CN111699607A - Micro-energy acquisition chip, circuit, equipment and control method thereof - Google Patents
Micro-energy acquisition chip, circuit, equipment and control method thereof Download PDFInfo
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- CN111699607A CN111699607A CN202080000614.3A CN202080000614A CN111699607A CN 111699607 A CN111699607 A CN 111699607A CN 202080000614 A CN202080000614 A CN 202080000614A CN 111699607 A CN111699607 A CN 111699607A
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/007—Regulation of charging or discharging current or voltage
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/145—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M3/155—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
- H02M3/158—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators including plural semiconductor devices as final control devices for a single load
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2207/00—Indexing scheme relating to details of circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J2207/20—Charging or discharging characterised by the power electronics converter
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B40/00—Technologies aiming at improving the efficiency of home appliances, e.g. induction cooking or efficient technologies for refrigerators, freezers or dish washers
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- Charge And Discharge Circuits For Batteries Or The Like (AREA)
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Abstract
The application belongs to the field of weak energy collection and discloses a micro-energy collection chip, a circuit, equipment and a control method thereof; the first energy storage assembly and the second energy storage assembly are charged according to the first micro-energy voltage; the second switch component switches off the power ground and the second end of the second energy storage component according to a second control signal; the first switch component is communicated with the first end of the first energy storage component and the second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from the ground terminal, and generates a first wireless communication signal according to a first data signal and transmits the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to the power ground according to a third control signal; the weak energy acquisition threshold is reduced, and the energy use efficiency is improved.
Description
Technical Field
The application belongs to the field of weak energy collection, and particularly relates to a micro-energy collection chip, a circuit, equipment and a control method thereof.
Background
In the field of weak energy collection, the energy use efficiency is very low, for example, a pressing collection circuit is taken, micro-energy alternating current is obtained through pressing, and then micro-energy voltage is generated according to the micro-energy alternating current, and in one period, from 0V to the highest point, the micro-energy voltage at the highest point is determined by the size of an energy storage capacitor. During the 0V up to 2V period, the chip (including microprocessor and RF chip) is not working.
In an original parallel circuit or series circuit, only one system energy storage capacitor (about 2.2 UF) is arranged, and the positive electrode of the system energy storage capacitor and the negative electrode of the system energy storage capacitor are respectively and electrically connected to the power supply positive end of the chip and the ground. After the working voltage of the system is lower than about 2V, the microprocessor and the radio frequency chip stop working, so that residual charges exist in an energy storage capacitor of the system, micro-energy alternating current cannot be effectively utilized, and only the charges stored between the highest voltage and 2V are used in principle.
Therefore, the conventional micro-energy harvesting device has the defects that the energy lower than the micro-energy voltage cannot be utilized, so that the threshold value of weak energy harvesting is high and the energy use efficiency is low.
Disclosure of Invention
The application provides a micro-energy acquisition chip, a circuit, equipment and a control method thereof, aiming at solving the problems of high threshold value and low energy use efficiency of weak energy acquisition in the prior art.
The micro energy acquisition chip is connected with a first energy storage assembly and a second energy storage assembly, and comprises a first switch assembly, a second switch assembly, a first radio frequency assembly, a first one-way conduction assembly, a first field effect tube, a second field effect tube, a third field effect tube and a fourth field effect tube;
the control end of the first switch component is the first control end of the micro energy collecting chip, the control end of the second switch component is the second control end of the micro energy collecting chip, the grid of the first field effect tube and the grid of the second field effect tube jointly form the third control end of the micro energy collecting chip, the grid of the third field effect tube and the grid of the fourth field effect tube jointly form the fourth control end of the micro energy collecting chip, the drain of the first field effect tube, the drain of the third field effect tube, the cathode of the first one-way conduction component and the power end of the first radio frequency component jointly form the first capacitor end of the micro energy collecting chip, the first input and output end of the first switch component and the anode of the first one-way conduction component jointly form the input power end of the micro energy collecting chip, the second input/output end of the first switch component and the first input/output end of the second switch component jointly form a second capacitor end of the micro energy acquisition chip, the second input/output end of the second switch component, the drain electrode of the fourth field effect transistor and the drain electrode of the second field effect transistor jointly form a power ground end of the micro energy acquisition chip, the source electrode of the second field effect transistor is connected with the source electrode of the first field effect transistor and the radio frequency ground end of the first radio frequency component, and the source electrode of the third field effect transistor is connected with the source electrode of the fourth field effect transistor and the data end of the first radio frequency component;
the first end of the first energy storage assembly is connected with the input power end of the micro energy acquisition chip, the first end of the second energy storage assembly is connected with the first capacitor end of the micro energy acquisition chip, the second end of the second energy storage assembly is connected with the second capacitor end of the micro energy acquisition chip, and the power ground end of the micro energy acquisition chip and the second end of the first energy storage assembly are connected to a power ground in a shared mode;
the first unidirectional conducting component is configured to conduct a first micro-energy voltage in a unidirectional way; the first energy storage assembly and the second energy storage assembly are both configured to be charged according to the first micro-energy voltage; the second switch component is configured to switch off the connection between a power ground and the second end of the second energy storage component according to a second control signal; the first switch component is configured to communicate a first end of the first energy storage component with a second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage-multiplying voltage; the first radio frequency component is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from a ground, and generate a first wireless communication signal according to a first data signal and transmit the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to a power ground according to a third control signal; the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip.
The embodiment of the application further provides a control method of the micro energy collecting chip, which includes:
step A1: the first switch assembly is turned off, and the second switch assembly is communicated to a power ground, so that the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage, and the second energy storage assembly is charged according to the first micro-energy voltage conducted by the first unidirectional conduction assembly to generate a second charging voltage;
step A2: the input power end of the micro-energy acquisition chip inputs a first micro-energy voltage, and the micro-energy acquisition chip works according to the first micro-energy voltage;
step A3: a second control signal is input through the second control end of the micro energy acquisition chip to turn off the connection between the second end of the second energy storage component and a power ground, a first control signal is input through the first control end of the micro energy acquisition chip to control the first switch component to communicate the first end of the first energy storage component and the second end of the second energy storage component, so that the potential of the first end of the first energy storage component is equal to the potential of the second end of the second energy storage component, and the voltage of the second end of the second energy storage component is the sum of the second charging voltage and the first charging voltage to generate the first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; inputting a third control signal through a third control end of the micro-energy acquisition chip to control the second field effect transistor to communicate the first ground voltage to a power ground;
step A4: the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
The embodiment of the application also provides micro-energy acquisition equipment, which comprises a first energy storage assembly, a second energy storage assembly and the micro-energy acquisition chip.
The embodiment of the application also provides another micro energy acquisition chip which is connected with the first radio frequency assembly, the first energy storage assembly and the second energy storage assembly, wherein the micro energy acquisition chip comprises a first switch assembly, a second switch assembly, a first one-way conduction assembly, a first field effect tube, a second field effect tube, a third field effect tube and a fourth field effect tube;
the control end of the first switch component is a first control end of the micro energy acquisition chip, the control end of the second switch component is a second control end of the micro energy acquisition chip, the grid electrode of the first field effect tube and the grid electrode of the second field effect tube jointly form a third control end of the micro energy acquisition chip, the grid electrode of the third field effect tube and the grid electrode of the fourth field effect tube jointly form a fourth control end of the micro energy acquisition chip, the drain electrode of the first field effect tube, the drain electrode of the third field effect tube and the negative electrode of the first one-way conduction component jointly form a first capacitor end of the micro energy acquisition chip, the first input and output end of the first switch component and the positive electrode of the first one-way conduction component jointly form an input power supply end of the micro energy acquisition chip, and the second input and output end of the first switch component and the first input and output end of the second switch component jointly form a second control end of the micro energy acquisition chip The second capacitor end of the micro energy acquisition chip, the second input/output end of the second switch component, the drain electrode of the fourth field effect transistor and the drain electrode of the second field effect transistor jointly form a power ground end of the micro energy acquisition chip, the source electrode of the second field effect transistor and the source electrode of the first field effect transistor jointly form a voltage input end of the micro energy acquisition chip, and the source electrode of the third field effect transistor and the source electrode of the fourth field effect transistor jointly form a first data input/output end of the micro energy acquisition chip;
the first end of the first energy storage component is connected with the input power end of the micro energy acquisition chip, the first end of the second energy storage component is connected with the power end of the first radio frequency component and the first capacitor end of the micro energy acquisition chip, the second end of the second energy storage component is connected with the second capacitor end of the micro energy acquisition chip, the data end of the first radio frequency component is connected with the voltage input end of the micro energy acquisition chip, the grounding end of the first radio frequency component is connected with the first data input and output end of the micro energy acquisition chip, and the power ground end of the micro energy acquisition chip and the second end of the first energy storage component are connected to a power ground in common;
the first unidirectional conducting component is configured to conduct a first micro-energy voltage in a unidirectional way; the first energy storage assembly and the second energy storage assembly are both configured to be charged according to the first micro-energy voltage; the second switch component is configured to switch off the connection between a power ground and the second end of the second energy storage component according to a second control signal; the first switch component is configured to communicate a first end of the first energy storage component with a second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage-multiplying voltage; the first radio frequency component is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from a ground, and generate a first wireless communication signal according to a first data signal and transmit the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to a power ground according to a third control signal; the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip.
The embodiment of the present application further provides a control method for the micro energy collection chip, including:
step B1: the first switch assembly is turned off, and the second switch assembly is communicated to a power ground, so that the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage, and the second energy storage assembly is charged according to the first micro-energy voltage conducted by the first unidirectional conduction assembly to generate a second charging voltage;
step B2: the input power end of the micro-energy acquisition chip inputs a first micro-energy voltage, and the micro-energy acquisition chip works according to the first micro-energy voltage;
step B3: inputting a second control signal through a second control end B of the micro energy acquisition chip to turn off the connection between a second end of the second energy storage component and a power ground, inputting a first control signal through a first control end A of the micro energy acquisition chip to control the first switch component to communicate the first end of the first energy storage component and the second end of the second energy storage component, so that the potential of the first end of the first energy storage component is equal to the potential of the second end of the second energy storage component, and the voltage of the second end of the second energy storage component is the sum of the second charging voltage and the first charging voltage to generate the first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; inputting a third control signal through a third control end of the micro-energy acquisition chip to control the second field effect transistor to communicate the first ground voltage to a power ground;
step B4: the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
The embodiment of the application also provides micro-energy acquisition equipment, which comprises a first energy storage assembly, a second energy storage assembly and the micro-energy acquisition chip.
The embodiment of the application also provides a micro energy acquisition circuit, which comprises a microprocessor, a first radio frequency assembly, a first switch assembly, a second switch assembly, a first energy storage assembly, a second energy storage assembly and a first one-way conduction assembly;
the first unidirectional conducting component is configured to conduct the first micro-energy voltage in a unidirectional way;
the first energy storage assembly is connected with the first unidirectional conduction assembly and is configured to be charged according to the first micro-energy voltage;
the second energy storage assembly is connected with the first unidirectional conduction assembly and is configured to be charged according to the first micro-energy voltage;
the first switch component is connected with the first energy storage component and the first unidirectional conducting component and is configured to be communicated with the second energy storage component and the first energy storage component according to a first control signal so that the second energy storage component and the first energy storage component are connected in series to generate a first voltage doubling voltage;
the second switch assembly is connected with the second energy storage assembly and the first switch assembly and is configured to turn off the connection between the second energy storage assembly and a power ground according to a second control signal;
the microprocessor is provided with a power supply end connected with the negative electrode of the first unidirectional conducting component and the second energy storage component, a first input-output end connected with the first radio frequency component, a second input-output end connected with the first radio frequency component, and a ground end which is commonly connected with the first energy storage component and the second switch component and is used for supplying power according to the first micro-energy voltage and generating a third control signal so that the first ground end voltage is communicated to the power ground through the first input-output end and a first data signal is generated;
the first radio frequency component is provided with a negative electrode connected with the first unidirectional conducting component, a power end connected with the microprocessor and the second energy storage component, a data end connected with the microprocessor and a ground end connected with the microprocessor, and is configured to generate the first ground end voltage according to the first voltage doubling voltage and output the first ground end voltage from the ground end, generate a first wireless communication signal according to the first data signal and send the first wireless communication signal from a wireless link.
The embodiment of the present application further provides a control method of the micro energy collection circuit, including:
step C1: the first switch assembly is turned off, the second switch assembly is communicated to a power ground, so that the second energy storage assembly is charged according to the first micro-energy voltage to generate a second charging voltage, and the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage;
step C2: a power supply end of the microprocessor inputs a first micro-energy voltage, and the microprocessor works according to the first micro-energy voltage;
step C3: a second control signal is input through the control end of the second switch assembly to turn off the connection between the second energy storage assembly and a power ground, a first control signal is input through the control end of the first switch assembly to communicate the second energy storage assembly and the first energy storage assembly, so that the second energy storage assembly and the first energy storage assembly are connected in series, and the voltage of the first end of the second energy storage assembly is the sum of the first charging voltage and the second charging voltage to generate a first voltage doubling voltage;
the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; generating the third control signal through the microprocessor to connect the first ground voltage to a power ground through a first input/output end of the microprocessor;
step C4: the microprocessor generating the first data signal; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
The beneficial effect that technical scheme that this application provided brought is: as can be seen from the above application, the first unidirectional conducting component conducts the first micro-energy voltage unidirectionally; the first energy storage assembly and the second energy storage assembly are charged according to the first micro-energy voltage; the second switch component switches off the connection between the power ground and the second end of the second energy storage component according to a second control signal; the first switch component is communicated with the first end of the first energy storage component and the second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage, outputs the first ground voltage from the ground terminal, generates a first wireless communication signal according to a first data signal and sends the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to the power ground according to a third control signal; the first energy storage assembly and the second energy storage assembly are connected in series to realize double-voltage bootstrap, so that the threshold value of weak energy collection is reduced, and the energy use efficiency is improved.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.
Fig. 1 is a block diagram of a micro energy harvesting chip according to an embodiment of the present disclosure;
fig. 2 is another block diagram of a micro energy harvesting chip according to an embodiment of the present disclosure;
fig. 3 is a schematic circuit diagram of a micro energy harvesting chip according to an embodiment of the present disclosure;
fig. 4 is a block diagram of a micro energy collection device according to a second embodiment of the present disclosure;
fig. 5 is another block structure diagram of the micro energy collecting device according to the second embodiment of the present application;
fig. 6 is another block structure diagram of the micro energy collecting device according to the second embodiment of the present application;
fig. 7 is a circuit diagram of an example of a micro energy collection device according to a second embodiment of the present disclosure;
fig. 8 is a block diagram of a micro energy harvesting chip according to a third embodiment of the present application;
fig. 9 is another block structure diagram of a micro energy collection chip according to a third embodiment of the present application;
fig. 10 is a schematic circuit diagram of a micro energy harvesting chip according to a third embodiment of the present application;
fig. 11 is a block diagram of a micro energy collection device according to a fourth embodiment of the present disclosure;
fig. 12 is another block diagram of a micro energy collection device according to a fourth embodiment of the present disclosure;
fig. 13 is another block diagram of a micro energy collection device according to a fourth embodiment of the present disclosure;
fig. 14 is a circuit diagram of an example of a micro energy collection device according to a fourth embodiment of the present disclosure;
fig. 15 is a block diagram of a micro energy collection circuit according to a fifth embodiment of the present application;
fig. 16 is another block diagram of the micro energy collection circuit according to the fifth embodiment of the present application;
fig. 17 is another block diagram of the micro energy collection circuit according to the fifth embodiment of the present application;
fig. 18 is another block diagram of the micro energy collection circuit according to the fifth embodiment of the present application;
fig. 19 is a circuit diagram of an example of a micro energy collection circuit according to a fifth embodiment of the present application;
fig. 20 is a graph of voltage variation with time of a conventional micro energy collecting device and a graph of voltage variation with time of a micro energy collecting circuit provided in the fifth embodiment of the present application.
Detailed Description
In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.
Example one
Fig. 1 shows a module structure of a micro energy harvesting chip 01 provided in a first embodiment of the present application, and for convenience of description, only a part related to the first embodiment of the present application is shown, which is detailed as follows:
a micro energy acquisition chip 01 is connected with a first energy storage component 02 and a second energy storage component 03, and the micro energy acquisition chip 01 comprises a first switch component 011, a second switch component 012, a first radio frequency component 013, a first one-way conduction component 014, a first field effect transistor M1, a second field effect transistor M2, a third field effect transistor M3 and a fourth field effect transistor M4;
wherein, the control terminal of the first switch assembly 011 is the first control terminal a of the micro energy collecting chip 01, the control terminal of the second switch assembly 012 is the second control terminal B of the micro energy collecting chip 01, the gate of the first fet M1 and the gate of the second fet M2 jointly form the third control terminal C of the micro energy collecting chip 01, the gate of the third fet M3 and the gate of the fourth fet M4 jointly form the fourth control terminal D of the micro energy collecting chip 01, the drain of the first fet M1, the drain of the third fet M3, the cathode of the first unidirectional conducting assembly 014 and the power terminal of the first rf assembly 013 jointly form the first capacitor terminal PC1 of the micro energy collecting chip 01, the first input/output terminal of the first switch assembly 011 and the anode of the first unidirectional conducting assembly 014 jointly form the input power terminal of the micro energy collecting chip 01, the second input/output terminal of the first switch assembly VCC and the first input/output terminal of the second switch assembly 012 jointly form the input/output terminal of the micro energy collecting chip 01, and the second switch assembly VCC A second capacitor end PC2 forming the micro energy acquisition chip 01, a second input/output end of the second switch component 012, a drain of the fourth field effect transistor M4 and a drain of the second field effect transistor M2 together form a power ground GND of the micro energy acquisition chip 01, a source of the second field effect transistor M2 is connected with a source of the first field effect transistor M1 and a radio frequency ground of the first radio frequency component 013, and a source of the third field effect transistor M3 is connected with a source of the fourth field effect transistor M4 and a data end of the first radio frequency component 013;
the first end of the first energy storage component 02 is connected with an input power supply end VCC of the micro energy acquisition chip 01, the first end of the second energy storage component 03 is connected with a first capacitor end PC1 of the micro energy acquisition chip 01, the second end of the second energy storage component 03 is connected with a second capacitor end PC2 of the micro energy acquisition chip 01, and a power supply ground end GND of the micro energy acquisition chip 01 and the second end of the first energy storage component 02 are connected to a power supply ground in a sharing mode;
in the micro-energy harvesting chip 01, the first unidirectional conducting assembly 014 is configured to conduct the first micro-energy voltage unidirectionally; the first energy storage assembly 02 and the second energy storage assembly 03 are both configured to be charged according to the first micro-energy voltage; the second switching component 012 is configured to switch off the connection between the power ground and the second end of the second energy storing component 03 according to a second control signal; the first switching component 011 is configured to communicate a first end of the first energy storage component 02 and a second end of the second energy storage component 03 according to a first control signal, so that the first energy storage component 02 and the second energy storage component 03 are connected in series to generate a first voltage-multiplying voltage; the first rf component 013 is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from the ground, and generate a first wireless communication signal according to the first data signal and transmit the first wireless communication signal from the wireless link; the second field effect transistor M2 connects the first ground voltage to the power ground according to a third control signal; the third field effect transistor M3 and the fourth field effect transistor M4 are both configured to generate a first data signal according to a first original data signal accessed by a fourth control terminal of the micro energy collecting chip 01.
As shown in fig. 2, the micro energy collecting chip 01 is further connected to a third energy storage assembly 04; the control end A of the first switch component 011 is a third capacitor end PC3 of the micro-energy acquisition chip 01; the first end of the third energy storage assembly 04 is connected with the third capacitor end PC3 of the micro energy acquisition chip 01, and the second end of the third energy storage assembly 04 is connected with the power ground.
As shown in fig. 3, the first switch assembly 011 is a fifth fet M5; the gate of the fifth fet M5 is the control terminal of the first switch component 011, the drain of the fifth fet M5 is the first input/output terminal of the first switch component 011, and the source of the fifth fet M5 is the second input/output terminal of the first switch component 011.
The second switch element 012 is a sixth fet M6; the gate of the sixth fet M6 is the control terminal of the second switch element 012, the drain of the sixth fet M6 is the second input/output terminal of the first switch element 011, and the source of the sixth fet M6 is the second input/output terminal of the second switch element 012.
The fifth field effect transistor M5 is an enhancement field effect transistor, and the sixth field effect transistor M6 is a depletion field effect transistor. When the micro energy collection chip 01 does not operate, the first switch component 011 is turned off, and the second switch component 012 is turned on.
The first embodiment of the present application further provides a control method of the micro energy collecting chip 01 shown in fig. 1, including:
step A1: the first switch component 011 is turned off, and the second switch component 012 is connected to the power ground, so that the first energy storage component 02 charges according to the first micro-energy voltage to generate a first charging voltage, and the second energy storage component 03 charges according to the first micro-energy voltage turned on by the first unidirectional turn-on component 014 to generate a second charging voltage;
step A2: an input power supply terminal VCC of the micro energy acquisition chip 01 inputs a first micro energy voltage, and the micro energy acquisition chip 01 works according to the first micro energy voltage;
step A3: a second control signal is input through a second control end of the micro energy acquisition chip 01 to turn off the connection between a second end of the second energy storage component 03 and a power ground, a first control signal is input through a first control end of the micro energy acquisition chip 01 to control the first switch component 011 to communicate the first end of the first energy storage component 02 and the second end of the second energy storage component 03, so that the potential of the first end of the first energy storage component 02 is equal to the potential of the second end of the second energy storage component 03, and the voltage of the second end of the second energy storage component 03 is the sum of a second charging voltage and a first charging voltage to generate a first voltage doubling voltage; the first rf component 013 generates a first ground voltage according to the first voltage-doubling voltage and outputs the first ground voltage from the ground terminal; inputting a third control signal through a third control end of the micro-energy acquisition chip 01 to control the second field effect transistor M2 to connect the first ground end voltage to the power ground;
step A4: the third field-effect transistor M3 and the fourth field-effect transistor M4 are both configured to generate a first data signal according to a first original data signal accessed by a fourth control terminal of the micro energy acquisition chip 01; the first radio frequency component 013 generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from the wireless link.
Example two
Fig. 4 shows a module structure of a micro energy collection device provided in the second embodiment of the present application, and for convenience of description, only the parts related to the second embodiment of the present application are shown, which are detailed as follows:
a micro energy collecting device comprises a first energy storage component 02, a second energy storage component 03 and a micro energy collecting chip 01 according to the first embodiment.
As shown in fig. 5, the micro energy harvesting device further comprises a first rectifying assembly 05.
The first rectifying component 05 is connected with the first energy storage component 02 and the micro-energy acquisition chip 01, and is configured to generate a first micro-energy voltage according to the first micro-energy alternating current.
As shown in fig. 6, the micro energy harvesting device further includes a third energy storage assembly 04.
The third energy storage assembly 04 is connected with the micro energy acquisition chip 01 and configured to generate a third charging voltage according to the first control signal; the first switching component 011 is specifically configured to connect the first end of the first energy storage component 02 and the second end of the second energy storage component 03 according to the third charging voltage, so that the first energy storage component 02 and the second energy storage component 03 are connected in series to generate the first voltage-multiplying voltage.
The third energy storage assembly 04 generates a ramp voltage (third charging voltage) according to the pulse voltage (first control signal), so that the first switch assembly 011 works in an amplification state and then in a saturation state, the first voltage-multiplying voltage is prevented from generating a peak, and the stability of the first voltage-multiplying voltage is improved. The duration of the first voltage-multiplying voltage is extended.
As shown in fig. 7, the first energy storage assembly 02 includes a first capacitor C1, the second energy storage assembly 03 includes a second capacitor C2, and the third energy storage assembly 04 includes a third capacitor C3.
EXAMPLE III
Fig. 8 shows a module structure of the micro energy harvesting chip 10 provided in the third embodiment of the present application, and for convenience of description, only the parts related to the third embodiment of the present application are shown, which are detailed as follows:
a micro energy acquisition chip 10 is connected with a first radio frequency component 11, a first energy storage component 12 and a second energy storage component 13, wherein the micro energy acquisition chip 10 comprises a first switch component 101, a second switch component 102, a first one-way conduction component 103, a first field effect tube M1, a second field effect tube M2, a third field effect tube M3 and a fourth field effect tube M4;
wherein, the control terminal of the first switch assembly 101 is the first control terminal a of the micro energy collecting chip 10, the control terminal of the second switch assembly 102 is the second control terminal B of the micro energy collecting chip 10, the gate of the first fet M1 and the gate of the second fet M2 jointly form the third control terminal C of the micro energy collecting chip 10, the gate of the third fet M3 and the gate of the fourth fet M4 jointly form the fourth control terminal D of the micro energy collecting chip 10, the drain of the first fet M1, the drain of the third fet M3 and the negative electrode of the first unidirectional conducting assembly 103 jointly form the first capacitor terminal PC1 of the micro energy collecting chip 10, the first input/output terminal of the first switch assembly 101 and the positive electrode of the first unidirectional conducting assembly 103 jointly form the input power terminal VCC of the micro energy collecting chip 10, the second input/output terminal of the first switch assembly 101 and the first input/output terminal of the second switch assembly 102 jointly form the VCC of the micro energy collecting chip 10 A second capacitor terminal PC2, a second input/output terminal of the second switch component 102, a drain of the fourth field-effect transistor M4, and a drain of the second field-effect transistor M2 jointly form a power ground terminal GND of the micro-energy acquisition chip 10, a source of the second field-effect transistor M2 and a source of the first field-effect transistor M1 jointly form a voltage input terminal P2.0 of the micro-energy acquisition chip 10, and a source of the third field-effect transistor M3 and a source of the fourth field-effect transistor M4 jointly form a first data input/output terminal P1.0 of the micro-energy acquisition chip 10;
the first end of the first energy storage component 12 is connected with an input power supply end VCC of the micro energy acquisition chip 10, the first end of the second energy storage component 13 is connected with a power supply end of the first radio frequency component 11 and a first capacitance end PC1 of the micro energy acquisition chip 10, the second end of the second energy storage component 13 is connected with a second capacitance end PC2 of the micro energy acquisition chip 10, a data end of the first radio frequency component 11 is connected with a voltage input end P2.0 of the micro energy acquisition chip 10, a grounding end of the first radio frequency component 11 is connected with a first data input and output end P1.0 of the micro energy acquisition chip 10, and a power ground end GND of the micro energy acquisition chip 10 and the second end of the first energy storage component 12 are connected to a power ground in a sharing manner;
in the micro energy collecting chip 10, the first unidirectional conducting component 103 is configured to conduct the first micro energy voltage in a unidirectional way; the first energy storage assembly 12 and the second energy storage assembly 13 are both configured to be charged according to the first micro-energy voltage; the second switching component 102 is configured to switch off the connection between the power ground and the second end of the second energy storage component 13 according to a second control signal; the first switching component 101 is configured to communicate a first end of the first energy storage component 12 and a second end of the second energy storage component 13 according to a first control signal, so that the first energy storage component 12 and the second energy storage component 13 are connected in series to generate a first voltage-multiplying voltage; the first radio frequency component 11 is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from the ground, and generate a first wireless communication signal according to the first data signal and transmit the first wireless communication signal from the wireless link; the second field effect transistor M2 connects the first ground voltage to the power ground according to a third control signal; the third fet M3 and the fourth fet M4 are both configured to generate a first data signal according to a first original data signal accessed by the fourth control terminal of the micro energy harvesting chip 10.
As shown in fig. 9, the micro energy collecting chip 10 is further connected to a third energy storage assembly 14; the control end a of the first switch component 101 is a third capacitor end PC3 of the micro energy acquisition chip 10; a first terminal of the third energy storage assembly 14 is connected to the third capacitor terminal PC3 of the micro energy harvesting chip 10, and a second terminal of the third energy storage assembly 14 is connected to the power ground.
As shown in fig. 10, the first switch assembly 101 is a fifth fet M5; the gate of the fifth fet M5 is the control terminal of the first switch device 101, the drain of the fifth fet M5 is the first input/output terminal of the first switch device 101, and the source of the fifth fet M5 is the second input/output terminal of the first switch device 101.
The second switch assembly 102 is a sixth fet M6; the gate of the sixth fet M6 is the control terminal of the second switch device 102, the drain of the sixth fet M6 is the second input/output terminal of the first switch device 101, and the source of the sixth fet M6 is the second input/output terminal of the second switch device 102.
The fifth field effect transistor M5 is an enhancement field effect transistor, and the sixth field effect transistor M6 is a depletion field effect transistor. When the micro energy collecting chip 01 is not in operation, the first switch component 101 is turned off, and the second switch component 102 is turned on.
The third embodiment of the present application further provides a control method of the micro energy collecting chip 10 shown in fig. 6, including:
step B1: the first switch element 101 is turned off and the second switch element 102 is connected to the power ground, so that the first energy storage element 12 is charged according to the first micro energy voltage to generate a first charging voltage, and the second energy storage element 13 is charged according to the first micro energy voltage turned on by the first unidirectional conducting element 103 to generate a second charging voltage.
Step B2: the input power terminal VCC of the micro energy collecting chip 10 inputs a first micro energy voltage, and the micro energy collecting chip 10 operates according to the first micro energy voltage.
Step B3: a second control signal is input through a second control end B of the micro energy acquisition chip 10 to turn off the connection between a second end of the second energy storage component 13 and a power ground, a first control signal is input through a first control end A of the micro energy acquisition chip 10 to control the first switch component 101 to communicate the first end of the first energy storage component 12 and the second end of the second energy storage component 13, so that the potential of the first end of the first energy storage component 12 is equal to the potential of the second end of the second energy storage component 13, and the voltage of the second end of the second energy storage component 13 is the sum of a second charging voltage and a first charging voltage to generate a first voltage doubling voltage; the first rf module 11 generates a first ground voltage according to the first voltage-doubling voltage and outputs the first ground voltage from the ground terminal; and a third control signal is input through a third control end of the micro-energy acquisition chip 10 to control the second field effect transistor M2 to connect the first ground end voltage to the power ground.
Step B4: the third field-effect transistor M3 and the fourth field-effect transistor M4 are both configured to generate a first data signal according to a first original data signal accessed by a fourth control terminal of the micro energy collection chip 10; the first radio frequency assembly 11 generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from the wireless link.
In summary, in the embodiment of the present application, the first energy storage assembly 12 and the second energy storage assembly 13 are connected in series to realize double voltage bootstrap, so that the threshold for weak energy collection is reduced, and the energy utilization efficiency is improved.
Example four
Fig. 11 shows a module structure of a micro energy collection device provided in the fourth embodiment of the present application, and for convenience of description, only the parts related to the fourth embodiment of the present application are shown, which are detailed as follows:
a micro energy collecting device comprises a first energy storage component 12, a second energy storage component 13 and a micro energy collecting chip 10 according to the third embodiment.
As shown in fig. 12, the micro energy harvesting device further includes a first rectifying assembly 15.
The first rectifying component 15 is connected with the first energy storage component 12 and the micro-energy acquisition chip 10, and is configured to generate a first micro-energy voltage according to the first micro-energy alternating current.
As shown in fig. 13, the micro energy harvesting device further includes a third energy storage assembly 14.
The third energy storage assembly 14 is connected with the micro energy acquisition chip 10 and configured to generate a third charging voltage according to the first control signal; the first switching component 101 is specifically configured to connect the first end of the first energy storage component 12 and the second end of the second energy storage component 13 according to the third charging voltage, so that the first energy storage component 12 and the second energy storage component 13 are connected in series to generate the first voltage-multiplying voltage.
The third energy storage component 14 generates a ramp voltage (third charging voltage) according to the pulse voltage (first control signal), so that the first switch component 101 works in an amplification state and then works in a saturation state, a peak of the first voltage-multiplying voltage is avoided, and the stability of the first voltage-multiplying voltage is improved. The duration of the first voltage-multiplying voltage is extended.
As shown in fig. 14, the first energy storage assembly 12 includes a fourth capacitor C4, the second energy storage assembly 13 includes a fifth capacitor C5, and the third energy storage assembly 14 includes a sixth capacitor C6.
EXAMPLE five
Fig. 15 shows a module structure of the micro energy collection circuit provided in the fourth embodiment of the present application, and for convenience of description, only the parts related to the fourth embodiment of the present application are shown, which are detailed as follows:
a micro energy acquisition circuit comprises a microprocessor U1, a first radio frequency assembly 20, a first switch assembly 23, a second switch assembly 24, a first energy storage assembly 21, a second energy storage assembly 22 and a first one-way conduction assembly 25.
The first unidirectional conducting component 25 is configured to conduct the first micro-energy voltage unidirectionally; the first energy storage assembly 21 is connected with the first unidirectional conducting assembly 25 and is configured to be charged according to a first micro-energy voltage; and the second energy storage assembly 22 is connected with the first unidirectional conducting assembly 25 and is configured to be charged according to the first micro-energy voltage.
The first switching component 23 is connected with the first energy storage component 21 and the first unidirectional conducting component 25, and is configured to communicate the second energy storage component 22 and the first energy storage component 21 according to a first control signal so that the second energy storage component 22 and the first energy storage component 21 are connected in series to generate a first voltage doubling voltage;
and a second switching component 24, connected to the second energy storage component 22 and the first switching component 23, configured to turn off the connection between the second energy storage component 22 and the power ground according to a second control signal.
And a microprocessor U1 having a power supply terminal connected to the negative electrode of the first unidirectional conducting element 25 and the second energy storage element 22, a first input/output terminal connected to the first rf element 20, a second input/output terminal connected to the first rf element 20, and a ground terminal connected to the power ground in common with the first energy storage element 21 and the second switch element 24, configured to supply power according to the first micro energy voltage, and generate a third control signal to connect the first ground voltage to the power ground through the first input/output terminal, and generate a first data signal.
The first rf module 20, having a power terminal connected to the cathode of the first unidirectional conducting module 25, the microprocessor U1 and the second energy storage module 22, a data terminal connected to the microprocessor U1, and a ground terminal connected to the microprocessor U1, is configured to generate a first ground voltage according to the first voltage doubling voltage and output the first ground voltage from the ground terminal, and generate a first wireless communication signal according to the first data signal and transmit the first wireless communication signal from the wireless link.
As shown in fig. 16, the micro energy harvesting circuit further includes a second unidirectional conducting component 26.
The second unidirectional conducting component 26 is connected to the power ground, the second energy storage component 22, the first switching component 23, and the second switching component 24, and is configured to conduct the first ground voltage unidirectionally.
As shown in fig. 17, the micro energy harvesting circuit further comprises a third energy storage component 27.
The third energy storage component 27 is connected to the power ground and the first switch component 23, and configured to generate a third charging voltage according to the first control signal; the first switching component 23 is specifically configured to connect the second energy storage component 22 and the first energy storage component 21 according to the third charging voltage, so that the second energy storage component 22 and the first energy storage component 21 are connected in series to generate the first voltage-multiplying voltage.
The third energy storage component 27 generates a ramp voltage (third charging voltage) according to the pulse voltage (first control signal), so that the first switching component 23 works in an amplification state and then works in a saturation state, the spike of the first voltage-multiplying voltage is avoided, the stability of the first voltage-multiplying voltage is improved, and the duration of the first voltage-multiplying voltage is prolonged.
As shown in fig. 18, the micro energy harvesting circuit further includes a first rectifying component 28.
The first rectifying component 28 is connected to the first energy storage component 21, the first switching component 23 and the first unidirectional conducting component 25, and configured to generate a first micro-energy voltage according to the first micro-energy alternating current.
As shown in fig. 19, the first energy storage assembly 21 includes a seventh capacitor C7, the second energy storage assembly 22 includes an eighth capacitor C8, the ninth energy storage assembly 27 includes a ninth capacitor C9, the first unidirectional conducting assembly 25 includes a third diode D3, and the second unidirectional conducting assembly 26 includes a fourth diode D4. The first switching assembly 23 includes a fifth fet M5; the second switching assembly 24 includes a sixth fet M6.
The fifth field effect transistor M5 is an enhancement field effect transistor, and the sixth field effect transistor M6 is a depletion field effect transistor.
It should be noted that the voltage-time variation graph of the conventional micro energy collecting device is shown in fig. 20(a), the voltage-time variation graph of the micro energy collecting circuit shown in fig. 15 is shown in fig. 20(b), and the voltage-time variation graph of the micro energy collecting circuit shown in fig. 17 is shown in fig. 20(c), and it can be found that the operating time of the micro energy collecting circuit shown in fig. 15 is longer than that of the conventional micro energy collecting device, and the operating time of the micro energy collecting circuit shown in fig. 17 is longer than that of the micro energy collecting circuit shown in fig. 15.
Fifth, an embodiment of the present application further provides a method for controlling a micro energy collection circuit shown in fig. 11, where the method includes:
step C1: the first switch component 23 is turned off, and the second switch component 24 is connected to the power ground, so that the second energy storage component 22 is charged according to the first micro energy voltage to generate a second charging voltage, and the first energy storage component 21 is charged according to the first micro energy voltage to generate a first charging voltage;
step C2: a power supply end of the microprocessor U1 inputs a first micro energy voltage, and the microprocessor U1 works according to the first micro energy voltage;
step C3: a second control signal is input through the control end of the second switch component 24 to turn off the connection between the second energy storage component 22 and the power ground, a first control signal is input through the control end of the first switch component 23 to communicate the second energy storage component 22 and the first energy storage component 21, so that the second energy storage component 22 and the first energy storage component 21 are connected in series, and the voltage of the first end of the second energy storage component 22 is the sum of the first charging voltage and the second charging voltage to generate a first voltage doubling voltage;
the first rf module 20 generates a first ground voltage according to the first voltage-doubling voltage and outputs the first ground voltage from the ground terminal; generating a third control signal by the microprocessor U1 to connect the first ground voltage to the power ground via the first input/output terminal of the microprocessor U1;
step C4: microprocessor U1 generates a first data signal; the first radio frequency assembly 20 generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from the wireless link.
The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.
Claims (21)
1. A micro energy acquisition chip is characterized in that the micro energy acquisition chip is connected with a first energy storage assembly and a second energy storage assembly, and comprises a first switch assembly, a second switch assembly, a first radio frequency assembly, a first one-way conduction assembly, a first field effect tube, a second field effect tube, a third field effect tube and a fourth field effect tube;
the control end of the first switch component is the first control end of the micro energy collecting chip, the control end of the second switch component is the second control end of the micro energy collecting chip, the grid of the first field effect tube and the grid of the second field effect tube jointly form the third control end of the micro energy collecting chip, the grid of the third field effect tube and the grid of the fourth field effect tube jointly form the fourth control end of the micro energy collecting chip, the drain of the first field effect tube, the drain of the third field effect tube, the cathode of the first one-way conduction component and the power end of the first radio frequency component jointly form the first capacitor end of the micro energy collecting chip, the first input and output end of the first switch component and the anode of the first one-way conduction component jointly form the input power end of the micro energy collecting chip, the second input/output end of the first switch component and the first input/output end of the second switch component jointly form a second capacitor end of the micro energy acquisition chip, the second input/output end of the second switch component, the drain electrode of the fourth field effect transistor and the drain electrode of the second field effect transistor jointly form a power ground end of the micro energy acquisition chip, the source electrode of the second field effect transistor is connected with the source electrode of the first field effect transistor and the radio frequency ground end of the first radio frequency component, and the source electrode of the third field effect transistor is connected with the source electrode of the fourth field effect transistor and the data end of the first radio frequency component;
the first end of the first energy storage assembly is connected with the input power end of the micro energy acquisition chip, the first end of the second energy storage assembly is connected with the first capacitor end of the micro energy acquisition chip, the second end of the second energy storage assembly is connected with the second capacitor end of the micro energy acquisition chip, and the power ground end of the micro energy acquisition chip and the second end of the first energy storage assembly are connected to a power ground in a shared mode;
the first unidirectional conducting component is configured to conduct a first micro-energy voltage in a unidirectional way; the first energy storage assembly and the second energy storage assembly are both configured to be charged according to the first micro-energy voltage; the second switch component is configured to switch off the connection between a power ground and the second end of the second energy storage component according to a second control signal; the first switch component is configured to communicate a first end of the first energy storage component with a second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage-multiplying voltage; the first radio frequency component is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from a ground, and generate a first wireless communication signal according to a first data signal and transmit the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to a power ground according to a third control signal; the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip.
2. The micro energy harvesting chip of claim 1, wherein the micro energy harvesting chip is further connected to a third energy storage component;
the control end of the first switch component is a third capacitor end of the micro-energy acquisition chip;
the first end of the third energy storage assembly is connected with the third capacitor end of the micro-energy acquisition chip, and the second end of the third energy storage assembly is connected with a power ground.
3. The micro energy harvesting chip of claim 1, wherein the first switching component is a fifth field effect transistor;
the grid electrode of the fifth field effect transistor is the control end of the first switch component, the drain electrode of the fifth field effect transistor is the first input and output end of the first switch component, and the source electrode of the fifth field effect transistor is the second input and output end of the first switch component.
4. The micro energy harvesting chip of claim 1, wherein the second switching component is a sixth field effect transistor;
the grid electrode of the sixth field effect transistor is the control end of the second switch component, the drain electrode of the sixth field effect transistor is the second input and output end of the first switch component, and the source electrode of the sixth field effect transistor is the second input and output end of the second switch component.
5. A method for controlling the micro energy harvesting chip of claim 1, comprising:
step A1: the first switch assembly is turned off, and the second switch assembly is communicated to a power ground, so that the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage, and the second energy storage assembly is charged according to the first micro-energy voltage conducted by the first unidirectional conduction assembly to generate a second charging voltage;
step A2: the input power end of the micro-energy acquisition chip inputs a first micro-energy voltage, and the micro-energy acquisition chip works according to the first micro-energy voltage;
step A3: a second control signal is input through the second control end of the micro energy acquisition chip to turn off the connection between the second end of the second energy storage component and a power ground, a first control signal is input through the first control end of the micro energy acquisition chip to control the first switch component to communicate the first end of the first energy storage component and the second end of the second energy storage component, so that the potential of the first end of the first energy storage component is equal to the potential of the second end of the second energy storage component, and the voltage of the second end of the second energy storage component is the sum of the second charging voltage and the first charging voltage to generate the first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; inputting a third control signal through a third control end of the micro-energy acquisition chip to control the second field effect transistor to communicate the first ground voltage to a power ground;
step A4: the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
6. A micro energy collecting device, characterized by comprising a first energy storage component, a second energy storage component and a micro energy collecting chip according to any one of claims 1 to 4.
7. The micro energy harvesting device of claim 6, further comprising:
and the first rectifying component is connected with the first energy storage component and the micro energy acquisition chip and is configured to generate the first micro energy voltage according to first micro energy alternating current.
8. The micro energy harvesting device of claim 6, further comprising:
the third energy storage assembly is connected with the micro energy acquisition chip and configured to generate the third charging voltage according to a first control signal;
the first switch component is specifically configured to connect the first end of the first energy storage component and the second end of the second energy storage component in series according to a third charging voltage so as to enable the first energy storage component and the second energy storage component to generate a first voltage doubling voltage.
9. A micro energy acquisition chip is characterized in that the micro energy acquisition chip is connected with a first radio frequency assembly, a first energy storage assembly and a second energy storage assembly, and comprises a first switch assembly, a second switch assembly, a first one-way conduction assembly, a first field effect tube, a second field effect tube, a third field effect tube and a fourth field effect tube;
the control end of the first switch component is a first control end of the micro energy acquisition chip, the control end of the second switch component is a second control end of the micro energy acquisition chip, the grid electrode of the first field effect tube and the grid electrode of the second field effect tube jointly form a third control end of the micro energy acquisition chip, the grid electrode of the third field effect tube and the grid electrode of the fourth field effect tube jointly form a fourth control end of the micro energy acquisition chip, the drain electrode of the first field effect tube, the drain electrode of the third field effect tube and the negative electrode of the first one-way conduction component jointly form a first capacitor end of the micro energy acquisition chip, the first input and output end of the first switch component and the positive electrode of the first one-way conduction component jointly form an input power supply end of the micro energy acquisition chip, and the second input and output end of the first switch component and the first input and output end of the second switch component jointly form a second control end of the micro energy acquisition chip The second capacitor end of the micro energy acquisition chip, the second input/output end of the second switch component, the drain electrode of the fourth field effect transistor and the drain electrode of the second field effect transistor jointly form a power ground end of the micro energy acquisition chip, the source electrode of the second field effect transistor and the source electrode of the first field effect transistor jointly form a voltage input end of the micro energy acquisition chip, and the source electrode of the third field effect transistor and the source electrode of the fourth field effect transistor jointly form a first data input/output end of the micro energy acquisition chip;
the first end of the first energy storage component is connected with the input power end of the micro energy acquisition chip, the first end of the second energy storage component is connected with the power end of the first radio frequency component and the first capacitor end of the micro energy acquisition chip, the second end of the second energy storage component is connected with the second capacitor end of the micro energy acquisition chip, the data end of the first radio frequency component is connected with the voltage input end of the micro energy acquisition chip, the grounding end of the first radio frequency component is connected with the first data input and output end of the micro energy acquisition chip, and the power ground end of the micro energy acquisition chip and the second end of the first energy storage component are connected to a power ground in common;
the first unidirectional conducting component is configured to conduct a first micro-energy voltage in a unidirectional way; the first energy storage assembly and the second energy storage assembly are both configured to be charged according to the first micro-energy voltage; the second switch component is configured to switch off the connection between a power ground and the second end of the second energy storage component according to a second control signal; the first switch component is configured to communicate a first end of the first energy storage component with a second end of the second energy storage component according to a first control signal so that the first energy storage component and the second energy storage component are connected in series to generate a first voltage-multiplying voltage; the first radio frequency component is configured to generate a first ground voltage according to the first voltage-multiplying voltage and output the first ground voltage from a ground, and generate a first wireless communication signal according to a first data signal and transmit the first wireless communication signal from a wireless link; the second field effect transistor is used for connecting the first ground end voltage to a power ground according to a third control signal; the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip.
10. The micro energy harvesting chip of claim 9, wherein the micro energy harvesting chip is further connected to a third energy storage component;
the control end of the first switch component is a third capacitor end of the micro-energy acquisition chip;
the first end of the third energy storage assembly is connected with the third capacitor end of the micro-energy acquisition chip, and the second end of the third energy storage assembly is connected with a power ground.
11. The micro energy harvesting chip of claim 9, wherein the first switching component is a fifth field effect transistor;
the grid electrode of the fifth field effect transistor is the control end of the first switch component, the drain electrode of the fifth field effect transistor is the first input and output end of the first switch component, and the source electrode of the fifth field effect transistor is the second input and output end of the first switch component.
12. The micro energy harvesting chip of claim 9, wherein the second switching component is a sixth field effect transistor;
the grid electrode of the sixth field effect transistor is the control end of the second switch component, the drain electrode of the sixth field effect transistor is the second input and output end of the first switch component, and the source electrode of the sixth field effect transistor is the second input and output end of the second switch component.
13. A method for controlling the micro energy harvesting chip of claim 9, comprising:
step B1: the first switch assembly is turned off, and the second switch assembly is communicated to a power ground, so that the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage, and the second energy storage assembly is charged according to the first micro-energy voltage conducted by the first unidirectional conduction assembly to generate a second charging voltage;
step B2: the input power end of the micro-energy acquisition chip inputs a first micro-energy voltage, and the micro-energy acquisition chip works according to the first micro-energy voltage;
step B3: a second control signal is input through the second control end of the micro energy acquisition chip to turn off the connection between the second end of the second energy storage component and a power ground, a first control signal is input through the first control end of the micro energy acquisition chip to control the first switch component to communicate the first end of the first energy storage component and the second end of the second energy storage component, so that the potential of the first end of the first energy storage component is equal to the potential of the second end of the second energy storage component, and the voltage of the second end of the second energy storage component is the sum of the second charging voltage and the first charging voltage to generate the first voltage doubling voltage; the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; inputting a third control signal through a third control end of the micro-energy acquisition chip to control the second field effect transistor to communicate the first ground voltage to a power ground;
step B4: the third field effect transistor and the fourth field effect transistor are both configured to generate the first data signal according to a first original data signal accessed by a fourth control end of the micro energy collecting chip; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
14. A micro energy harvesting device comprising a third energy storage component, a second energy storage component and a micro energy harvesting chip according to any one of claims 9 to 12.
15. The micro energy harvesting device of claim 14, further comprising:
and the first rectifying component is connected with the first energy storage component and the micro energy acquisition chip and is configured to generate the first micro energy voltage according to first micro energy alternating current.
16. The micro energy harvesting device of claim 14, further comprising:
the third energy storage assembly is connected with the micro energy acquisition chip and configured to generate the third charging voltage according to a first control signal;
the first switch component is specifically configured to connect the first end of the first energy storage component and the second end of the second energy storage component in series according to a third charging voltage so as to enable the first energy storage component and the second energy storage component to generate a first voltage doubling voltage.
17. The micro-energy acquisition circuit is characterized by comprising a microprocessor, a first radio frequency assembly, a first switch assembly, a second switch assembly, a first energy storage assembly, a second energy storage assembly and a first one-way conduction assembly;
the first unidirectional conducting component is configured to conduct the first micro-energy voltage in a unidirectional way;
the first energy storage assembly is connected with the first unidirectional conduction assembly and is configured to be charged according to the first micro-energy voltage;
the second energy storage assembly is connected with the first unidirectional conduction assembly and is configured to be charged according to the first micro-energy voltage;
the first switch component is connected with the first energy storage component and the first unidirectional conducting component and is configured to be communicated with the second energy storage component and the first energy storage component according to a first control signal so that the second energy storage component and the first energy storage component are connected in series to generate a first voltage doubling voltage;
the second switch assembly is connected with the second energy storage assembly and the first switch assembly and is configured to turn off the connection between the second energy storage assembly and a power ground according to a second control signal;
the microprocessor is provided with a power supply end connected with the negative electrode of the first unidirectional conducting component and the second energy storage component, a first input-output end connected with the first radio frequency component, a second input-output end connected with the first radio frequency component, and a ground end which is commonly connected with the first energy storage component and the second switch component and is used for supplying power according to the first micro-energy voltage and generating a third control signal so that the first ground end voltage is communicated to the power ground through the first input-output end and a first data signal is generated;
the first radio frequency component is provided with a negative electrode connected with the first unidirectional conducting component, a power end connected with the microprocessor and the second energy storage component, a data end connected with the microprocessor and a ground end connected with the microprocessor, and is configured to generate the first ground end voltage according to the first voltage doubling voltage and output the first ground end voltage from the ground end, generate a first wireless communication signal according to the first data signal and send the first wireless communication signal from a wireless link.
18. The micro energy harvesting circuit of claim 17, further comprising:
and the second unidirectional conduction assembly is connected with a power ground, the second energy storage assembly, the first switch assembly and the second switch assembly and is configured to conduct the voltage of the first ground terminal in a unidirectional mode.
19. The micro energy harvesting circuit of claim 17, further comprising:
a third energy storage component connected with a power ground and the first switch component and configured to generate a third charging voltage according to the first control signal;
the first switch assembly is specifically configured to communicate the second energy storage assembly and the first energy storage assembly according to the third charging voltage so that the second energy storage assembly and the first energy storage assembly are connected in series to generate a first voltage-multiplying voltage.
20. The micro energy harvesting circuit of claim 17, further comprising:
the first rectifying assembly is connected with the first energy storage assembly, the first switch assembly and the first one-way conduction assembly and configured to generate the first micro-energy voltage according to first micro-energy alternating current.
21. A method of controlling the micro energy collection circuit according to claim 17, comprising:
step C1: the first switch assembly is turned off, the second switch assembly is communicated to a power ground, so that the second energy storage assembly is charged according to the first micro-energy voltage to generate a second charging voltage, and the first energy storage assembly is charged according to the first micro-energy voltage to generate a first charging voltage;
step C2: a power supply end of the microprocessor inputs a first micro-energy voltage, and the microprocessor works according to the first micro-energy voltage;
step C3: a second control signal is input through the control end of the second switch assembly to turn off the connection between the second energy storage assembly and a power ground, a first control signal is input through the control end of the first switch assembly to communicate the second energy storage assembly and the first energy storage assembly, so that the second energy storage assembly and the first energy storage assembly are connected in series, and the voltage of the first end of the second energy storage assembly is the sum of the first charging voltage and the second charging voltage to generate a first voltage doubling voltage;
the first radio frequency component generates a first ground voltage according to the first voltage doubling voltage and outputs the first ground voltage from a ground terminal; generating the third control signal through the microprocessor to connect the first ground voltage to a power ground through a first input/output end of the microprocessor;
step C4: the microprocessor generating the first data signal; the first radio frequency component generates a first wireless communication signal from the first data signal and transmits the first wireless communication signal from a wireless link.
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