CN203522703U - Large power memristor - Google Patents
Large power memristor Download PDFInfo
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- CN203522703U CN203522703U CN201320575257.0U CN201320575257U CN203522703U CN 203522703 U CN203522703 U CN 203522703U CN 201320575257 U CN201320575257 U CN 201320575257U CN 203522703 U CN203522703 U CN 203522703U
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- input
- voltage
- memristor
- voltage source
- controller
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Abstract
The utility model provides a large power memristor comprising a controlled voltage source, a controller, a voltage sampler, a current sampler and a resistor; according to input AC voltage collected by the voltage sampler and input current collected by the current sampler, the controller can generate a corresponding control signal so as to adjust output voltage of the controlled voltage source, so the input voltage and the input current can comply with voltage-current relation of the memristor. The large power memristor employs an inversion circuit to realize the controlled voltage source; the features are that: first, the control signal can be designed according to the needs of application places, a PWM mode is employed to control the output voltage of the inverter, thereby realizing the memristor with different work performances; second, the power of the memristor can be decided by a rated power of the inversion circuit, so the memristors with different power levels can be realized through designing work parameters of the inversion circuit, thereby providing references for real application of the memristor in various power occasions.
Description
Technical field
The utility model relates to memristor technical field, is specifically related to a kind of high-power memristor.
Background technology
1971, the few Chinese bush cherry of American scientist Cai proposed the 4th kind of basic passive electric circuit element except resistance, electric capacity, inductance, and by its called after memristor, but fail to produce the memristor that meets its physical definition always.Until 2008, Hewlett-Packard utilizes TiO
2thin-film material is successfully produced lotus control type memristor (referring to document [1]: D.B.Strukov, G.S.Snider, D.R.Stewart, and R.S.Williams, " The missing memristor found ", Nature, 2008 (453), pp.80 – 83), confirmed the existence of memristor.But Hewlett-Packard's memristor is made by Nanometer Semiconductor Films material, and yardstick is very little, mainly, as computer storage, can not be applied to electronic circuit.And the memristor circuit model of building with computing circuit, as document [2] (B.Muthuswamy, " Implementing Memristor based Chaotic Circuits ", International Journal of Bifurcation and Chaos, 2010, 20 (5), pp.1335 – 1350) a kind of memristor model of the AD633 of application multiplier chip has been proposed, its power is subject to multiplier, the restriction of the computing circuit operating voltages such as operational amplifier, can only be applicable to the small-power occasion of milliwatt level, seriously limited the application of memristor in various power occasions.
Utility model content
The lower situation of memristor circuit model power grade for present stage, a kind of high-power memristor that the utility model provides, the control signal specifically producing with controller is controlled the output voltage of controlled voltage source, makes input ac voltage and input current meet the definition of memristor.Controlled voltage source adopts voltage type PWM inverter circuit, has operating characteristic adjustable feature flexibly, and the power of memristor determines by inverter circuit, therefore the utility model can be realized the memristor of different capacity grade.
The purpose of this utility model is achieved through the following technical solutions.
A high-power memristor, it comprises controlled voltage source, controller, voltage sample device, current sampler and resistance and input ac voltage source; The one end in input ac voltage source is connected with one end of resistance, and the other end of resistance is connected with the positive output end of controlled voltage source, and the negative output terminal N of controlled voltage source is connected with the other end in input ac voltage source; The input voltage v in the input sampling input ac voltage source of voltage sample device
in, the output of voltage sample device is connected with the first signal input of controller; The input current in the input sampling input ac voltage source of current sampler, the output of current sampler is connected with the secondary signal input of controller; Controller is processed voltage, the current signal of input, and the control signal of generation is from the output end output of controller; The output of controller is connected with the control signal input of controlled voltage source, and controlled voltage source produces voltage according to the control signal of control signal input input between positive output end end and negative output terminal end.
In the control method of above-mentioned high-power memristor, the input current that the input ac voltage that controller gathers according to voltage sample device and current sampler gather, produces control signal, regulates the output voltage of controlled voltage source, makes input ac voltage v
inwith input current i
inbetween meet the voltage-current relationship of memristor; By selecting the controlled source of different capacity capacity, realize the memristor of different capacity grade; Controlled source is realized by voltage source type inverter, and inverter circuit adopts PWM control mode; By controller is set, make the value of leading of recalling of described high-power memristor be,
V in formula
infor input voltage, i
infor input current, R is the resistance of resistance (5), G
rwith λ be the constant that controller (2) algorithm is set, φ is magnetic flux,
The resistance of recalling of described high-power memristor is
M in formula
rwith μ be the constant that controller (2) algorithm is set, q is magnetic flux, M
0=M
rr, β=μ R.
Described controller of the present utility model comprises more than one in integrator, adder, multiplier; Controlled voltage source consists of PWM inverter circuit, its basic functional principle is that control signal is converted into pulse width modulating signal, be used for driving the switching tube in inverter, then the output waveform of inverter is through a low pass filter, after filtering high order harmonic component, can obtain output voltage similar to control signal and that amplified, make input current i
inwith input voltage v
inbetween relation meet the definition of memristor.
Compared with prior art, the utlity model has following advantage and technique effect: a kind of powerful memristor and control method thereof that the utility model provides, the definition of resulting input voltage input current relation and memristor is in full accord, can also be according to the needs of application scenario, by adjusting the algorithm of controller, the type and the parameter that can flexible realize memristor, and the memristor power that the utility model is realized determines by controlled voltage source, therefore can select the controlled voltage source of different capacity grade to adapt to different power applications.
Accompanying drawing explanation
The circuit model that Fig. 1 is the memristor that provides in execution mode.
Fig. 2 is the memristor simulating schematic diagram in execution mode.
Fig. 3 is the control signal of execution mode middle controller output and the simulation waveform figure of controlled voltage source output voltage.
Fig. 4 is the input voltage of memristor in execution mode and the simulation waveform figure of input current.
Fig. 5 is the oscillogram in kind of input voltage and the input current of memristor in execution mode.
Embodiment
Below in conjunction with accompanying drawing and example, concrete enforcement of the present utility model is described further, but enforcement of the present utility model and protection are not limited to this.
The basic principle of the high-power memristor of the utility model is with the modulation signal that controller generates, controlled voltage source to be controlled, and makes the input voltage v of circuit
inwith input current i
inbetween meet the definition of magnetic control or lotus control type memristor, whole circuit is equivalent to a memristor.
As Fig. 1, the circuit of high-power memristor formation comprises controlled voltage source 1, controller 2, voltage sample device 3, current sampler 4 and resistance R 5 and input ac voltage source 6.The A end in input ac voltage source 6 is connected with one end of resistance R 5, and the other end of resistance R 5 is connected with the positive output end P of controlled voltage source 1, and the negative output terminal N of controlled voltage source 1 is connected with the B in input ac voltage source 6 end; The input voltage v in the input Si sampling input ac voltage source 6 of voltage sample device 3
in, the output So of voltage sample device 3 is connected with the signal input part D1 of controller 2; The input current i in the input Ci sampling input ac voltage source 6 of current sampler 4
in, the output Co of current sampler 4 is connected with the signal input part D2 of controller 2,2 couples of v of controller
so, v
cosignal carries out after a series of mathematical operation, and its signal is in the output of D3 end, and D3 end is connected with the controlled signal input VC of controlled voltage source 1, and controlled voltage source 1 is according to the output signal v of controller 2
d3at P, N end, produce output voltage v
f.
As shown in Figure 1, voltage sample device 3 and current sampler 4 are respectively to input voltage signal v
inwith input current signal i
ingather, it exports v
so, v
cobe input to controller 2, according to the definition of the quantity of electric charge and Faraday's electromagnetic induction law, current signal carried out to integration and can obtain equivalently quantity of electric charge q, voltage signal is carried out to integration can obtain magnetic flux equivalently,
k
vφ=∫v
Sodt=k
v·∫v
indt, (1)
k
iq=∫v
Codt=k
i·∫i
indt, (2)
Wherein, k
v, k
ibe respectively the sampling coefficient of voltage, electric current.
If build previously described magnet controlled memristor, output signal that can CONTROLLER DESIGN 2 is
v
D3=k
Dv
in-k
Dv
in(G
R+λ·φ), (3)
K wherein
d, G
rbe with λ the constant that in controller 2, algorithm is set.
v
F=k
F·v
D3=k
F[k
Dv
in-k
Dv
in(G
R+λ·φ)], (4)
v
F=v
in-v
in(G
R+λ·φ), (5)
Thereby the voltage swing obtaining in resistance R is
v
R=v
in-v
F=v
in(G
R+λ·φ), (6)
In resistance R, built thus a flux-controlled voltage source, now the size of input current is
The input current voltage relationship of utility model circuit is
G in formula
0=G
r/ R, α=λ/R.Obviously formula (8) meets the magnet controlled expression formula of recalling the value of leading, has proved the correctness of the utility model circuit.
If build lotus control type memristor, output signal that can CONTROLLER DESIGN (2) is
K wherein
d, M
rbe with μ the constant of setting in controller (2) algorithm.
Establish equally the amplification coefficient of controlled voltage source (1)
the output voltage of controlled voltage source (1) is
The pass that finally can obtain between input voltage and input current is
M in formula
0=RM
r, β=R μ.Obviously formula (11) meets the expression formula that lotus control type is recalled resistance, has proved the correctness of the utility model circuit.
Fig. 2 is the simulating schematic diagram of a kind of high-power magnet controlled memristor under PSIM environment.Wherein VSEN1 is voltage sample device 3, and sampling coefficient is k
d; Integrator B1(integral constant is λ), adder SUMP1, direct current biasing source VDC1(produce direct voltage V
dC1), multiplier MULT1, adder SUMP2 formed the mathematical operation circuit of controller 2, it is output as
v
D3=k
Dv
in+k
Dv
in(V
DC1+λ·φ), (12)
Half-bridge converter, LC filter, load R
fformed the main circuit of controlled voltage source 1 with direct voltage source VDC2.The output signal v of controller 2
d3as modulating wave, be input to comparator C OMP1, the high frequency triangular carrier that triangular-wave generator VTRI1 produces is also input to comparator C OMP1, and the pwm signal that comparator C OMP1 produces is controlled the turn-on and turn-off of switching tube in half-bridge converter after drive amplification.
In the situation that modulation degree is less than 1, the output signal of controlled voltage source 1 through filtered size is
v
F=k
F·v
D3=k
F[k
Dv
in+k
Dv
in(V
DC1+λ·φ)], (13)
Multiplication factor in formula
v
dC2for the voltage of direct voltage source VDC2, V
triamplitude for triangular carrier.
If input ac voltage v
infor 100V/50Hz, k
d=0.01, λ=100, V
dC1=-2V, triangular carrier is 1V/10kHz, V
dC2=100V, R=100 Ω, inverter output inductor is L
f=4.8mH, filter capacitor is C
f=6.8uF, resulting recall lead value expression and be
V
fwith v
d3waveform as shown in Figure 3, the output voltage v of visible controlled voltage source (inverter circuit)
ffor v
d3100 times; The input voltage v of simulation model
inwith input current i
inas shown in Figure 4, the relation between them and the definition of magnet controlled memristor are in full accord for waveform.
The circuit in kind of building according to the simulation parameter of Fig. 2, input voltage v
inwith input current i
inwaveform as shown in Figure 5, input current i wherein
inrange be 1A/div, input voltage v
inrange be 50V/div, experimental waveform is also in full accord with the ideal waveform of magnet controlled memristor, more than circuit gross power reaches 100W, has verified feasibility and the correctness of the utility model circuit.
Claims (3)
1. a high-power memristor, is characterized in that comprising controlled voltage source (1), controller (2), voltage sample device (3), current sampler (4) and resistance
rand input ac voltage source (6) (5); One end (A) and the resistance in input ac voltage source (6)
r(5) one end connects, resistance
r(5) the other end is connected with the positive output end (P) of controlled voltage source (1), and the negative output terminal (N) of controlled voltage source (1) is connected with the other end (B) of input ac voltage source (6); The input voltage in input (Si) the sampling input ac voltage source (6) of voltage sample device (3)
v in, the output (So) of voltage sample device (3) is connected with the first signal input (D1) of controller (2); The input current in input (Ci) the sampling input ac voltage source (6) of current sampler (4) (
i in ), the output (Co) of current sampler (4) is connected with the secondary signal input (D2) of controller (2); Controller (2) is processed voltage, the current signal of input, and the control signal of generation is from output (D3) the end output of controller (2); The output (D3) of controller (2) is connected with the control signal input (VC) of controlled voltage source (1), controlled voltage source (1) according to the control signal of control signal input (VC) input between positive output end (P) and negative output terminal (N), produce voltage (
v f ).
2. a kind of high-power memristor according to claim 1, is characterized in that described controlled voltage source (1) consists of PWM inverter circuit.
3. a kind of high-power memristor according to claim 1, is characterized in that described controller comprises more than one in integrator, adder, multiplier.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103490761A (en) * | 2013-09-16 | 2014-01-01 | 华南理工大学 | High-power memristor and control method thereof |
CN106067792A (en) * | 2016-07-04 | 2016-11-02 | 华南理工大学 | High-power fractional order electric capacity and the control method thereof that a kind of exponent number is more than 1 |
CN106411291A (en) * | 2016-07-31 | 2017-02-15 | 华南理工大学 | High-power adjustable high-frequency fractional order capacitor of which order is greater than 1 and control method thereof |
CN109359400A (en) * | 2018-10-25 | 2019-02-19 | 江西理工大学 | A kind of double magnetic control memristor Model Digitization circuit design methods of the isomery based on DSP Builder |
-
2013
- 2013-09-16 CN CN201320575257.0U patent/CN203522703U/en not_active Expired - Fee Related
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103490761A (en) * | 2013-09-16 | 2014-01-01 | 华南理工大学 | High-power memristor and control method thereof |
CN103490761B (en) * | 2013-09-16 | 2016-10-05 | 华南理工大学 | A kind of high-power memristor and control method thereof |
CN106067792A (en) * | 2016-07-04 | 2016-11-02 | 华南理工大学 | High-power fractional order electric capacity and the control method thereof that a kind of exponent number is more than 1 |
CN106067792B (en) * | 2016-07-04 | 2023-05-23 | 华南理工大学 | High-power fractional order capacitor with order larger than 1 and control method thereof |
CN106411291A (en) * | 2016-07-31 | 2017-02-15 | 华南理工大学 | High-power adjustable high-frequency fractional order capacitor of which order is greater than 1 and control method thereof |
CN106411291B (en) * | 2016-07-31 | 2023-04-07 | 华南理工大学 | High-power adjustable high-frequency fractional order capacitor with order greater than 1 and control method thereof |
CN109359400A (en) * | 2018-10-25 | 2019-02-19 | 江西理工大学 | A kind of double magnetic control memristor Model Digitization circuit design methods of the isomery based on DSP Builder |
CN109359400B (en) * | 2018-10-25 | 2023-08-15 | 江西理工大学 | Digital circuit design method of heterogeneous double-magnetic control memristor model based on DSP Builder |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20140402 Termination date: 20170916 |
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CF01 | Termination of patent right due to non-payment of annual fee |