameter application state JE1L. For example, the variable physical parameter QU1A enters the physical parameter application state JE1T by entering the physical parameter target range RD1ET.

The processing unit 331 executes a data storage control operation GM8T based on the obtained measurement value designated range code EL1T, and the data storage control operation GM8T is used to cause a clock time application interval code UF8T representing the clock time designated interval HR1ET to be stored. . For example, the clock time application interval code UF8T is the same as the measurement value obtained specifying the range code EL1T. The data storage control operation GM8T assigns the clock time application interval code UF8T to the variable clock time interval code UF8A by using the storage unit 332 .

For example, the storage unit 332 stores a variable physical parameter Range code UN8A. Under the condition that the physical parameter application state JE1L is different from the physical parameter application state JE1T and the processing unit 331 determines the physical parameter state difference DT8T by executing the physical parameter relationship check control GX8T, the processing unit 331 determines the physical parameter state difference DT8T by using the The storage unit 332 assigns one of the obtained physical parameter target range code UQ1T and the obtained physical parameter application status code EW1T to the variable physical parameter range code UN8A.

In some embodiments, the timer 342 is configured to represent the clock time specified interval HR1ET by using the measured value specified range RQ1T, and is configured to represent the clock time application by using the measured value applied range RQ1U Interval HR1EU. The input unit 380 receives the user input operation JS81 at a specific time. The specific time is adjacent to the clock time designation interval HR1ET. For example, the specific time is a current time. The processing unit 331 determines the measured time length value VH8T representing the specified time length LH8T and a clock reference time value NR81 representing a clock reference time TR81 in response to one of the user input operation JS81 and the operation request signal SH81 . For example, the clock reference time TR81 is close to the current time. For example, a time difference between the clock reference time TR81 and the current time is within a preset time length. The clock reference time value NR81 is preset in the designated measurement value format HH95 based on the clock reference time TR81 and the timer specification FT21.

The specified range of measured values RQ1T has the specified range limit value pair DQ1T. The specified range limit value pair DQ1T includes a specified range limit value DQ13 and a specified range limit value DQ14 corresponding to the specified range limit value DQ13. For example, the specified range limit value DQ13 and the The fixed range limit values DQ14 are respectively a start range limit value and an end range limit value. The specified range limit value DQ13 is equal to the clock reference time value NR81.

The processing unit 331 determines a control data CG81 in response to one of the user input operation JS81 and the operation request signal SH81. The control data CG81 includes the measured value specifying range code EL1T, the clock reference time value NR81 and the measured time length value VH8T. For example, the measurement application functional specification GAL8 includes a clock time representation GA8TR. The clock time representation GA8TR is used to represent the clock reference time TR81. The clock reference time value NR81 is preset in the designated measurement value format HH95 based on the clock time representation GA8TR, the timer specification FT21 and a data encoding operation ZX8TR for converting the clock time representation GA8TR.

In some embodiments, the processing unit 331 causes the timer 342 to start within a start time TT82 based on the determined clock reference time value NR81, thereby causing the timer 342 to start within the start time TT82 A sensing signal SY80 is generated by sensing the clock time TH1A. For example, the sensing signal SY80 is a clock time signal. The sensing signal SY80 is an initial time signal, and delivers a measured value NY80 in the designated measured value format HH95. For example, the measured value NY80 is an initial count value. For example, the measured value NY80 is equal to the clock reference time value NR81.

For example, the timer 342 is configured to have a variable count value NY8A. Under the condition that the input unit 380 receives the user input operation JS81, the processing unit 331 based on the determined clock reference time The timer 342 is started with a value NR81 to perform a count operation BD81 for the measurement application function FA81 to change the variable count value NY8A. The variable count value NY8A is configured to be equal to the measured value NY80 within the start time TT82 and is provided in the specified measured value format HH95. For example, the measured value NY80 is configured to be identical to the obtained clock reference time value NR81.

Under the condition that the variable physical parameter QU1A is configured to be within the physical parameter target range RD1ET due to the user input operation JS81 , the processing unit 331 reaches an operating time TY81 based on the counting operation BD81 . Within the operation time TY81, the timer 342 senses the clock time TH1A to cause the variable count value NY8A to be equal to a measured value NY81, thereby generating a sensing signal SY81 delivering the measured value NY81. For example, the operation time TY81 is a specified time.

For example, the trigger application unit 387 generates the operation request signal SJ81 in response to the trigger event JQ81, provides the operation request signal SJ81 to the processing unit 331, and thereby enables the processing unit 331 to receive the operation request signal SJ81. The processing unit 331 responds to the operation request signal SJ81 to obtain the measurement value NY81 from the sensing signal SY81 in the specified measurement value format HH95 within the operation time TY81, and within the operation time TY81 by executing the The obtained measured value specifies a scientific calculation MH85 of the range code EL1T to obtain or determine the measured value using the range code EL1U to check the physical parameter relationship KD9U between the variable physical parameter QU1A and the physical parameter target state JE1U.

In some embodiments, the specified range of measurements RQ1T has the specified range limit pair DQ1T. The specified range bounds pair DQ1T includes the specified range limit value DQ13 and the specified range limit value DQ14 relative to the specified range limit value DQ13. Both the specified measurement value range RQ1T and the specified range limit value pair DQ1T are preset in the specified measurement value format HH95 based on the clock time specified interval HR1ET and the timer specification FT21. The measured value application range RQ1U has the application range limit value pair DQ1U. The application range limit value pair DQ1U includes the first application range limit value DQ15 and the second application range limit value DQ16 corresponding to the first application range limit value DQ15 . Both the measurement value application range RQ1U and the application range limit value pair DQ1U are preset in the specified measurement value format HH95 based on the clock time application interval HR1EU and the timer specification FT21.

For example, the measurement application function specification GAL8 includes a clock time designation interval representation GA8HT and a clock time application interval representation GA8HU. The clock time designation interval indication GA8HT is used to indicate the clock time designation interval HR1ET. The clock time application interval representation GA8HU is used to represent the clock time application interval HR1EU. The measurement value specified range RQ1T and the specified range limit value pair DQ1T are based on the clock time specified interval representation GA8HT, the timer specification FT21 and a data encoding operation ZX8HT for converting the clock time specified interval representation GA8HT to use the specified The measured value format is HH95 and is preset. The measurement value application range RQ1U and the application range limit value pair DQ1U are based on the clock time application interval representation GA8HU, the timer specification FT21 and a data encoding operation ZX8HU for converting the clock time application interval representation GA8HU to use the specified The measured value format is HH95 and is preset.

In some embodiments, the processing unit 331 due to the The user inputs operation JS81 to determine the measured value application range code EL1U within the operation time TY81 to check the physical parameter relationship KD9U between the variable physical parameter QU1A and the physical parameter target state JE1U. For example, the processing unit 331 responds to the operation request signal SJ81 to determine the measurement value application range code EL1U within the operation time TY81 based on the determined control data CG81 . The processing unit 331 determines the relative value VL81 within the operation time TY81, and by performing a process using the determined relative value VL81, the obtained measurement time length value VH8T and the obtained clock reference time value NR81 A scientific calculation of ME85 to obtain the application range limit value pair DQ1U.

For example, the processing unit 331 determines the relative value VL81 within the operation time TY81 in response to the operation request signal SJ81, and determines the relative value VL81 based on the determined relative value VL81 and the obtained measured value specified range code EL1T. Measured values apply range code EL1U. The processing unit 331 checks the mathematical relationship KQ81 based on the obtained measured value NY81 and the obtained data comparison CF81 between the application range limit value pair DQ1U to make whether the measured value NY81 is for the selected This logic determines PQ81 within the measured value application range RQ1U. On the condition that the logic decision PQ81 is positive, the processing unit 331 determines the clock time application interval HR1EU where the clock time TH1A is currently located.

When the obtained measured value designation range code EL1T is different from the determined measured value application range code EL1U and the processing unit 331 determines the clock time application where the clock time TH1A is currently in by making the logic decision PQ81 Under the condition of interval HR1EU, the processing unit 331 is based on the variable clock time equal to the specified range code EL1T of the measured value A code difference DG83 between the range code UF8A and the determined measurement value application range code EL1U is used to perform the data storage control operation GM8U. The data storage control operation GM8U uses the storage unit 332 to assign the determined measurement value application range code EL1U to the variable clock time interval code UF8A.

In some embodiments, when the trigger event JQ81 occurs, the physical parameter target range code UQ1U is equal to the preset physical parameter target state code EW1U. Under the condition that the trigger event JQ81 occurs, the processing unit 331 determines the measurement value application range code EL1U based on the determined control data CG81 in response to the operation request signal SJ81 . Under the condition that the processing unit 331 determines that the clock time TH1A is currently in the clock time application interval HR1EU by making the logical decision PQ81, the processing unit 331 applies the range code EL1U based on the determined measured value to obtain The memory address AS8U, and access the physical parameter target range code UQ1U stored in the memory location YS8U based on the obtained memory address AS8U to obtain the physical parameter target range code UQ1U and the preset physical parameter target range code UQ1U One of the physical parameter target status codes EW1U.

For example, when the processing unit 331 checks the mathematical relationship KQ81, the variable physical parameter QU1A is in the physical parameter application state JE1T. The processing unit 331 executes the physical parameter relationship check control GX8U for checking the physical parameter relationship KD9U between the variable physical parameter QU1A and the physical parameter target state JE1U based on the obtained physical parameter target state code EW1U. When the physical parameter application state JE1T is different from the physical parameter target state JE1U and the processing unit 331 executes Under the condition that the physical parameter relationship checking control GX8U determines the physical parameter state difference DT81 between the physical parameter target state JE1U and the physical parameter application state JE1T, the processing unit 331 based on the obtained physical parameter target state code EW1U To execute the signal generation control GY85 to generate the operation signal SG85 , and transmit the operation signal SG85 to the physical parameter application unit 335 .

The physical parameter application unit 335 responds to the operation signal SG85 to make the variable physical parameter QU1A enter the physical parameter target state JE1U from the physical parameter application state JE1T. For example, the variable physical parameter QU1A enters the physical parameter target state JE1U by entering the physical parameter target range RD1EU. For example, under the condition that the physical parameter application state JE1T is different from the physical parameter target state JE1U and the processing unit 331 determines the physical parameter state difference DT81 by executing the physical parameter relationship checking control GX8U, the processing unit 331 determines the physical parameter state difference DT81 by using The storage unit 332 assigns one of the obtained physical parameter target range code UQ1U and the obtained physical parameter target state code EW1U to the variable physical parameter range code UN8A.

In some embodiments, the functional device 130 further includes a display unit 382 coupled to the processing unit 331 . The display unit 382 includes the LED matrix 385 and is controlled by the processing unit 331 . The complex physical parameter specified range codes UQ11, UQ12, ... belong to a physical parameter specified range code type TS81. The physical parameter specified range code type TS81 is identified by a physical parameter specified range code type identifier HS81. The physical parameter specifies that the range code type identifier HS81 is preset. The memory address AS8T specifies the range code type based on the preset physical parameter The identifier HS81 and the preset measured value specify the range code EL1T and are preset. The memory address AS8U is preset based on the preset physical parameter designation range code type identifier HS81 and the preset measurement value application range code EL1U.

The LED matrix 385 includes the LEDs 3852 associated with the target time interval HV1U. For example, the input unit 380 receives the user input operation JS81 under the condition that the processing unit 331 causes the light emitting diode 3852 to display a state indication LL81. The state indicator LL81 is used to indicate that the variable physical parameter QU1A is expected to be in a specific state XE81 of the physical parameter target state JG1C within the target time interval HV1U. For example, the status indication LL82 is different from the status indication LL81.

Before the input unit 380 receives the user input operation JS81, the functional device 130 is configured in a setting stage UC81. The processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to make the functional device 130 leave the setting stage UC81 to enter a certain timing stage UD81. For example, the processing unit 331 makes the functional device 130 leave the setting stage UC81 to enter the timing stage UD81 by means of the push button switch 380A.

In some embodiments, before the input unit 380 receives the user input operation JS81, the processing unit 331 obtains the preset physical parameter by using at least one of the input unit 380 and the display unit 382 The target range code UQ1T, the preset physical parameter specified range code type identifier HS81 and the preset measured value specified range code EL1T, and the specified range code type based on the obtained physical parameter in advance The identifier HS81 and the measured value obtained specify the range code EL1T to obtain the memory address AS8T. The processing unit 331 uses the storage unit 332 to store the obtained physical parameter at the memory location YS8T based on the obtained physical parameter target range code UQ1T and the obtained memory address AS8T in the setting phase UC81 Target range code UQ1T.

Before the input unit 380 receives the user input operation JS81, the processing unit 331 obtains the physical parameter target range code UQ1U and the preset physical parameter target range code UQ1U by using at least one of the input unit 380 and the display unit 382. The measured value applies the range code EL1U, and the memory address AS8U is obtained in advance based on the obtained physical parameter designation range code type identifier HS81 and the obtained measured value applied range code EL1U. The processing unit 331 uses the storage unit 332 to store the obtained physical parameter at the memory location YS8U based on the obtained physical parameter target range code UQ1U and the obtained memory address AS8U in the setting stage UC81 Target range code UQ1U.

See Figure 16, Figure 17, Figure 18 and Figure 19. FIG. 16 is a schematic diagram of an implementation structure 9225 of the control system 921 shown in FIG. 1 . FIG. 17 is a schematic diagram of an implementation structure 9226 of the control system 921 shown in FIG. 1 . FIG. 18 is a schematic diagram of an implementation structure 9227 of the control system 921 shown in FIG. 1 . FIG. 19 is a schematic diagram of an implementation structure 9228 of the control system 921 shown in FIG. 1 . As shown in FIG. 16 , FIG. 17 , FIG. 18 and FIG. 19 , each structure of the implementation structure 9225 , the implementation structure 9226 , the implementation structure 9227 and the implementation structure 9228 includes the functional device 130 . The functional device 130 includes the processing unit 331, the timer 342, the storage unit 332, the input unit 380, the display unit 382 and the physical parameter application unit 335 .

In some embodiments, the display unit 382 includes the LED matrix 385 . For example, the LED matrix 385 is a two-dimensional LED matrix and includes a base 385A, the LED 3852 and an LED 3851 adjacent to the LED 3852 . The LED 3852 is associated with the target time interval HV1U. The LED 3851 is associated with a target time interval HV1T adjacent to the target time interval HV1U. For example, the target time interval HV1T is or is the same as the clock time specified interval HR1ET. Both the LED 3851 and the LED 3852 are coupled to the base 385A, and both are supported by the base 385A. The variable application time TC1A is characterized based on the target time interval HV1T. For example, the target time interval HV1T applies a status code EW1T in relation to the stored physical parameter.

Under the condition that the variable physical parameter state code EG1A is equal to the physical parameter target state code EG1C and the processing unit 331 determines that the clock time TH1A is currently in the clock time application interval HR1EU due to checking the mathematical relationship KQ81, the processing The unit 331 accesses the stored physical parameter target state code EG1C related to the target time interval HV1U, selects the light-emitting diode 3852 related to the target time interval HV1U, and based on the stored target state code within the target time interval HV1U The physical parameter target state code EG1C is obtained to make the selected light emitting diode 3852 display the state indication LL82. The state indicator LL82 is used to indicate that the variable physical parameter QU1A is configured to be in the specific state XE82 of the physical parameter target state JG1C within the target time interval HV1U.

The processing unit 331 is within the target time interval HV1T Access the stored physical parameters related to the target time interval HV1T and use the status code EW1T, select the light-emitting diode 3851 related to the target time interval HV1T within the target time interval HV1T, and The status code EW1T is applied in the HV1T based on the accessed physical parameter to make the selected LED 3851 display a status indication LL72. The state indicator LL72 is used to indicate that the variable physical parameter QU1A is configured to be in a specific state XE72 of the physical parameter application state JE1T within the target time interval HV1T. For example, the processing unit 331 transmits the operation signal SG81 to the physical parameter application unit 335 based on the accessed physical parameter application status code EW1T within the target time interval HV1T. The operation signal SG81 is used to cause the physical parameter application unit 335 to make the variable physical parameter QU1A in the physical parameter application state JE1T.

In some embodiments, the variable physical parameter QU1A is a variable electrical parameter, a variable mechanical parameter, a variable optical parameter, a variable temperature, a variable humidity, a variable voltage, a variable Current, a variable electric power, a variable resistance, a variable capacitance, a variable inductance, a variable frequency, a clock time, a variable time length, a variable brightness, a variable luminous intensity, A variable volume, a variable data flow rate, a variable amplitude, a variable spatial position, a variable displacement, a variable sequence position, a variable angle, a variable spatial length, a variable distance, a One of variable translation velocity, a variable angular velocity, a variable acceleration, a variable force, a variable pressure, and a variable mechanical power.

The processing unit 331 is configured to execute the measurement application function FA81 related to the variable physical parameter QU1A. The functional device 130 is one of a plurality of application devices. The measurement application function FA81 is complex One of the specific control functions, the plurality of specific control functions include a time control function, a light control function, a force control function, an electric control function, a magnetic control function and any combination thereof. The plurality of application devices include a control target device, a relay, a control switch device, a motor, a lighting device, a door, a vending machine, an energy converter, an electric load device, a timing device, a toy, and an electrical appliance , a printing device, a display device, a mobile device, a speaker and any combination thereof. For example, the appliance is a household appliance.

The physical parameter application unit 335 is one of a plurality of application objects and is configured to execute a specific application function. The specific application function is one of the complex physical parameter application functions, and the complex physical parameter application function includes a light use function, a force use function, an electricity use function, a magnetic use function and any combination thereof. The plurality of application objects includes an electronic component, an actuator, a resistor, a capacitor, an inductor, a relay, a control switch, a transistor, a motor, a lighting unit, an energy conversion unit, and an electric load unit, a timing unit, a printing unit, a display object, a loudspeaker and any combination thereof. For example, the physical parameter application unit 335 is a physically realizable functional unit.

In some embodiments, the physical parameter application unit 335 has a physical parameter formation area AU11. The physical parameter forming area AU11 has the variable physical parameter QU1A. For example, the physical parameter formation area AU11 is one of an electric load area, a display area, a sensing area, a touch area, a power supply area and an environment area. For example, the physical parameter type TU11 is different from a time type.

For example, the physical parameter application unit 335 includes an input part 3357 and an output part 3358 coupled to the input part 3357. The input part 3357 is used to control the output part 3358 , coupled to the processing unit 331 and controlled by the processing unit 331 . The output section 3358 has the physical parameter forming area AU11. The physical parameter forming area AU11 has the variable physical parameter QU1A. For example, the input part 3357 is coupled to the processing unit 331 and the output part 3358 , and receives at least one of the operation signal SG81 and the operation signal SG85 from the processing unit 331 . For example, the variable physical parameter state JG1A is one of a variable switch state and a variable function state.

For example, the input part 3357 receives the operation signal SG81 from the processing unit 331, and executes a first functional operation in response to the operation signal SG81. The first function operates to control the output portion 3358 and to cause the output portion 3358 to place the variable physical parameter QU1A in the physical parameter application state JE1T. The input part 3357 receives the operation signal SG85 from the processing unit 331, and executes a second functional operation in response to the operation signal SG85. The second function operates to control the output portion 3358 and to cause the output portion 3358 to make the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

For example, under the condition that the physical parameter application unit 335 is a relay, the output part 3358 includes a control switch. The control switch is coupled to the input part 3357, controlled by the input part 3357, and has the physical parameter forming area AU11. The control switch forms the variable physical parameter state JG1A provided based on the variable physical parameter QU1A in the physical parameter forming area AU11.

In some embodiments, the variable application time TC1A base Characterized in a plurality of different reference time intervals HV11, HV12, . . . Under the condition that the variable application time TC1A is equal to the clock time TH1A, the plurality of different reference time intervals HV11 , HV12 , . . . are respectively equal to the plurality of different clock time reference intervals HR1E1 , HR1E2 , . . . The variable physical parameter QU1A is characterized in the plurality of different reference time intervals HV11, HV12, . . . based on a plurality of variable physical parameter states JG11, JG12, . . . respectively. The plural variable physical parameter states JG11 , JG12 , .

For example, the complex variable physical parameter state codes EG11, EG12, ... are respectively the same as the complex physical parameter specified range codes UQ11, UQ12, ..., including the variable physical parameter state code EG1A, and are determined according to a preset state code sequence are arranged. For example, the plural variable physical parameter states JG11 , JG12 , .

The storage unit 332 stores a variable physical parameter state code array EGAA. The variable physical parameter status code array EGAA includes the complex variable physical parameter status codes EG11, EG12, . . . and is a two-dimensional variable physical parameter status code array. The LED matrix 385 is associated with the stored variable physical parameter state code array EGAA. The processing unit 331 enables the LED matrix 385 to perform a display operation ZJ82 based on the stored variable physical parameter state code array EGAA. For example, the display operation ZJ82 includes displaying the status indication LL82 by means of the LED 3852 .

In some embodiments, the variable physical parameter QU1A is characterized based on a physical parameter target state JG1P represented by a physical parameter target state code EG1P. The input unit 380 receives a user input operation BB8H in the setting stage UC81 . The processing unit 331 transmits an operation signal SG67 to the physical parameter application unit 335 in real time in response to the user input operation BB8H. The operation signal SG67 is used to cause the physical parameter application unit 335 to make the variable physical parameter QU1A be in the physical parameter target state JG1P. For example, the processing unit 331 obtains the physical parameter target state code EG1P in response to the user input operation BB8H, and generates the operation signal SG67 in real time based on the obtained physical parameter target state code EG1P.

For example, the input part 3357 of the physical parameter application unit 335 receives the operation signal SG67 from the processing unit 331 . The input part 3357 receives the operation signal SG67 from the processing unit 331, and executes a third functional operation in response to the operation signal SG67. The third function operates to control the output portion 3358 and to cause the output portion 3358 to cause the variable physical parameter QU1A to be in the physical parameter target state JG1P instantaneously.

For example, the input unit 380 includes a button switch 3807, and responds to the user input operation BB8H to make the processing unit 331 receive an operation request signal SA87. The button switch 3807 receives the user input operation BB8H for selecting the button switch 3807 in the setting stage UC81, and the processing unit 331 receives the operation request signal SA87 in response to the user input operation BB8H. The processing unit 331 responds to the operation request signal SA87 to obtain the physical parameter target state code EG1P. For example, the processing unit 331 relies on the button switch 3807 to obtain The physical parameter target status code EG1P.

The input unit 380 includes the button switch 3805 . Under the condition that the functional device 130 is configured in the setting stage UC81 and the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the button switch 3805 receives the user’s request for selecting the button switch 3805 Input the operation BB8C, and make the processing unit 331 receive the operation request signal SA81 in response to the user input operation BB8C. The processing unit 331 responds to the operation request signal SA81 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter target status code EG1C. For example, the button switch 3805 is coupled to the processing unit 331 . The triggering event JQ81 occurs during the timing phase UD81.

For example, the input unit 380 receives the user input operation BB8C within an operation time TF61. Under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the processing unit 331 accesses the stored physical parameter application status within a target time interval HY1U earlier than the operation time TF61 Code EG1B, and apply state code EG1B based on the accessed physical parameter to make the variable physical parameter state JG1A equal to the physical parameter target state JG1B. For example, the variable application time TC1A is characterized based on the target time interval HY1U. The target time interval HV1U is the same as the target time interval HY1U and later than the target time interval HY1U.

In some embodiments, the input unit 380 receives a user input operation JS82 occurring before the user input operation BB8C, and responds to the user input operation JS82 to make the processing unit 331 receive an operation request signal SH82. The processing unit 331 responds to the operation request A signal SH82 is requested to cause the functional device 130 to enter the setting stage UC81. The input unit 380 further includes a button switch 380B coupled to the processing unit 331 . The button switch 380B receives the user input operation JS82 for selecting the button switch 380B, and responds to the user input operation JS82 to make the processing unit 331 receive the operation request signal SH82. For example, the processing unit 331 makes the functional device 130 enter the setting stage UC81 by means of the button switch 380B.

For example, the trigger application unit 387 is controlled by the processing unit 331 to cause the trigger event JQ81 to occur. If the trigger event JQ81 is the integer overflow event, the trigger application unit 387 is controlled by the processing unit 331 to cause the integer overflow event to occur. The functional device 130 further includes a timer 343 coupled to the processing unit 331 . The timer 343 is controlled by the processing unit 331 . Under the condition that the trigger event JQ81 is the integer overflow event, it is the timer 343 of the trigger application unit 387 that responds to a time control GD81 related to the processing unit 331 to cause the integer overflow event to occur. For example, the processing unit 331 responds to the control signal SC81 to execute the time control GD81 for controlling the timer 343 . The timer 343 responds to the time control GD81 to form the integer overflow event.

For example, the trigger application unit 387 is one of the input unit 380 , the display unit 382 and the timer 343 . Under the condition that the trigger event JQ81 is the user input event, it is the input unit 380 of the trigger application unit 387 that receives a user input operation JS83 to cause the user input event to occur. For example, under the condition that the functional device 130 is configured in the timing stage UD81, the input unit 380 receives A user inputs operation JS86, and the processing unit 331 receives an operation request signal SH86 in response to the user input operation JS86.

The processing unit 331 responds to the operation request signal SH86 to make the functional device 130 leave the timing stage UD81 to enter a setting stage UC82. For example, the button switch 380B receives the user input operation JS86 for selecting the button switch 380B, and the processing unit 331 receives the operation request signal SH86 in response to the user input operation JS86.

See Figure 20. FIG. 20 is a schematic diagram of an implementation structure 9229 of the control system 921 shown in FIG. 1 . As shown in FIG. 20 , the implementation structure 9229 includes the functional device 130 . In some embodiments, the variable physical parameter QU1A is characterized based on a physical parameter target state JE1U. For example, the physical parameter target state JG1C is or is the same as the physical parameter target state JE1U. The functional device 130 further includes a timer 346 coupled to the processing unit 331 .

The timer 346 senses a variable remaining time TA1A to generate a sensing signal ST81. For example, the variable remaining time TA1A is characterized based on a remaining time application interval HJ1EU represented by a measurement value application range RJ1U. For example, the target time interval HV1U is or is the same as the remaining time application interval HJ1EU. The processing unit 331 obtains a measurement value NJ81 in response to the sensing signal ST81, and determines the variable remaining value by checking a mathematical relationship KB81 between the measurement value NJ81 and the measurement value application range RJ1U in the processing unit 331. The variable physical parameter QU1A is in the physical parameter target state JE1U under the condition of the remaining time application interval HJ1EU where the time TA1A is currently located. For example, the sensing signal ST81 is a digital signal.

See Figure 21 and Figure 22. FIG. 21 is a schematic diagram of an implementation structure 9230 of the control system 921 shown in FIG. 1 . FIG. 22 is a schematic diagram of an implementation structure 9231 of the control system 921 shown in FIG. 1 . As shown in FIG. 21 and FIG. 22 , each structure of the implementation structure 9230 and the implementation structure 9231 includes the functional device 130 . In some embodiments, the functional device 130 further includes a physical parameter application unit 335 coupled to the processing unit 331 . For example, the functional device 130 is a control target device. The physical parameter application unit 335 is a functional object. The input unit 380 further includes a button switch 380A coupled to the processing unit 331 . For example, the timer 346 may be the same as or different from the timer 342 . The variable physical parameter QU1A is related to the variable remaining time TA1A.

In some embodiments, the variable remaining time TA1A is further characterized based on a remaining time specifying interval HJ1ET different from the remaining time applying interval HJ1EU. For example, the remaining time designation section HJ1ET is earlier than the remaining time application section HJ1EU. Before the variable remaining time TA1A enters the remaining time application interval HJ1EU, the input unit 380 receives a user input operation JS81, and makes the processing unit 331 receive an operation request signal SH81 in response to the user input operation JS81. The processing unit 331 determines a specific range code EB1T in response to the operation request signal SH81. The specific range code EB1T indicates the remaining time designation interval HJ1ET.

For example, the processing unit 331 determines the specific range code EB1T in response to the user input operation JS81. Before the variable remaining time TA1A enters the remaining time application interval HJ1EU, the button switch 380A receives the user input operation for selecting the button switch 380A JS81, and respond to the user input operation JS81 to make the processing unit 331 receive the operation request signal SH81. For example, the user input operation BB8C occurs before the user input operation JS81. The processing unit 331 starts the timer 346 in response to one of the user input operation JS81 and the operation request signal SH81.

The processing unit 331 obtains the measurement value NJ81 in response to the sensing signal ST81 due to the operation request signal SH81. For example, the operation request signal SH81 is used to determine the remaining time specified interval HJ1ET. The functional device 130 uses the timer 346 to check a time relationship KC81 between the variable remaining time TA1A and the remaining time application interval HJ1EU based on the operation request signal SH81. For example, the sensing signal ST81 is a remaining time signal. The measured value NJ81 is a specific count value.

In some embodiments, the timer 346 complies with a timer specification FT31. For example, the measurement value application range RJ1U is preset based on the timer specification FT31. The timer specification FT31 contains a full measured value range representation FJ8E for representing a full measured value range QJ8E. For example, the measured value application range RJ1U is equal to a part of the full measured value range QJ8E. The measurement value NJ81 is obtained in a specified measurement value format HH97. The measurement value application range RJ1U is preset in the designated measurement value format HH97 based on the timer specification FT31. For example, the remaining time application interval HR1EU is a remaining time candidate interval. The measurement value application range RJ1U is a measurement time value candidate range. The remaining time designation period HJ1ET is a remaining time target period. The specified measurement value format HH97 is a specified count value format.

The application range of the measured value RJ1U has an application range The limit value pair is DJ1U, and is represented by a measurement value application range code EF1U. For example, the application range threshold is preset for DJ1U. The processing unit 331 responds to one of the user input operation JS81 and the operation request signal SH81 to obtain the application range limit value pair DJ1U and the measurement value application range code EF1U, and compare the measurement value NJ81 with the obtained Check the mathematical relationship KB81 for the application range limit value for DJ1U. The physical parameter target state JE1U is represented by a physical parameter target state code EW1U. The physical parameter application unit 335 has the variable physical parameter QU1A. For example, the variable physical parameter QU1A is currently in a physical parameter application state JE1T. The application range limit pair DJ1U is a candidate range limit pair. The measurement value application range code EF1U is a measurement time value candidate range code. The physical parameter target status code EG1C is or is the same as the physical parameter target status code EW1U.

The variable remaining time TA1A is characterized based on a plurality of different remaining time reference intervals HJ1E1 , HJ1E2 , . . . . The plurality of different remaining time reference intervals HJ1E1, HJ1E2, . . . include the remaining time specified interval HJ1ET and the remaining time application interval HJ1EU. Under the condition that the variable application time TC1A is equal to the variable remaining time TA1A, the plurality of different reference time intervals HV11, HV12, . . . are respectively equal to the plurality of different remaining time reference intervals HJ1E1, HJ1E2, . . .

In some embodiments, under the condition that the processing unit 331 determines the remaining time application interval HJ1EU in which the variable remaining time TA1A is currently located by checking the mathematical relationship KB81, the processing unit 331 based on the obtained measurement The value applies the range code EF1U to obtain the physical parameter target status code EW1U, and based on the obtained physical parameter target status The state code EW1U executes a physical parameter relationship checking control GX8U for checking a physical parameter relationship KD9U between the variable physical parameter QU1A and the physical parameter target state JE1U.

When the physical parameter application state JE1T is different from the physical parameter target state JE1U and the processing unit 331 determines a physical relationship between the physical parameter target state JE1U and the physical parameter application state JE1T by executing the physical parameter relationship check control GX8U Under the condition of the parameter state difference DT81, the processing unit 331 executes a signal generation control GY85 based on the obtained physical parameter target state code EW1U to generate an operation signal SG85, and transmits the operation signal SG85 to the physical parameter application unit 335 . For example, the operation signal SG85 is one of a function signal and a control signal.

The physical parameter application unit 335 responds to the operation signal SG85 to make the variable physical parameter QU1A enter the physical parameter target state JE1U from the physical parameter application state JE1T. Under the condition that the processing unit 331 determines the remaining time application interval HJ1EU where the variable remaining time TA1A is currently located by checking the mathematical relationship KB81, the processing unit 331 executes a data storage control operation GN8U, the data storage control Operation GN8U is used to cause a remaining time application interval code UG8U representing the determined remaining time application interval HJ1EU to be stored by the storage unit 332 . The variable physical parameter QU1A and the variable remaining time TA1A belong to a physical parameter type TU11 and a remaining time type TQ21 respectively. For example, the physical parameter type TU11 is different from the remaining time type TQ21.

See Figure 23, Figure 24 and Figure 25. FIG. 23 is a schematic diagram of an implementation structure 9232 of the control system 921 shown in FIG. 1 . FIG. 24 is a schematic diagram of an implementation structure 9233 of the control system 921 shown in FIG. 1 . FIG. 25 is a schematic diagram of an implementation structure 9234 of the control system 921 shown in FIG. 1 . As shown in FIG. 23 , FIG. 24 and FIG. 25 , each structure of the implementation structure 9232 , the implementation structure 9233 and the implementation structure 9234 includes the functional device 130 . The functional device 130 includes the processing unit 331 , the storage unit 332 , the input unit 380 , the LED matrix 385 and a timer 34A coupled to the processing unit 331 . The timer 34A is one of the timer 342 and the timer 346 .

In some embodiments, the variable physical parameter QU1A is further characterized based on a physical parameter application state JG1E represented by a physical parameter application state code EG1E and a physical parameter target state JG1F different from the physical parameter application state JG1E change. The physical parameter target state JG1F is represented by a physical parameter target state code EG1F. The storage unit 332 further stores a variable physical parameter state code EG1D representing a variable physical parameter state JG1D. For example, the variable physical parameter state JG1D is a state that the variable physical parameter QU1A is expected to be in in a target time interval HV1V adjacent to the target time interval HV1U. The variable physical parameter status code EG1A and the variable physical parameter status code EG1D are arranged such that the variable physical parameter status code EG1D is adjacent to the variable physical parameter status code EG1A. The variable application time TC1A is characterized based on the target time interval HV1V. For example, the variable physical parameter state JG1A and the variable physical parameter state JG1D are two variable function states respectively. For example, the target time interval HV1V is related to the stored variable physical parameter status code EG1D.

For example, the storage unit 332 stores the variable physical parameter Status code array EGAA. The variable physical parameter status code array EGAA includes the complex variable physical parameter status codes EG11, EG12, . . . The plurality of variable physical parameter status codes EG11, EG12, . . . include the variable physical parameter status code EG1A and the variable physical parameter status JG1D. Under the condition that the clock time TH1A is applied, the plurality of different clock time reference intervals HR1E1, HR1E2, . . . include the target time interval HV1U and the target time interval HV1V. On the condition that the variable remaining time TA1A is applied, the target time interval HV1V is adjacent to the remaining time application interval HJ1EU, and the variable remaining time TA1A is further characterized based on the target time interval HV1V.

In some embodiments, the target time interval HV1V is represented by a measured value target range RQ3V. Under the condition that the variable physical parameter status code EG1D is equal to the physical parameter application status code EG1E and the variable physical parameter status code EG1A is changed to the physical parameter target status code EG1C by virtue of the input unit 380, the processing unit 331 In the setting phase UC81 the variable physical parameter status code EG1D is changed from the physical parameter application status code EG1E to the physical parameter target status code EG1F by means of the input unit 380 . The timer 34A senses the variable application time TC1A in the timing period UD81 to generate a sensing signal SY61 . The processing unit 331 obtains a measurement value NY61 in response to the sensing signal SY61.

Under the condition that the variable physical parameter status code EG1D is equal to the physical parameter target status code EG1F and the functional device 130 is configured in the timing phase UD81, the processing unit 331 checks the measured value NY61 and the measured value application range RQ3V A mathematical relationship between KQ61. In the processing unit 331 due to checking the mathematical relationship KQ61 to determine the clock time Under the condition of the target time interval HV1V that TC1A is currently in, the processing unit 331 accesses the stored physical parameter target state code EG1F, and based on the accessed physical parameter target state code within the target time interval HV1V, EG1F to make the variable physical parameter QU1A in the physical parameter target state JG1F.

For example, the processing unit 331 transmits an operation signal SG8K to the physical parameter application unit 335 based on the accessed physical parameter target state code EG1F within the target time interval HV1V. The operation signal SG8K is used to cause the physical parameter application unit 335 to make the variable physical parameter QU1A be in the physical parameter target state JG1F. For example, the input part 3357 receives the operation signal SG8K from the processing unit 331, and performs a fourth function operation in response to the operation signal SG8K. The fourth function operates to control the output portion 3358 and to cause the output portion 3358 to cause the variable physical parameter QU1A to be in the physical parameter target state JG1F.

The input unit 380 includes the button switch 3805 . Under the condition that the variable physical parameter status code EG1D is equal to the physical parameter application status code EG1E and the variable physical parameter status code EG1A is changed to the physical parameter target status code EG1C by means of the button switch 3805, the processing unit 331 In the setting stage UC81, a user input operation BB8F for selecting the button switch 3805 is received, and the processing unit 331 receives an operation request signal SA82 in response to the user input operation BB8F. The processing unit 331 changes the variable physical parameter status code EG1D from the physical parameter application status code EG1E to the physical parameter target status code EG1F in response to the operation request signal SA82 in the setting phase UC81 .

For example, the button switch 3805 is associated with the variable physical Parameter status code array EGAA. The processing unit 331 responds to one of the user input operation BB8C and the operation request signal SA81 to select the variable physical parameter status code EG1A related to the target time interval HV1U from the variable physical parameter status code array EGAA , and change the selected variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter target status code EG1C. The processing unit 331 responds to one of the user input operation BB8F and the operation request signal SA82 to select the variable physical parameter status code EG1D related to the target time interval HV1V from the variable physical parameter status code array EGAA , and change the selected variable physical parameter status code EG1D from the physical parameter application status code EG1E to the physical parameter target status code EG1F.

For example, the processing unit 331 selects the variable physical parameter status code EG1A from the plurality of variable physical parameter status codes EG11, EG12, . . . in response to one of the user input operation BB8C and the operation request signal SA81. The processing unit 331 selects the variable physical parameter status code EG1D from the plurality of variable physical parameter status codes EG11, EG12, . . . in response to one of the user input operation BB8F and the operation request signal SA82.

In some embodiments, the LED matrix 385 is associated with the variable physical parameter state code array EGAA, and further includes an LED 3853 associated with the target time interval HV1V. For example, the LED 3853 is adjacent to the LED 3852 and is related to the target time interval HV1V. Under the condition that the variable physical parameter state code EG1D is equal to the physical parameter target state code EG1F and the functional device 130 is configured in the timing stage UD81, the processing unit 331 relies on the fixed The timer 34A checks a first time relationship between the variable application time TC1A and the target time interval HV1V.

On the condition that the processing unit 331 determines the target time interval HV1V in which the variable application time TC1A is currently located due to checking the first time relationship, the processing unit 331 accesses the stored time interval associated with the target time interval HV1V. The physical parameter target state code EG1F selects the light emitting diode 3853 related to the target time interval HV1V, and activates the light emitting diode 3853 based on the accessed physical parameter target state code EG1F within the target time interval HV1V Body 3853 displays a status indication LL84. The state indicator LL84 is used to indicate that the variable physical parameter QU1A is configured to be in a specific state XE84 of the physical parameter target state JG1F within the target time interval HV1V. For example, the status indicator LL84 has a blink. For example, the LED 3853 is coupled to the base 385A and supported by the base 385A.

In some embodiments, under the condition that the variable physical parameter status code EG1A is equal to the physical parameter target status code EG1C and the functional device 130 is configured in the timing phase UD81, the processing unit 331 relies on the timer 34A to A second time relationship between the variable application time TC1A and the target time interval HV1U is checked. On the condition that the processing unit 331 determines the target time interval HV1U in which the variable application time TC1A is currently located due to checking the second time relationship, the processing unit 331 accesses the stored time interval associated with the target time interval HV1U. The physical parameter target state code EG1C selects the light-emitting diode 3852 related to the target time interval HV1U, and makes the selected light-emitting diode 3852 based on the accessed physical parameter target state code EG1C within the target time interval HV1U send Photodiode 3852 displays the status indication LL82.

For example, the input unit 380 receives the user input operation JS81 under the condition that the processing unit 331 causes the light emitting diode 3853 to display a state indication LL83. The state indicator LL83 is used to indicate that the variable physical parameter QU1A is expected to be in a specific state XE83 of the physical parameter target state JG1F within the target time interval HV1V. For example, the status indication LL84 is different from the status indication LL83. The functional device 130 is used by a user 395 . For example, the user 395 performs the user input operation JS82, the user input operation BB8C, the user input operation BB8F, the user input operation BB8H, the user input operation JS81, the user input operation JS83, the user input operation User input operates on one of JS86 and any combination thereof.

For example, the light emitting diode matrix 385 includes the base body 385A and a plurality of light emitting diodes 3851, 3852, . The plurality of light emitting diodes 3851, 3852, . . . include the light emitting diode 3851, the light emitting diode 3852 and the light emitting diode 3853, all of which are directly coupled to the base body 385A. For example, the LED matrix 385 includes a first LED row 581 and a second LED row 582 adjacent to the first LED row 581 . The first LED array 581 includes the LED 3852 and the LED 3853 and is associated with a first specific hour. The first specific hour includes the target time interval HV1U and the target time interval HV1V.

The second light-emitting diode column 582 includes a plurality of light-emitting diodes, and is related to a second specific hour adjacent to the first specific hour. Time. The plurality of light emitting diodes 3851 , 3852 , . . . include the plurality of light emitting diodes of the second light emitting diode row 582 . The second specific hour includes a plurality of target time intervals respectively associated with the plurality of light-emitting diodes. On the condition that the target time interval HV1V is a first end time interval, the plurality of target time intervals includes a second end time interval adjacent to the target time interval HV1V. The plurality of different reference time intervals HV11, HV12, . . . include the target time interval HV1U, the target time interval HV1V and the plurality of target time intervals of the second specific hour.

For example, the variable physical parameter status code array EGAA includes a first variable physical parameter status code column related to the first LED column 581 and a first variable physical parameter status code column related to the second LED column 582. Two variable physical parameter status code columns. The first variable physical parameter status code column is related to the first specific hour, and includes the variable physical parameter status code EG1A related to the target time interval HV1U, and the variable physical parameter status code related to the target time interval HV1V. Parameter status code EG1D. The second variable physical parameter status code column is related to the second specific hour and includes a plurality of variable physical parameter status codes; and the plurality of target time intervals in the second specific hour are respectively related to the second variable physical parameter The complex variable physical parameter status code of the status code column.

The input unit 380 includes the plurality of push button switches 3805, 380A, . . . The plurality of button switches 3805, 380A, . . . include the button switch 3805, the button switch 3807, the button switch 380A, and the button switch 380B, and are coupled to each other through a silicon film 380Z. For example, the input unit 380 includes the silicon film 380Z. The silicone sheet 380Z includes a plurality of silicone parts A1, A2, . . . The plurality of pushbutton switches 3805, 380A, . . . The plurality of silicone rubber parts A1, A2, . . . and a plurality of conductive adhesive layers B1, B2, .

Please refer to FIG. 26 , which is a schematic diagram of a control system 931 in various embodiments of the present disclosure. The control system 931 comprises a function device 130 for a variable physical parameter QU1A. For example, the variable physical parameter QU1A is characterized based on a physical parameter target state JG1C represented by a physical parameter target state code EG1C. The functional device 130 includes an LED matrix 385 and a processing unit 331 .

The LED matrix 385 includes an LED 3852 associated with a target time interval HV1U. The processing unit 331 is coupled to the light emitting diode matrix 385, configured to obtain the physical parameter target state code EG1C within the target time interval HV1U, and make the light emitting diodes based on the obtained physical parameter target state code EG1C Pole body 3852 displays a status indication LL82. The state indicator LL82 is used to indicate that the variable physical parameter QU1A is configured to be in a specific state XE82 of the physical parameter target state JG1C within the target time interval HV1U.

See Figure 27 and Figure 28. FIG. 27 is a schematic diagram of an implementation structure 9311 of the control system 931 shown in FIG. 26 . FIG. 28 is a schematic diagram of an implementation structure 9312 of the control system 931 shown in FIG. 26 . As shown in FIG. 27 and FIG. 28 , each structure of the implementation structure 9311 and the implementation structure 9312 includes the functional device 130 . In some embodiments, the processing unit 331 is coupled to a physical parameter application unit 335 having the variable physical parameter QU1A. The variable physical parameter QU1A is related to a variable application time TC1A. The variable application time TC1A is characterized based on the target time interval HV1U and is a clock time TH1A and a variable Change one of the remaining time TA1A. For example, the status indicator LL82 has a blink.

For example, the target time interval HV1U is one of a clock time target interval and a remaining time target interval. Under the condition that the processing unit 331 determines that the variable application time TC1A is currently in the target time interval HV1U, the processing unit 331 obtains the physical parameter target state code EG1C, and based on the obtained physical parameter target state code EG1C to transmit an operation signal SG85 to the physical parameter application unit 335 . The operation signal SG85 is used to cause the physical parameter application unit 335 to make the variable physical parameter QU1A be in the physical parameter target state JG1C.

In some embodiments, the functional device 130 further includes an input unit 380 coupled to the processing unit 331 , and a storage unit 332 coupled to the processing unit 331 . The variable physical parameter QU1A is further characterized based on a physical parameter application state JG1B different from the physical parameter target state JG1C. The physical parameter application status JG1B is represented by a physical parameter application status code EG1B. The storage unit 332 stores a variable physical parameter state code EG1A representing a variable physical parameter state JG1A. For example, the variable physical parameter state JG1A is a state that the variable physical parameter QU1A is expected to be in within the target time interval HV1U.

Under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, the processing unit 331 relies on the input unit 380 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to The physical parameter target status code EG1C. The input unit 380 includes a button switch 3805 . For example, the button switch 3805 is coupled to the processing unit 331 . In this variable physical parameter state Under the condition that the status code EG1A is equal to the application status code EG1B of the physical parameter, the button switch 3805 receives a user input operation BB8C for selecting the button switch 3805, and responds to the user input operation BB8C to make the processing unit 331 receive An operation request signal SA81.

The processing unit 331 responds to the operation request signal SA81 to change the variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter target status code EG1C. Under the condition that the variable physical parameter state code EG1A is equal to the physical parameter target state code EG1C, the processing unit 331 accesses the stored physical parameter target state code EG1C within the target time interval HV1U, and based on the accessed The physical parameter target state code EG1C is used to make the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

See Figure 26, Figure 27 and Figure 28. A method MM82 for a variable physical parameter QU1A is disclosed. For example, the variable physical parameter QU1A is characterized based on a physical parameter target state JG1C represented by a physical parameter target state code EG1C.

The method MM80 comprises the following steps: providing an LED matrix 385 comprising an LED 3852, wherein the LED 3852 is associated with a target time interval HV1U; within the target time interval HV1U, obtaining the physical Parameter target state code EG1C; and based on the obtained physical parameter target state code EG1C, make the light-emitting diode 3852 display a state indication LL82, and the state indication LL82 is used to indicate that the variable physical parameter QU1A is in the target time interval HV1U is configured to be in a specific state XE82 of the physical parameter target state JG1C.

In some embodiments, the variable physical parameter QU1A phase Regarding a variable application time TC1A. The variable application time TC1A is characterized based on the target time interval HV1U and is one of a clock time TH1A and a variable remaining time TA1A. The method MM82 further includes the following steps: providing a physical parameter application unit 335 with the variable physical parameter QU1A; obtaining the physical parameter under the condition that the target time interval HV1U in which the variable application time TC1A is currently located is determined Target state code EG1C; and based on the obtained physical parameter target state code EG1C, transmit an operation signal SG85 to the physical parameter application unit 335, the operation signal SG85 is used to cause the physical parameter application unit 335 to make the variable physical parameter QU1A is in the physical parameter target state JG1C.

In some embodiments, the variable physical parameter QU1A is further characterized based on a physical parameter application state JG1B different from the physical parameter target state JG1C. The physical parameter application status JG1B is represented by a physical parameter application status code EG1B. The method MM82 further includes the following steps: providing a button switch 3805; and storing a variable physical parameter state code EG1A representing a variable physical parameter state JG1A, wherein the variable physical parameter state JG1A is the variable physical parameter QU1A in A state expected to be in the target time interval HV1U.

The method MM82 further includes the following steps: under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, changing the variable physical parameter status code EG1A from the physical parameter application status code EG1B to the physical parameter application status code EG1B Parameter target state code EG1C; under the condition that the variable physical parameter state code EG1A is equal to the physical parameter target state code EG1C, access the stored physical parameter target state code EG1C within the target time interval HV1U; and based on the access The physical parameter target state code EG1C makes the variable physical parameter state JG1A equal to the physical parameter target state JG1C.

The step of changing the variable physical parameter status code EG1A into the physical parameter target status code EG1C includes the following substeps: under the condition that the variable physical parameter status code EG1A is equal to the physical parameter application status code EG1B, make the button switch 3805 receives a user input operation BB8C for selecting the button switch 3805; in response to the user input operation BB8C, receives an operation request signal SA81; and in response to the operation request signal SA81, changes the variable physical parameter status code EG1A from The physical parameter application status code EG1B is changed to the physical parameter target status code EG1C.

Many variations and other embodiments of the present disclosure presented herein will be appreciated by those skilled in the art having the benefit of the teachings presented in the foregoing description and associated drawings. Therefore, it should be understood that the present disclosure is not limited to the disclosed specific embodiments, and modifications and other embodiments are intended to be included within the scope of the following claims.

130: Functional device

331: processing unit

332: storage unit

380: input unit

921: control system

EG1A: variable physical parameter status code

EG1C: physical parameter target status code

HV1U: target time interval

JG1A: variable physical parameter status

JG1C: Physical parameter target state

QU1A: variable physical parameters

Claims (12)

A functional device for controlling a variable physical parameter, wherein the variable physical parameter is characterized based on a physical parameter target state represented by a physical parameter target state code, the variable physical parameter is further based on a A physical parameter application state of the physical parameter target state is characterized, and the physical parameter application state is represented by a physical parameter application state code. The functional device includes: an input unit, including a switch; a storage unit, storing representative a variable physical parameter state code for a variable physical parameter state, wherein the variable physical parameter state is a state that the variable physical parameter is expected to be in within a target time interval; and a processing unit coupled to the input The unit and the storage unit are configured to change the variable physical parameter status code from the physical parameter application status code to the physical parameter status code by means of the switch under the condition that the variable physical parameter status code is equal to the physical parameter application status code. parameter target state code, and make the variable physical parameter state equal to the physical parameter target state within the target time interval based on the changed variable physical parameter state code equal to the physical parameter target state code. The functional device as claimed in claim 1, further comprising a light-emitting diode matrix coupled to the processing unit, wherein: the variable physical parameter is related to a variable application time; the variable application time is based on the target time interval characterized by, and being one of, a clock time and a variable remaining time; the light-emitting diode matrix comprising a light-emitting diode associated with the target time interval; Under the condition that the variable physical parameter state code is equal to the physical parameter target state code and the processing unit determines that the variable application time is currently in the target time interval, the processing unit accesses the stored physical parameter target state code, and based on the accessed physical parameter target state code to make the light emitting diode display a state indication, the state indication is used to indicate that the variable physical parameter is configured to be at the physical parameter within the target time interval a specific state of the target state; and the processing unit is coupled to a physical parameter application unit having the variable physical parameter, and transmits an operation signal to the physical parameter application unit based on the accessed physical parameter target state code, the physical parameter application unit The operation signal is used to cause the physical parameter application unit to make the state of the variable physical parameter equal to the target state of the physical parameter. The functional device as described in claim 1, wherein: the switch is a button switch; under the condition that the variable physical parameter status code is equal to the physical parameter application status code, the button switch receives a button for selecting the button switch The user inputs an operation, and the processing unit receives an operation request signal in response to the user input operation; and the processing unit responds to the operation request signal to change the variable physical parameter status code from the physical parameter application status code to The physical parameter target status code. A method for controlling a variable physical parameter, wherein the variable physical parameter is characterized based on a physical parameter target state represented by a physical parameter target state code, the variable physical parameter is further based on a a physical parameter of the parameter target state is characterized using the state, and The physical parameter application state is represented by a physical parameter application state code, and the method includes the following steps: providing a switch; storing a variable physical parameter state code representing a variable physical parameter state, wherein the variable physical parameter state is A state that the variable physical parameter is expected to be in within a target time interval; under the condition that the variable physical parameter state code is equal to the physical parameter application state code, relying on the switch to change the variable physical parameter state code from The physical parameter application state code is changed to the physical parameter target state code; and during the target time interval, the variable physical parameter state is based on the changed variable physical parameter state code equal to the physical parameter target state code equal to the physical parameter target state. The method of claim 4, wherein: the variable physical parameter is associated with a variable application time; the variable application time is characterized based on the target time interval and is a clock time and a variable remaining time and the method further comprises the steps of: providing a light emitting diode matrix comprising a light emitting diode, wherein the light emitting diode is associated with the target time interval; providing a light emitting diode having the variable physical parameter A physical parameter application unit; under the condition that the variable physical parameter state code is equal to the physical parameter target state code and the target time interval in which the variable application time is currently located is determined, access the stored physical parameter target state code; based on the physical parameter target status code accessed, make the light The diode displays a state indication for indicating that the variable physical parameter is configured to be in a specific state of the physical parameter target state within the target time interval; and based on the accessed physical parameter target state The code transmits an operation signal to the physical parameter application unit, and the operation signal is used to cause the physical parameter application unit to make the state of the variable physical parameter equal to the target state of the physical parameter. The method as claimed in claim 4, wherein: the switch is a button switch; and the step of changing the variable physical parameter status code into the physical parameter target status code includes the following sub-steps: in the variable physical parameter status code Under the condition equal to the application state code of the physical parameter, the button switch receives a user input operation for selecting the button switch; in response to the user input operation, an operation request signal is received; and in response to the operation request signal, the The variable physical parameter status code is changed from the physical parameter application status code to the physical parameter target status code. A functional device for a variable physical parameter characterized based on a physical parameter target state represented by a physical parameter target state code, the functional device comprising: a light emitting diode matrix , including a light-emitting diode associated with a target time interval; and a processing unit, coupled to the light-emitting diode matrix, configured to obtain the physical parameter target state code within the target time interval, and based on the The obtained physical parameter target state code is used to make the light emitting diode display a state indication, and the state indication is used to indicate that the variable physical parameter is configured to be in a specific state of the physical parameter target state within the target time interval . The functional device as claimed in claim 7, wherein: the processing unit is coupled to a physical parameter application unit having the variable physical parameter; the variable physical parameter is related to a variable application time; the variable application time is based on the The target time interval is characterized by a target time interval and is one of a clock time and a variable remaining time; and under the condition that the processing unit determines that the variable application time is currently in the target time interval, the processing unit Obtain the physical parameter target state code, and transmit an operation signal to the physical parameter application unit based on the obtained physical parameter target state code, the operation signal is used to cause the physical parameter application unit to make the variable physical parameter in the physical parameter Parameter target state. The functional device as claimed in claim 7, further comprising an input unit coupled to the processing unit, and a storage unit coupled to the processing unit, wherein: the variable physical parameter is further based on a target state different from the physical parameter A physical parameter application status is characterized, and the physical parameter application status is represented by a physical parameter application status code; the storage unit stores a variable physical parameter status code representing a variable physical parameter status, wherein the variable The physical parameter state is a state that the variable physical parameter is expected to be in within the target time interval; On the condition that the variable physical parameter status code is equal to the physical parameter application status code, the processing unit changes the variable physical parameter status code from the physical parameter application status code to the physical parameter target status code by means of the input unit ; The input unit includes a button switch; Under the condition that the variable physical parameter status code is equal to the physical parameter application status code, the button switch receives a user input operation for selecting the button switch, and responds to the user input operation to cause the processing unit to receive an operation request signal; and the processing unit responds to the operation request signal to change the variable physical parameter status code from the physical parameter application status code to the physical parameter target status code; and Under the condition that the variable physical parameter status code is equal to the physical parameter target status code, the processing unit accesses the stored physical parameter target status code within the target time interval, and based on the accessed physical parameter target status code to make the variable physical parameter state equal to the physical parameter target state. A method for a variable physical parameter characterized based on a physical parameter target state represented by a physical parameter target state code, the method comprising the steps of: providing a A light-emitting diode matrix of a body, wherein the light-emitting diodes are associated with a target time interval; within the target time interval, the physical parameter target state code is obtained; and based on the obtained physical parameter target state code, the The LED The body displays a state indication for indicating that the variable physical parameter is configured to be in a specific state of the physical parameter target state within the target time interval. The method of claim 10, wherein: the variable physical parameter is associated with a variable application time; the variable application time is characterized based on the target time interval and is a clock time and a variable remaining time and the method further comprises the steps of: providing a physical parameter application unit having the variable physical parameter; obtaining the physical parameter target status code; and based on the obtained physical parameter target status code, transmit an operation signal to the physical parameter application unit, the operation signal is used to cause the physical parameter application unit to make the variable physical parameter at the physical parameter target state. The method of claim 10, wherein: the variable physical parameter is further characterized based on a physical parameter application state different from the physical parameter target state, and the physical parameter application state is defined by a physical parameter application state code Representative; the method further includes the following steps: providing a button switch; storing a variable physical parameter state code representing a variable physical parameter state, wherein the variable physical parameter state is that the variable physical parameter is within the target time interval a state to be expected to be in; Under the condition that the variable physical parameter status code is equal to the physical parameter application status code, change the variable physical parameter status code from the physical parameter application status code to the physical parameter target status code; in the variable physical parameter status Under the condition that the code is equal to the target status code of the physical parameter, access the stored target status code of the physical parameter within the target time interval; and based on the accessed target status code of the physical parameter, make the variable physical parameter status equal to the physical parameter target state; and the step of changing the variable physical parameter status code to the physical parameter target status code includes the following sub-steps: under the condition that the variable physical parameter status code is equal to the physical parameter application status code, making the button switch receive a user input operation for selecting the button switch; receiving an operation request signal in response to the user input operation; and changing the variable physical parameter status code from the physical parameter in response to the operation request signal The application status code is changed to the physical parameter target status code.

Images