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Lidan Wang 1,2 and Shukai Duan 1

Recommended by Chuandong Li

1, School of Electronic and Information Engineering, Southwest University, Chongqing 400715, China
2, College of Computer Science, Chongqing University, Chongqing 400044, China

Received 21 September 2012; Accepted 13 October 2012

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

The memristor, characterized by a relation of the type f ( [straight phi] ,q ) =0 , is a nanometer-scale circuit element postulated by Chua in 1971 [ 1] on the basis of the conceptual symmetry between the resistor, inductor, and capacitor. After 37 years a team at HP Labs announced [ 2] the first physical realization of a memristor and a mathematical model accounting for its behavior. This missing memristor is a new nanometer-size two-terminal circuit element characterized by a relationship between charge and flux. The resistance of memristor is proportional to the amount of charge that has passed through it. So, in a way, it possesses memory, which has caused tremendously increased interests. Recently many researchers worked actively on the memristor models and possible applications of the device [ 3]. For interpreting and understanding the principle and structure of memristor, people discuss theoretical models from different angles.

Theoretical design and circuitry implementation of various chaotic generators by simple electronic circuits have been a key subject of nonlinear science [ 4]. To enhance degree of chaos, a nonlinear part in a chaotic circuit, which is frequently implemented by operational amplifiers, becomes more and more complex. Considering the nanoscopic scale size and the nonlinear characteristics of memristor, more rich chaotic behaviors should be generated if replacing the nonlinear circuit with memristor. Itoh and Chua [ 5] initially derive several nonlinear oscillators from Chua's oscillators by replacing Chua's diodes with memristors. Recently a lot of papers on memristive chaotic circuit have been reported [ 6- 10]. Because of its small size and nonlinearity, memristor is very suitable for chaotic oscillators [ 11]. In this paper, a delayed system utilizing T_i O₂ memristors as nonlinear function is proposed to generate chaotic signals.

2. T_i O ₂ Memristor with Linear Dopant Drift

In HP's memristor, a titanium dioxide (T_i O₂ ) layer and an oxygen-poor titanium dioxide (T_i O_2-x ) layer are sandwiched between two platinum electrodes, shown as Figure 1. Let D be the physical length of the memristor, _{μ V} =1 ^{0 -14 m 2 s -1 V -1} is the dopant mobility, _{R ON} and _{R OFF} are the low resistance and higher resistance areas, respectively. The electrical characteristics of the memristor with linear dopant drift from [ 1] are given by ( 2.1): [figure omitted; refer to PDF] where ω (t ) is the width of dopant region bounded between zero and D , which its derivative is [figure omitted; refer to PDF]

Structure (a) and symbol (b) of T_i O₂ memristor.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

According to the Bernoulli dynamics, we can derive the relation between the charge and magnetic flux as follows [ 5]: [figure omitted; refer to PDF] where [figure omitted; refer to PDF]

k is a constant k = ( _{R ON} - _{R OFF} ) _{μ V R ON} / ^{D 2} , and _{ω 0} and M (0 ) are the initial conditions of ω (t ) and M (t ) , respectively. The resistance of memristor is [figure omitted; refer to PDF] Figure 2shows the characteristics of memristor when parameters are chosen by _{R ON} =100 ohm , _{R OFF} =20 k ohm , _{M 0} =10 k ohm , and D =10 nm . There is an obvious turning point at _{C 4} in q - [straight phi] curve.

The M - [straight phi] and q - [straight phi] characteristics of memristor.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

3. The Memristive Delayed System

In this section, we design a delayed chaotic system with memristors, which is described by the following first-order delay differential equation: [figure omitted; refer to PDF]

where τ is a delay time, a , b , and c are system parameters, and F [ ] is a nonlinear function composed by three memristors.

From Section 2, we can find q - [straight phi] characteristics of memristor are determined by four internal parameters ( _{R ON} , _{R OFF} , _{M 0} , and D ) described by ( 2.3). If we adjust the turning point and the segment's slope, the combinational circuit of memristors can implement a piecewise function through the original point. The parallel circuit of three memristors is shown in Figure 3. The parameters of memristors are set as follows: _{R OFF1} = _{R OFF2} = _{R OFF3} =100 k ohm , _{D 1} = _{D 2} = _{D 3} =10 nm , _{R ON1} =200 ohm , _{R ON2} = _{R ON3} =100 ohm , _{M 01} =10 k ohm , _{M 02} =10 k ohm , and _{M 03} =10 k ohm . The simulation results are shown in Figure 4.

Figure 3: The parallel circuit of three memristors.

[figure omitted; refer to PDF]

The curves of q - [straight phi] relation in the memristive parallel system.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

(c) [figure omitted; refer to PDF]

(d) [figure omitted; refer to PDF]

In the first-order delay differential equation ( 3.1), when a = -1 , b =1000 , c =3 , and the delay time τ =10 , there is a chaotic attractor in x (t ) -x (t - τ ) plane (see Figure 5). The time series x (t ) is exhibited in Figure 6.

Figure 5: A chaotic attractor of the delayed memristive system ( 3.1).

[figure omitted; refer to PDF]

Figure 6: Time dependence of the state variables x (t ) in the system ( 3.1).

[figure omitted; refer to PDF]

The circuitry implementation of the delayed memristive system: a possible electronic circuit realizing the system is given in Figure 7. The circuit consists mainly of three basic blocks: the integrator (A1), the delay element (Time delay), and the nonlinear block (F [ ] ). The electronic equation of system is [figure omitted; refer to PDF]

Figure 7: The circuitry implementation of memristive delayed system.

[figure omitted; refer to PDF]

The F [ ] block is composed of three memristors and an μ A741 operational amplifier, which follows can be written as follows: [figure omitted; refer to PDF]

The time-delay circuit block (see Figure 8) is a network of T-type LCL filters with matching resistors, where n is the number of the LCL filter. The dimensionless delay parameter is [figure omitted; refer to PDF]

Figure 8: Circuit implementation of the time delay block.

[figure omitted; refer to PDF]

Notably, the T-type LCL unit will bring a little attenuation of the circuit gain. This hurdle can be easily eliminated by operational amplifiers A3 and A4. The circuit parameters are set as follows: _{R 0} =1 kohm, _{C 0} =100 nF , L =9 .5 mH , C =525 nF , n =10 , _{R 6} = _{R 7} =1 k ohm , _{R 4} = _{R 5} = _{R 8} =10 k ohm , and _{R 9} =30 k ohm . According to ( 3.4), we can get τ =10 .

Set _{R 1} =1 k ohm , _{R 2} =1 k ohm , _{R 3} =1 M ohm , _{C 1} =1 μF , and _{V 1} = _{V 2} =15 V , system ( 3.2) has a chaotic attractor in x (t ) -x (t - τ ) plane as sown in Figure 5.

4. Conclusion

This paper gives a new perspective to understand the performance and application of memristor. The proposed piecewise models are composed by three memristors. We can that find memristor can remember not only the charge (current) but also magnetic flux (voltage). As the nonlinear element, the memristor can also act as an essential nonlinear part in chaotic system. The SPICE models designed in this paper can complete a good simulation work of chaotic circuits, which are expected to produce more rich chaotic attractors.

Acknowledgments

The work was supported by the National Natural Science Foundation of China under Grants 60972155 and 61101233, the Natural Science Foundation of Chongqing under Grants CSTC2009BB2305, the Fundamental Research Funds for the Central Universities under Grant XDJK2012A007 and XDJK2010C023, the University Excellent Talents supporting Foundations in of Chongqing under Grant 2011-65, the University Key teacher supporting Foundations of Chongqing under Grant 2011-65, the National Science Foundation for Post-doctoral Scientists of China under Grant CPSF20100470116, the Doctoral Foundation of the Southwest University under Grant SWUB2008074, and Spring Sunshine Plan Research Project of Ministry of Education of China under Grant z2011148.