METHOD AND CIRCUIT FOR SWITCHING A MEMRISTIVE DEVICE
A method of switching a memristive device applies a current ramp of a selected polarity to the memristive device. The resistance of the device during the current ramp is monitored. When the resistance of the memristive device reaches the target value, the current ramp is removed.
Memristive devices, or memristors, are a new type of switchable devices with an electrically switchable device resistance. Memristive devices are both scientifically and technically interesting, and hold promise for non-volatile memory (NVM) and other fields. For NVM applications, the compatibility with matured CMOS technology requires the memristive devices to work in binary or other digital modes. The resistance value of a memristive device is used to define the binary or other multi- level digital states. Switching the memristive device reliably and repeatedly to desired states has been a major challenge. It is frequently observed that applying a voltage write pulse often produces large fluctuations in device resistance that exhibit a lognormal distribution. The wide range of such lognormal distribution of device parameters is a potential hinder for the usability, reliability and longevity of memristive devices.
The following description provides a method of switching a bipolar memristive device and the associated control circuitry for such switching. As used herein, a memristive device is a switching device with its resistance representing its switching state, and the resistance depends on the history of the voltage and current applied to the device. The term “bipolar” means that the device can be switched from a low-resistance state (“LRS”) to a high-resistance state (“HRS”) by applying a switching voltage of one polarity, and from a high-resistance state to a low-resistance state by applying a switching voltage of the opposite polarity.
Many different materials with their respective suitable dopants can be used as the switching material. Materials that exhibit suitable properties for switching include oxides, sulfides, selenides, nitrides, carbides, phosphides, arsenides, chlorides, and bromides of transition and rare earth metals. Suitable switching materials also include elemental semiconductors such as Si and Ge, and compound semiconductors such as III-V and II-VI compound semiconductors. The listing of possible switching materials is not exhaustive and do not restrict the scope of the present invention. The dopant species used to alter the electrical properties of the switching material depends on the particular type of switching material chosen, and may be cations, anions or vacancies, or impurities as electron donors or acceptors. For instance, in the case of transition metal oxides such as TiO2, the dopant species may be oxygen vacancies. For GaN, the dopant species may be nitride vacancies or sulfide ions. For compound semiconductors, the dopants may be n-type or p-type impurities.
By way of example, as shown in
If the polarity of the electric field is reversed, the dopants may drift in an opposite direction across the switching material and away from the top electrode 120, thereby turning the device into an OFF state. In this way, the switching is reversible and may be repeated. Due to the relatively large electric field needed to cause dopant drifting, after the switching voltage is removed, the locations of the dopants remain stable in the switching material. The switching is bipolar in that voltages of opposite polarities are used to switch the device on and off. The state of the switching device 100 may be read by applying a read voltage to the bottom and top electrodes 110 and 120 to sense the resistance across these two electrodes. The read voltage is typically much lower than the threshold voltage required to induce drifting of the ionic dopants between the top and bottom electrodes, so that the read operation does not alter the resistance state of the switching device.
In the embodiment of
For instance, the primary region 124 may contain TiO2 with initially very low oxygen deficiency (i.e., low oxygen vacancies), and the second region 126 may be formed with a titanium oxide material (TiO2−x) that is stoichiometrically close to TiO2 but with a high level of oxygen vacancies. The top electrode 120 may be formed of a metal, such as platinum (Pt), that does not react with the switching material. The bottom electrode may be formed of a different conductor, such as a mixture of Pt and Ti. The interface of the Pt top electrode 120 with the TiO2 switching material in the primary region 124 generates a Schottky-type depletion region. The interface between the dopant-rich material in the secondary region 126 and the bottom electrode 110, in contrast, may form an Ohmic-type contact. Initially, with a low dopant level in the switching material of the primary region, the height and width of the Schottky-type barrier in the primary region 124 may be large, making it difficult for electrons to tunnel through. As a result, the device has a relatively high resistance. When a switching voltage to turn the device ON is applied, the oxygen vacancies may drift from the secondary region 126 into the primary region and towards the top electrode 120. The increased concentration of dopants in the primary region and/or altered distribution can significantly reduce the height and/or width of the Schotty-type barrier. As a result, electrons can tunnel through the interface much more easily, resulting in a significantly reduced overall resistance of the switching device.
As mentioned above, the resistive state of a bipolar memristive device may be changed by applying a switching voltage, and the resultant resistive state depends on the history of the switching. As an example,
The application of a voltage sweep with a current compliance has traditionally been used as a means for controlling the switching of a memristive device. The I-V curve and the final resistance obtained depend on the level of Icomp. Higher Icomp in an ON-switching will switch the device to more conductive state. While it is convenient to use Icomp as a way of switching control, that approach is not universally applicable.
To provide improved control over the switching process to obtain a much narrower distribution of the resultant resistance value, a method utilizing closed-loop feedback control is provided.
By way of example,
The resistance value of the memristive device 100 during the current ramp is monitored. To that end, the voltage drop across the memristive device 100 is used as an indicator of the resistance value. The voltage drop across the memristive device 100 is compared with the voltage drop across the reference resistor Rref. In the circuit of
The feedback-controlled switching process can be applied multiple times to set the resistance of the memristive device to different target values, by using different reference resistors of different values. As an example,
Referring back to
Also, latched comparator output stage is considered useful. Without a latched output stage that maintains the comparator output level after been tripped, the feedback circuit may possibly run into oscillation. This is due to the fact that once the current ramp is terminated, the voltage drop across the memristive device and Rref will disappear, flipping the polarity of the comparator differential input signal, and turning the comparator output back to logic low. Since the voltage ramp may still be running up, the mirror output transistors (M2 and M3) will be turned on again to continue the current ramp. After the memristive device is written, the comparator is reinitialized to get ready for the next write operation. This is realized by a reset signal to reset the comparator latched output to logic low, and two reset transistors (M5 and M6) that set up a proper initial polarity of the comparator differential input.
To further reduce the power consumption, another n-channel transistor M7 can be placed in between Rramp and the mirror master transistor M1. The gate of this transistor M7 is controlled by the Q output of the latch 212. When the memristive device is switched to the ON state, the current ramp through M1 is physically turned off rather than being shunted through M4 to ground. The circuit footprint is also reduced because the channel width of M4 does not need to be larger than M1.
It should be noted that the design of an analog feedback circuit for switching a memristive device is not exclusive and is not limited to the presented example in
It should also be noted that in the circuit in
Turning first to
The switches S1 and S2 may be implemented as CMOS devices and together form an inverter for controlling the direction of current flow through the memristive device 100. To switch the memristive device 100 from a high resistance state (HRS) to low resistance state (LRS), the voltage ramp Vramp1 is applied, and the switches S1 and S2 are set such that the ramp current sourced by the slave driver 308 flows through the memristive device 100 in the ON-switching direction. The latched comparator 312 cuts off the ramp current when the memristive device reaches the value of the reference resistor Rref1. To switch the memristive device from a low-resistance state (LRS) to a high-resistance state (HRS), the voltage ramp Vramp2 is applied. The switches S1 and S2 are set such that the ramp current sourced by the slave driver 328 flows through the memristive device in the OFF-switching direction. When the resistance of the memristive device reaches that of the reference resistor Rref2, the latched comparator 332 turns off the current ramp.
As described above, a closed-loop feedback-controlled process has been provided to control the switching a memristive device to a desired resistive state. Embodiments of electronic circuits for implementing the closed-loop switching process are also provided. The closed-loop switching process effectively enhances the consistency of the resistance values of the memristive device over multiple switching operations.
In the foregoing description, numerous details are set forth to provide an understanding of the present invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these details. While the invention has been disclosed with respect to a limited number of embodiments, those skilled in the art will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover such modifications and variations as fall within the true spirit and scope of the invention.
Claims
1.-15. (canceled)
16. A method of switching a memristive device, comprising:
- applying a first current ramp of a first polarity to the memristive device simultaneously and in parallel to a reference resistor of a first target value;
- monitoring a resistance of the memristive device during the first current ramp; and
- turning the first current ramp off when the resistance of the memristive device reaches the first target value.
17. A method as in claim 16, wherein the step of monitoring includes comparing a voltage across the memristive device with a voltage across the reference resistor.
18. A method as in claim 17, wherein the step of comparing includes feeding the voltage across the memristive device and the voltage across the reference resistor to a latched comparator.
19. A method as in claim 17, wherein the steps of applying the current ramp to the memristive device and the reference resistor include driving a current mirror with the current ramp and feeding output currents of the current mirror to the memristive device and the reference resistor.
20. A method as in claim 16, further including:
- applying a second current ramp to the memristive device;
- monitoring the resistance of the memristive device during the second current ramp;
- removing the second current ramp from the memristive device when the resistance of the memristive device reaches a second resistance value.
21. A method as in claim 20, wherein the first current ramp is non-linear.
22. A method as in claim 20, wherein the second current ramp is of a second polarity opposite to the first polarity.
23. A switching circuit for switching a memristive device, comprising:
- a current driver component for passing a current ramp simultaneously and in parallel through the memristive device and a reference resistor of a target value;
- a control component for monitoring a resistance of the memristive device and removing the current ramp from the memristive device when the resistance of the memristive device reaches the target value by turning the current ramp off.
24. A switching circuit as in claim 23, wherein the current driver component includes a current mirror.
25. A switching circuit as in claim 24, wherein the control component includes a reference resistor connected to the current mirror such that output current of the current mirror duplicating the current ramp passes through the reference resistor.
26. A switching circuit as in claim 25, wherein the control component further includes a latched comparator connected to take a voltage of the memristive device and a voltage of the reference resistor as inputs.
27. A switching circuit as in claim 26, wherein the current ramp is non-linear.
28. A switching system for switching a memristive device, comprising:
- a first half and a second half connected by the memristive device to form an H-bridge, the first half including a first current driver component and a first control component, and the second half including a second current driver component and a second control component,
- wherein the first current driver component passes a first current ramp through the memristive device in a first direction, the first control component turns the first current ramp off when a resistance of the memristive device reaches a first target value, the second current driver component passes a second current ramp through the memristive device in a second direction opposite to the first direction, and the second control component turns the second current ramp off when the resistance of the memristive device reaches a second target value.
29. A switching circuit as in claim 28, wherein the first half includes a first reference resistor for providing the first target value, and the second half includes a second reference resistor for providing the second target value.
30. A switching circuit as in claim 29, wherein the first and second current driver components each includes a current mirror.
Type: Application
Filed: Mar 30, 2016
Publication Date: Jul 28, 2016
Inventors: Frederick Perner (Palo Alto, CA), Wei Yi (Palo Alto, CA), Matthew D. Pickett (Palo Alto, CA)
Application Number: 15/085,403