WO2012032775A1 - 抵抗変化型不揮発性記憶装置の検査方法および抵抗変化型不揮発性記憶装置 - Google Patents
抵抗変化型不揮発性記憶装置の検査方法および抵抗変化型不揮発性記憶装置 Download PDFInfo
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- WO2012032775A1 WO2012032775A1 PCT/JP2011/005022 JP2011005022W WO2012032775A1 WO 2012032775 A1 WO2012032775 A1 WO 2012032775A1 JP 2011005022 W JP2011005022 W JP 2011005022W WO 2012032775 A1 WO2012032775 A1 WO 2012032775A1
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C13/00—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00
- G11C13/0002—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00 using resistive RAM [RRAM] elements
- G11C13/0007—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00 using resistive RAM [RRAM] elements comprising metal oxide memory material, e.g. perovskites
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C13/00—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00
- G11C13/0002—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00 using resistive RAM [RRAM] elements
- G11C13/0021—Auxiliary circuits
- G11C13/003—Cell access
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C29/00—Checking stores for correct operation ; Subsequent repair; Testing stores during standby or offline operation
- G11C29/04—Detection or location of defective memory elements, e.g. cell constructio details, timing of test signals
- G11C29/50—Marginal testing, e.g. race, voltage or current testing
- G11C29/50008—Marginal testing, e.g. race, voltage or current testing of impedance
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C13/00—Digital stores characterised by the use of storage elements not covered by groups G11C11/00, G11C23/00, or G11C25/00
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- G—PHYSICS
- G11—INFORMATION STORAGE
- G11C—STATIC STORES
- G11C2213/00—Indexing scheme relating to G11C13/00 for features not covered by this group
- G11C2213/10—Resistive cells; Technology aspects
- G11C2213/15—Current-voltage curve
Definitions
- the present invention relates to a method for inspecting a defect of a memory cell composed of a so-called variable resistance nonvolatile memory element (resistance variable element) and a current control element, and a variable resistance nonvolatile memory device having such a function. It is about.
- the resistance change element refers to an element having a property that the resistance value reversibly changes by an electrical signal, and further capable of storing data corresponding to the resistance value in a nonvolatile manner.
- a so-called 1T1R type memory in which a MOS transistor and a resistance change element are connected in series at a position near the intersection of a bit line and a word line arranged orthogonally
- a nonvolatile memory device in which cells are arranged in a matrix is generally known.
- one end of the two-terminal resistance change element is connected to the bit line or the source line, and the other end is connected to the drain terminal or the source terminal of the transistor.
- the gate terminal of the transistor is connected to the word line.
- the source line is arranged in parallel with the bit line or the word line.
- a so-called 1D1R type memory in which a diode as a current control element and a resistance change element are connected in series at the intersection of a bit line and a word line arranged orthogonally.
- a non-volatile memory device having a cross-point structure in which cells are arranged in a matrix is also generally known (see, for example, Patent Documents 1 and 2).
- Patent Document 1 discloses a 1D1R type nonvolatile memory device using a variable resistance element having bidirectional resistance change characteristics as a memory cell.
- FIG. 17 is a configuration diagram of a conventional nonvolatile memory cell.
- a memory cell 1280 in which a variable resistance element 1260 having a variable resistor 1230 sandwiched between an upper electrode 1240 and a lower electrode 1250 and a non-linear element 1270 are connected in series is an intersection of a bit line 1210 and a word line 1220.
- 2 shows a memory cell array having a cross-point structure arranged at a portion where the cross-section is located.
- variable resistance element 1260 is a variable resistance element having a bidirectional resistance change characteristic in which a resistance value reversibly transits between a low resistance state and a high resistance state depending on the polarity of an applied voltage.
- the non-linear element 1270 is constituted by, for example, a varistor for the purpose of reducing a so-called leakage current flowing through the non-selected cell.
- a memory cell array having a cross-point structure can have a large capacity because memory cells can be arranged at a wiring pitch and the memory cell arrays can be stacked three-dimensionally.
- Patent Document 2 discloses a defect detection method for a nonlinear element in a 1D1R type memory cell using a unidirectional variable resistance element as a memory cell.
- FIG. 18 is a configuration diagram of a conventional nonvolatile memory cell array.
- a memory cell in which a unidirectional variable resistance element and a unidirectional diode element having an anode and a cathode are connected in series are shown as bit lines BL1, BL2, BL3 and word lines WL, WL2, WL3. It is placed at the intersection.
- FIG. 19 is a model of a memory cell using a conventional unidirectional diode. As shown in FIG.
- the defect detection circuit 2053 described in Patent Document 2 includes a bit line power supply circuit 2054, a latch circuit 2531, and a switch circuit 2055, and a bit connected to the bit line selection circuit 2024. It is disclosed that a defective bit line connected to a line and to which a defective diode element is connected in the standby unit 2052 is detected.
- JP 2006-203098 A (FIG. 2) JP 2009-199695 A (FIG. 6)
- Patent Document 2 describes a method for detecting a defective bit line of a unidirectional diode element having an anode and a cathode. That is, it describes a method for detecting a defective bit line causing a leakage current abnormality by utilizing the fact that a current flows when a voltage is applied in the forward direction and no current flows when a voltage is applied in the reverse direction. .
- By setting all the bit lines to the Vdd potential, all the word lines to the Vss potential, and setting the diode elements to the reverse bias state current does not flow if all the memory cells are normal, but leakage current abnormality occurs. If there is a defective memory cell, a leak current flows from the bit line including the defective memory cell to the word line. By determining this leakage current, it is possible to detect a defective bit line causing a leakage current abnormality.
- the present invention provides an inspection method of a resistance change type nonvolatile memory device and a resistance change type nonvolatile memory device capable of detecting a defective memory cell of a memory cell array using a current control element.
- the purpose is to do.
- a resistance change type nonvolatile memory device inspection method is a resistance change type nonvolatile memory device inspection method, wherein the resistance change type nonvolatile memory device includes: A resistance change element that changes into at least two states, a low resistance state and a high resistance state, and a current control element that is connected in series with the resistance change element and that allows a current that can be regarded as a conduction state when an applied voltage exceeds a predetermined threshold voltage
- a memory cell array in which the plurality of memory cells are arranged at a solid intersection of a plurality of word lines and a plurality of bit lines, and at least one of the plurality of word lines A memory cell selection circuit for selecting a memory cell by selecting and selecting at least one of the plurality of bit lines, and the current control element of the selected memory cell By applying a voltage to the selected memory cell such that a first voltage higher than the threshold voltage and a second voltage lower than the threshold voltage are applied, the resistance state of the selected memory cell is changed
- a read circuit and when the resistance state of the memory cell is read by the second voltage, if the resistance change element is in a low resistance state and a current of a predetermined value or more flows through the current control element, Whether the state of the resistance change element is a low resistance state or a high resistance state when determining that the current control element has a short circuit abnormality and reading the resistance state of the memory cell by the first voltage Determining.
- a defective memory cell including a current control element having a threshold voltage characteristic defect that is, a current control having a short circuit abnormality.
- a memory cell including an element can be specified. Thereby, a highly reliable memory cell array can be realized.
- the second voltage is preferably lower than the first voltage by a voltage value of the threshold voltage.
- the first voltage and the second voltage can be easily set by, for example, a current control element.
- the method further includes a step of performing a write operation in a low resistance state on the memory cell before the step of determining that the current control element has a short-circuit abnormality, wherein the current control element has a current greater than or equal to a predetermined value. If the current does not flow, it is preferable to determine that the current control element is normal.
- the resistance state of the memory cell is read with the first voltage.
- the predetermined value is a maximum value of a current flowing through the current control element when the threshold voltage is applied to the normal current control element in a low resistance state and the current control element can be regarded as an off state. It is preferable that
- the current control element when determining whether the current control element of the selected memory cell is normal or abnormal, the current control element is turned off when the threshold voltage is applied to the normal current control element in the low resistance state. Since it can be determined based on the maximum value (maximum off-current) of the current flowing through the current control element when it can be regarded as a state, it can be accurately determined whether the current control element is normal or abnormal.
- a variable resistance nonvolatile memory device includes a plurality of word lines arranged in parallel to each other in a first plane, and the first plane.
- a plurality of bit lines arranged parallel to each other in a parallel second plane and three-dimensionally intersecting the word line, and a resistance change element that changes into at least two states of a low resistance state and a high resistance state
- a plurality of memory cells connected in series with the variable resistance element and a current control element through which a current that can be regarded as a conductive state when an applied voltage exceeds a predetermined threshold voltage, and the plurality of word lines,
- a memory cell array in which the plurality of memory cells are arranged at solid intersections with the plurality of bit lines; and at least one selected from the plurality of word lines; and at least from the plurality of bit lines.
- a memory cell selection circuit that selects a memory cell by selecting one and a read circuit that reads the resistance state of the selected memory cell, the read circuit including a first voltage higher than the threshold voltage; A second voltage lower than the threshold voltage is generated and output from a first output terminal and a second output terminal, respectively, and connected to the bit line control voltage generation circuit, and the first voltage and the A bit line voltage switching circuit for switching and outputting a second voltage; a bit line voltage limiting circuit having an output terminal connected to the memory selection circuit and a control terminal connected to the bit line voltage switching circuit; and the bit line A voltage applied to the selected bit line is determined by a voltage applied to a control terminal of the voltage limiting circuit, and a voltage applied to the selected memory cell is determined in advance.
- a detection circuit that detects a current flowing through the selected word line and the selected bit line, and the detection circuit reads the resistance state of the memory cell by the first voltage.
- a first logic output is output
- a second logic output is output
- the resistance state of the memory cell is read by the second voltage.
- the first logic output is output when the resistance change element is in a low resistance state
- the current control element is in a high resistance state.
- the bit line voltage limiting circuit is composed of an N-type MOS transistor, and the output terminal of the bit line voltage limiting circuit is one of a source and a drain of the N-type MOS transistor, and the bit line voltage limiting circuit
- the control terminal is preferably the gate of the N-type MOS transistor.
- a defective memory cell including a current control element having a threshold voltage characteristic defect that is, a current control having a short circuit abnormality.
- a memory cell including an element can be specified. Thereby, a highly reliable memory cell array can be realized.
- the second voltage is preferably lower than the first voltage by a voltage value of the threshold voltage.
- the first voltage and the second voltage can be easily set by, for example, a current control element.
- the second voltage is generated as a voltage divided between the first voltage and a ground potential which is a reference potential, and a current control element is provided between the first output terminal and the second output terminal. It is preferable that they are connected.
- the second voltage is generated as a voltage divided between the first voltage and a ground potential which is a reference potential, and a fixed resistance element is connected between the first output terminal and the second output terminal.
- the resistance value of the fixed resistance element is preferably set such that a potential difference between the first voltage and the second voltage is equal to the threshold voltage.
- the second voltage is generated as a voltage divided between the first voltage and a ground potential as a reference potential, and a drain and a gate are connected between the ground potential and the second output terminal.
- the N-type MOS transistor and the resistance element are preferably connected in series.
- the resistance element is formed of a resistance change element having the same structure as the memory cell, and is set to either a low resistance state or a high resistance state.
- the resistance element is formed of a fixed resistance element, and the resistance value of the fixed resistance element is set to a resistance value between a resistance value in a low resistance state and a resistance value in a high resistance state of the resistance change element. Preferably it is.
- the second voltage is generated as a voltage divided between the first voltage and a ground potential which is a reference potential, and a fixed resistance element is connected between the ground potential and the second output terminal,
- the resistance value of the fixed resistance element is preferably set so that a potential difference between the first voltage and the second voltage is equal to the threshold voltage.
- the second voltage is generated as a voltage divided between the first voltage and a ground potential which is a reference potential, and the memory cell and the second voltage are connected between the first output terminal and the second output terminal.
- a current control element and a resistance change element having the same structure are preferably connected in series.
- the bit line control voltage generation circuit preferably includes a first voltage source that generates the first voltage and a second voltage source that generates the second voltage.
- the first voltage and the second voltage can be directly set by the first voltage source and the second voltage source, respectively.
- the read circuit preferably further includes a voltage detection circuit for detecting the voltage of the bit line.
- the present invention it is possible to provide a resistance change type nonvolatile memory device inspection method and a resistance change type nonvolatile memory device capable of detecting a defective memory cell of a memory cell array using a current control element.
- FIG. 1 is an example of a configuration diagram of a memory cell according to the first embodiment.
- FIG. 2 is an equivalent circuit diagram of the memory cell.
- FIG. 3 is a diagram illustrating the voltage-current characteristics of the memory cell.
- FIG. 4 is a diagram showing voltage-current characteristics of normal memory cells and defective memory cells.
- FIG. 5 is a configuration diagram of a variable resistance nonvolatile memory device.
- FIG. 6 is a circuit diagram illustrating an example of the configuration of the readout circuit.
- FIG. 7 is a circuit diagram for explaining current paths in the memory cell array.
- FIG. 8 is an equivalent circuit diagram of the circuit diagram of FIG.
- FIG. 9 is a truth table for each mode.
- FIG. 10a is an example of a determination flow in the cell characteristic determination mode.
- FIG. 10a is an example of a determination flow in the cell characteristic determination mode.
- FIG. 10B is an example of a determination flow in the cell characteristic determination mode.
- FIG. 11a is a circuit diagram showing a modification of the bit line control voltage generating circuit.
- FIG. 11b is a circuit diagram showing a modification of the bit line control voltage generation circuit.
- FIG. 11c is a circuit diagram showing a modification of the bit line control voltage generation circuit.
- FIG. 12 is a circuit diagram illustrating an example of the configuration of the readout circuit.
- FIG. 13 is a circuit diagram illustrating an example of the configuration of the readout circuit.
- FIG. 14 is an example of an inspection flow in the cell characteristic determination mode.
- FIG. 15 is a circuit diagram illustrating an example of the configuration of the readout circuit.
- FIG. 16 is a circuit diagram illustrating an example of a configuration of a reading circuit.
- FIG. 17 is a configuration diagram of a conventional nonvolatile memory cell.
- FIG. 18 is a configuration diagram of a conventional nonvolatile memory cell array.
- FIG. 19 is
- variable resistance nonvolatile memory device hereinafter also simply referred to as “nonvolatile memory device” of the present invention will be described with reference to the drawings.
- nonvolatile memory device hereinafter also simply referred to as “nonvolatile memory device”
- FIG. 1 is an example of a configuration diagram of a memory cell according to the first embodiment of the present invention.
- a memory cell 30 shown in FIG. 1 includes a current control element 10 and a resistance change element 20.
- the current control element 10 is connected to the resistance change element 20 via a contact 41, and the current control element 10 and the resistance change element 20 constitute a 1-bit 1D1R type memory cell 30.
- One terminal of the memory cell 30 is connected to the lower wiring 50 via the contact 40, and the other terminal of the memory cell 30 is connected to the upper wiring 51 via the contact 42, and the resistance change between the current control element 10 and the current control element 10.
- the elements 20 are connected by contacts 41.
- the current control element 10 is an element in which a voltage applied to both ends of the current control element 10 and a current flowing through both ends of the current control element 10 exhibit nonlinear characteristics.
- This is a bidirectional diode in which the direction of the flowing current changes depending on the polarity of voltage. That is, the current control element 10 has a threshold voltage in each of the positive applied voltage region and the negative applied voltage region, and the absolute value of the voltage applied to both ends of the current control element 10 is less than or equal to the threshold voltage (VF).
- VF threshold voltage
- the absolute value of the flowing current is such that almost no current flows. However, when the value exceeds VF, the absolute value of the flowing current increases nonlinearly. Further, the direction of the flowing current changes depending on the polarity of the applied voltage, and the absolute value of the flowing current changes according to the absolute value of the applied voltage.
- the resistance change element 20 includes a lower electrode 23, a first resistance change layer 21, a second resistance change layer 22, and an upper electrode 24.
- the resistance change element 20 includes, for example, oxygen-deficient tantalum oxide (TaO x , 0 ⁇ x ⁇ 2.5) as the first resistance change layer 21, and the first resistance change layer 21 has a first resistance change layer 21.
- the second resistance change layer 22 made of tantalum oxide (TaO y , x ⁇ y) having a higher oxygen concentration than the resistance change layer 21 of the first resistance change layer 21, and the first resistance change between the lower electrode 23 and the upper electrode 24. It has a sandwich structure in which the layer 21 and the second resistance change layer 22 are sandwiched.
- the oxygen-deficient oxide is an oxide in which oxygen is insufficient from the stoichiometric composition.
- tantalum which is one of transition metals, has a stoichiometric composition.
- Ta 2 O 5 as an oxide.
- oxygen is contained 2.5 times as much as tantalum, and when expressed in terms of oxygen content, it is about 71.4%, and the oxide in a state lower than this oxygen content is TaO x.
- the tantalum oxide having a composition satisfying 0 ⁇ x ⁇ 2.5 is defined as an oxygen-deficient oxide.
- the resistance change element 20 exhibits a non-volatile characteristic in which the resistance value of the second resistance change layer 22 changes depending on the polarity of the voltage applied between the lower electrode 23 and the upper electrode 24 and can maintain this state. That is, by applying a positive first resistance change voltage to the upper electrode 24 with respect to the lower electrode 23, for example, the second resistance change layer 22 can be set in a high resistance state, and the upper electrode 24 is set as a reference. By applying a positive second resistance change voltage to the lower electrode 23, the second resistance change layer 22 can be set to a low resistance state.
- the upper electrode 24 is made of a metal (for example, Pt (platinum) or Ir (iridium) whose standard electrode potential is higher than the standard electrode potential of the metal (here, tantalum) constituting the first resistance change layer 21 and the second resistance change layer 22.
- the lower electrode 23 is made of an electrode material whose main component is a material having a lower standard electrode potential than the upper electrode 24 (for example, TaN (tantalum nitride)).
- the lower electrode 23 and the upper electrode 24 are made of materials made of different elements, and the standard electrode potential V1 of the lower electrode 23, the standard electrode potential V2 of the upper electrode 24, and the metal contained in the second resistance change layer 22
- the standard electrode potential Vt may be any material that satisfies Vt ⁇ V2 and V1 ⁇ V2.
- the lower electrode 23 is selected from the group consisting of TaN, W, Ni, Ta, Ti, and Al.
- the upper electrode 24 is preferably selected from the group consisting of Pt, Ir, Pd, Ag, Cu, Au, and the like.
- the current control element 10 in FIG. 1 and the resistance change element 20 may be connected in the reverse relationship, and the first resistance change layer 21 and the second resistance change layer 22 may be connected to each other.
- the upper and lower connection relationships between the lower electrode 23 and the upper electrode 24 may be reversed.
- FIG. 2 is an equivalent circuit diagram of the memory cell 30 in the present embodiment shown in FIG.
- FIG. 2 shows an equivalent circuit diagram of the memory cell 102 in which the current control element 100 and the resistance change element 101 are connected in series.
- One terminal T1 of the memory cell 102 may be connected to the lower wiring 50, the other terminal T2 may be connected to the upper wiring 51, or one terminal T2 of the memory cell may be connected to the lower wiring 50, The other terminal T1 may be connected to the upper wiring 51.
- FIG. 3 is a diagram showing voltage-current characteristics of the memory cell 30 in the present embodiment.
- the polarity at which the upper wiring 51 is higher than the lower wiring 50 is a positive voltage
- the direction of the current flowing from the upper wiring 51 to the lower wiring 50 is the positive current direction.
- the resistance change element 20 When a negative voltage is applied to the upper wiring 51 so that the lower wiring 50 has a higher potential than the upper wiring 51 with respect to the memory cell 30, current flows out from the point A, and the resistance change element 20 The change starts from the resistance state to the low resistance state. Further, when applied up to point B, the absolute value of the current increases according to the absolute value of the applied voltage, and the resistance value gradually decreases. That is, the resistance value in the low resistance state can be set according to the voltage (or current) applied to the memory cell 30.
- the measured data shown in FIG. 3 shows that the memory cell 30 having the structure of FIG. 1 is in a low resistance state when the voltage of the lower wiring 50 becomes the LR write voltage Vwl (point B) with reference to the voltage of the upper wiring 51.
- a bidirectional resistance change characteristic that changes to a high resistance state when the voltage of the upper wiring 51 becomes equal to or higher than the HR write voltage Vwh (voltage higher than the D point) with reference to the voltage of the lower wiring 50 is shown.
- Yes. 3 shows that the applied voltage in the low resistance state (point B) and the change start voltage to the high resistance state (point D) are substantially symmetrical with respect to the origin of the measured data shown in FIG. It shows that the voltage and current are in a relationship.
- the threshold voltage (VF) is a maximum voltage applied to the current control element 10 when only a current (maximum off-current) that can be regarded as the off state of the current control element 10 flows.
- the maximum off current of the current control element 10 is a current value smaller than the maximum current IHR that flows at least in the resistance change element 20 of the memory cell 30 in a high resistance state.
- the points A and C correspond to the total voltage of the threshold voltage (VF) of the current control element 10 and the voltage applied to the resistance change element 20, and a plurality of memory cells 30 are arranged in an array.
- the selected memory cell 30 is applied with a voltage higher than the voltage at the points A and C, and the non-selected memory cell has a voltage in the voltage range between the points A and C.
- FIG. 4 is a diagram showing voltage-current characteristics of the memory cell 30 having normal characteristics and the memory cell 30 having defective characteristics (short circuit abnormality) in the present embodiment.
- the polarity at which the upper wiring 51 is higher than the lower wiring 50 is a positive voltage and applied to the memory cell 30 having normal characteristics.
- the positive voltage and current to be displayed indicate a non-linear characteristic in which the threshold voltage is VF, as indicated by a characteristic 110 represented by a solid line.
- the characteristic 111 a linear characteristic is shown.
- the characteristic 110 when the threshold voltage VF of the current control element 10 is applied to both ends of the memory cell 30 having normal characteristics, the voltage Vdi applied to both ends of the current control element 10 is equal to or lower than the threshold voltage VF. Therefore, the current control element 10 is turned off, and as indicated by point E, the current flowing through the memory cell 30 flows only below the maximum off current.
- the characteristic 111 when the threshold voltage VF is applied to both ends of the memory cell 30 having a defective characteristic in which the current control element 10 is destroyed, the current control element 10 is destroyed, and thus a short state is caused. Thus, a current as shown by point F flows, and a current exceeding the maximum off-current flows.
- a voltage equal to or lower than the threshold voltage VF at which the current control element 10 is turned off is applied to both ends of the memory cell.
- the memory cell voltage Vce when a normal characteristic such as the characteristic 110 is exhibited, only a slight current (current equal to or smaller than the maximum off-state current) flows as much as the point E.
- a bad characteristic such as the characteristic 111 is shown, a current exceeding the maximum off-state current as shown at the point F flows. By detecting this current value, the characteristics of the memory cell 30 can be examined.
- Characteristic 112 and characteristic 113 in FIG. 4 are voltage / current characteristics of the memory cell when the threshold voltage of the current control element 10 is VF1 and VF2 which are lower than the threshold voltage VF of the normal memory cell 30, respectively. In either case, when VF is applied to both ends of the memory cell 30, the current control element 10 has a defective characteristic. Therefore, the memory cell 30 has a maximum off-current as indicated by the G point and the H point, respectively. Exceeds current. By detecting this current, the characteristics of the memory cell 30 can be examined.
- the characteristics of the memory cell 30 to be detected can be selected by changing the voltage value applied to both ends of the memory cell 30.
- FIG. 5 shows a configuration diagram of the variable resistance nonvolatile memory device 200 according to the first embodiment.
- the variable resistance nonvolatile memory device 200 according to the present embodiment includes a memory main body 201 on a substrate.
- the memory main body 201 includes a memory cell array 202, a word line selection circuit 203, a bit line selection circuit 204, a write circuit 205 for writing data, and a read circuit 206 for reading data. ing.
- the read circuit 206 includes a sense amplifier 300, a bit line voltage switching circuit 400, and a bit line control voltage generation circuit 500 that generates at least two types of clamp voltages. It is connected to a data signal input / output circuit 207 for outputting.
- the variable resistance nonvolatile memory device 200 includes an address signal input circuit 208 that receives an address signal input from the outside of the variable resistance nonvolatile memory device 200 and an input from the outside of the variable resistance nonvolatile memory device 200. And a control circuit 209 for receiving a control signal to be transmitted.
- the memory cell array 202 includes a plurality of word lines WL1, WL2, WL3,..., And a plurality of bit lines BL1, BL2, BL3,. ing.
- the plurality of word lines WL1, WL2, WL3,... Are arranged in parallel with each other in the same plane (in the first plane) parallel to the main surface of the substrate.
- the plurality of bit lines BL1, BL2, BL3,... Are arranged in parallel to each other in the same plane parallel to the first plane (in a second plane parallel to the first plane). Yes.
- Current control elements D11, D12, D13, D21, D22, D23 are located at three-dimensional intersections with these word lines WL1, WL2, WL3,... And bit lines BL1, BL2, BL3,. , D31, D32, D33,... (Hereinafter referred to as “current control elements D11, D12, D13,...”) And current control elements D11, D12, D13, D21, D22, D23, D31, D32. , D33,... Are connected in series with resistance change elements R11, R12, R13, R21, R22, R23, R31, R32, R33,...
- resistance change elements R11, R12, R13,... ⁇ are respectively memory cells M11, M12, M13, M21, M22, M23, M31, M32, M33,... (Hereinafter, “memory cells M11, M12, M13,...”). Are represented).
- one terminal of the resistance change elements R11, R21, R31,... Is connected to the current control elements D11, D21, D31,. Are connected to the bit line BL1, and one terminal of the resistance change elements R12, R22, R32,... Is connected to the current control elements D12, D22, D32,.
- a resistance change element is connected to the bit line side and a current control element is connected to the word line side.
- a current control element is connected to the bit line side and resistance change is made to the word line side. Elements may be connected.
- the address signal input circuit 208 receives an address signal input from the outside, outputs a row address signal to the word line selection circuit 203 based on this address signal, and outputs a column address signal to the bit line selection circuit 204.
- the address signal is a signal indicating the address of a specific memory cell selected from among the plurality of memory cells M11, M12, M13,.
- the variable resistance nonvolatile memory device 200 includes a write mode for writing data to the memory cell, a normal read mode for reading data from the memory cell, and a cell characteristic determination mode for determining the characteristics of the memory cell. ing.
- the control circuit 209 In the write mode, the control circuit 209 outputs a signal instructing application of the write voltage to the write circuit 205 in accordance with the input data Din input to the data signal input / output circuit 207.
- the control circuit 209 In the normal reading mode or the cell characteristic determination mode, the control circuit 209 outputs a signal instructing each operation to the reading circuit 206.
- the word line selection circuit 203 receives the row address signal output from the address signal input circuit 208, and selects a word selected from the plurality of word lines WL1, WL2, WL3,... According to the row address signal.
- a voltage supplied from the write circuit 205 is applied to the line, and a predetermined unselected row application voltage (Vss to Vwl, or Vwh) is applied to the unselected word line, or a high impedance (Hi-Z) is applied. ) State.
- the bit line selection circuit 204 receives the column address signal output from the address signal input circuit 208, and among the plurality of bit lines BL1, BL2, BL3,... According to the column address signal.
- a voltage supplied from the write circuit 205 or a voltage supplied from the read circuit 206 is applied to the selected bit line, and a predetermined unselected column application voltage (Vss to Vwl, Or Vwh, or Vbl) can be applied, or a high impedance (Hi-Z) state can be achieved.
- word line selection circuit 203 and the bit line selection circuit 204 correspond to the memory selection circuit in the present invention.
- the write circuit 205 receives the write signal output from the control circuit 209 in the write mode, and applies the LR write voltage Vwl or HR write to the memory cell selected by the word line selection circuit 203 and the bit line selection circuit 204.
- the memory cell can be brought into a low resistance state or a high resistance state.
- the resistance change element R11 is Changes to a low resistance state.
- the resistance change element R11 changes to the high resistance state.
- the read circuit 206 applies a read voltage between the word line selected by the word line selection circuit 203 and the bit line selected by the bit line selection circuit 204 during the read operation, and flows into the memory cell M11. By determining the current with the sense amplifier 300, the state stored in the memory cell M11 can be read. In the cell characteristic determination operation, a cell characteristic determination clamp voltage Vct is applied between the word line selected by the word line selection circuit 203 and the bit line selected by the bit line selection circuit 204, and the memory cell M11. The cell characteristics of the memory cell M11 can be determined by determining the memory cell current flowing through the memory cell with the sense amplifier 300.
- bit line control voltage generation circuit 500 sets the potential of the selected bit line selected by the bit line selection circuit 204 in accordance with the respective modes in the normal read mode and the cell characteristic determination mode.
- a clamp voltage Vcr (> VF) and a cell characteristic determination clamp voltage Vct ( ⁇ VF) are generated.
- the bit line voltage switching circuit 400 supplies the read clamp voltage Vcr output from the bit line control voltage generation circuit 500 to the sense amplifier 300 in the normal read mode.
- the cell characteristic determination clamp voltage Vct output from the bit line control voltage generation circuit 500 is supplied to the sense amplifier 300.
- the sense amplifier 300 sets the potential of the bit line to a predetermined potential in the normal read mode and the cell characteristic determination mode by the clamp voltage (Vcr or Vct) supplied from the bit line voltage switching circuit 400, respectively. Further, the cell characteristics are determined from the memory cell current read through the bit line selection circuit 204, and the determined result is output to the outside through the data signal input / output circuit 207. The setting of the bit line potential will be described later.
- FIG. 6 is a circuit diagram showing an example of the configuration of the readout circuit 206 in FIG.
- the read circuit 206 includes a sense amplifier 300, a bit line voltage switching circuit 400, and a bit line control voltage generation circuit 500.
- the sense amplifier 300 includes a comparison circuit 310, a current mirror circuit 320, and a bit line voltage control transistor N1 (bit line voltage limiting circuit).
- the bit line voltage control transistor N1 is the simplest configuration example of the bit line voltage limiting circuit.
- the current mirror circuit 320 includes a PMOS transistor P1, a PMOS transistor P2, a PMOS transistor P3, and a constant current circuit 330.
- the source terminals of the PMOS transistor P1, the PMOS transistor P2, and the PMOS transistor P3 of the current mirror circuit 320 are connected to the power supply, the gate terminals are connected to each other, the drain terminal of the PMOS transistor P1, and the constant current It is connected to one terminal of the circuit 330.
- the other terminal of the constant current circuit 330 is connected to the ground potential.
- the drain terminal of the PMOS transistor P2 is connected to one input terminal (for example, + terminal) of the comparison circuit 310 and the drain terminal (input terminal) of the bit line voltage control transistor N1.
- the drain terminal of the PMOS transistor P3 is connected to the bit line control voltage generation circuit 500.
- the gate terminal (control terminal) of the bit line voltage control transistor N1 is connected to the output terminal of the bit line voltage switching circuit 400, and the source terminal (output terminal) of the bit line voltage control transistor N1 is connected to the terminal BLIN of the read circuit 206. Via the bit line selection circuit 204.
- the other terminal (eg, ⁇ terminal) of the comparison circuit 310 is connected to the terminal SAREF of the read circuit 206, and the output terminal of the comparison circuit 310 is connected to the data signal input / output circuit 207 via the terminal SAOUT of the read circuit 206. And output data to the outside.
- the clamp voltage (Vcr or Vct) output from the bit line voltage switching circuit 400 is applied to the gate terminal (control terminal) of the bit line voltage control transistor N1 (bit line voltage limiting circuit).
- the threshold voltage Vtn of the bit line voltage control transistor N1 drops from the clamp voltage (Vcr or Vct) output from the bit line voltage switching circuit 400 to the source terminal (connected to the output terminal, BLIN) of the voltage control transistor N1.
- a voltage is applied and applied to the selected bit line via the bit line selection circuit 204.
- the bit line voltage limiting circuit may have another configuration as long as it has a characteristic of limiting the voltage applied to the bit line as described above.
- the potential of the drain terminal (connected to the input terminal, SAIN) of the bit line voltage control transistor N1 is applied to the + terminal of the comparison circuit 310, and the reference voltage Vref is applied to the ⁇ terminal of the comparison circuit 310 from the terminal SAREF.
- the comparison circuit 310 compares the reference voltage Vref applied to the ⁇ terminal and the potential of the terminal SAIN applied to the + terminal.
- the comparison circuit 310 outputs an L potential to the output terminal if the potential of the terminal SAIN is lower than the potential of the terminal SAREF, and outputs an H potential if the potential of the terminal SAIN is higher than the potential of the terminal SAREF.
- the state of the memory cell 30 is output to the outside via the data signal input / output circuit 207.
- the potential of the terminal SAIN changes from the H potential to the L potential quickly. Transition slowly or remain at H potential. Then, when the potential of the terminal SAIN and the terminal SAREF are compared by the comparison circuit 310 at a predetermined output sense timing, if the potential of the terminal SAIN is lower, the L potential is output to the output terminal SAOUT and the current flowing through the memory cell 30 is small. Is determined. Similarly, if the potential of the terminal SAIN is higher, the H potential is output to the output terminal SAOUT, and it is determined that the current flowing through the memory cell 30 is large.
- the reference voltage Vref applied from the terminal SAREF may be generated inside the variable resistance nonvolatile memory device 200 or may be applied from an external terminal. .
- the voltage applied to the gate terminal of the bit line voltage control transistor N1 is generated by the bit line control voltage generation circuit 500.
- the bit line control voltage generation circuit 500 includes a reference current control element RD10, an NMOS transistor N10, and a reference resistance change element RE10.
- One terminal of the reference current control element RD10 is connected to the drain terminal of the PMOS transistor P3 of the current mirror circuit 320 and is also connected to the output terminal OUT1 of the bit line control voltage generation circuit 500 to output the read clamp voltage Vcr. Output more.
- the other terminal of the reference current control element RD10 is connected to the drain terminal and the gate terminal of the NMOS transistor N10 and to the output terminal OUT2, and outputs the cell characteristic determination clamp voltage Vct from the output terminal.
- the source terminal of the NMOS transistor N10 is connected to one terminal of the reference resistance change element RE10, and the other terminal of the reference resistance change element RE10 is grounded.
- the reference current control element RD10 and the reference resistance change element RE10 are current control elements D11, D12, D13,... And resistance change elements R11, R12, R13,. Consists of the same elements.
- the reference resistance change element RE10 can be set to a high resistance state or a low resistance state similarly to the resistance change element included in the memory cell array 202, and at least a memory cell in the low resistance state is set. In order to detect, it is desirable to set the resistance value of the reference resistance change element RE10 to an average high resistance state resistance value of the memory cell array 202.
- the read clamp voltage Vcr output from the output terminal OUT1 of the bit line control voltage generation circuit 500 and the cell characteristic determination clamp voltage Vct output from the output terminal OUT2 are voltages applied to the reference resistance change element RE10 by Vre (resistance Are substantially the same applied voltage as the change elements R11, R12, R13,...,
- the threshold voltage of the NMOS transistor N10 is Vtn (substantially the same threshold voltage as the NMOS transistor N1), and the threshold voltage of the reference current control element RD10 is VF (current control) Assuming that the threshold voltages are substantially the same as those of the elements D11, D12, D13,.
- Vcr Vre + Vtn + VF (Formula 1)
- Vct Vre + Vtn (Formula 2)
- the NMOS transistor N10 is configured with the same transistor size as the bit line voltage control transistor N1 of the sense amplifier 300, and the PMOS transistor P3 of the sense amplifier 300 is configured with the same transistor size as the PMOS transistor P2.
- the NMOS transistor N10 and the PMOS transistor P3 may be reduced in size while maintaining the size ratio of the control transistor N1 and the PMOS transistor P2.
- the threshold voltage Vtn of the bit line voltage control transistor N1 is simulated based on the voltage from the output terminal OUT1 to the terminal BLIN of the read circuit 206 (that is, the bit line voltage when the memory cell is read). Higher voltage is output. Further, a voltage lower than the output terminal OUT1 by the threshold voltage VF of the reference current control element RD10 is output from the output terminal OUT2. Note that voltages output from the output terminal OUT1 and the output terminal OUT2 correspond to the first output and the second output in this embodiment, respectively.
- the bit line voltage switching circuit 400 includes switches SW1 and SW2. One terminal of the switch SW1 of the bit line voltage switching circuit 400 is connected to the output terminal OUT1 of the bit line control voltage generation circuit 500, and one terminal of the switch SW2 is connected to the output terminal OUT2 of the bit line control voltage generation circuit 500. It is connected. The other terminals of the switches SW1 and SW2 are connected to each other and connected to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 300.
- the bit line voltage switching circuit 400 sets the read clamp voltage Vcr at the output terminal OUT1 of the bit line control voltage generation circuit 500 to the transistor N1 by turning SW1 on and SW2 off. Output to the gate terminal.
- SW1 is turned off and SW2 is turned on to output the cell characteristic determination clamp voltage Vct of the output terminal OUT2 of the bit line control voltage generation circuit 500 to the gate terminal of the transistor N1.
- the voltage applied to the selected bit line does not exceed a voltage lower than the voltage applied to the gate terminal of the bit line voltage control transistor N1 by the threshold voltage Vtn of the transistor N1.
- the bit line voltage Vblr applied to the bit line in the mode and the bit line voltage Vblt applied to the bit line in the cell characteristic determination mode can be expressed by (Expression 3) and (Expression 4), respectively.
- FIG. 7 is a circuit diagram for explaining current paths in the memory cell array 202.
- FIG. 8 is an equivalent circuit diagram of FIG.
- the memory cell M22 In the normal read mode, in order to read the resistance state of the memory cell M22, first, the memory cell M22 is selected. To select the memory cell M22, a Vss potential is applied to the word line WL2 selected by the word line selection circuit 203, and the bit line voltage shown in (Equation 3) is applied to the bit line BL2 selected by the bit line selection circuit 204. Vblr is applied, and the unselected bit lines BL1 and BL3 and the unselected word lines WL1 and WL3 are set to a high impedance state (Hi-Z).
- the non-selected bit lines BL1 and BL3 and the non-selected word lines WL1 and WL3 are in a high impedance state, but a voltage equal to or lower than the voltage applied between the selected bit line BL2 and the selected word line WL2. It may be set to a value.
- the memory cells M11, M12, M13, M21, M23, M31, M32, and M33 have three stages of memory cells connected in series to the memory cell M22. Equivalent to being connected in parallel. That is, in the memory cell array having the 1D1R type cross-point structure shown in FIG. 7, as shown in FIG. 8, the leakage current paths in the non-selected memory cell array are equivalently connected in three stages in series.
- the unselected memory cell array shown in FIG. 8 has the following four paths (1) to (4).
- the selected bit line current Ibl that flows through the selected bit line flows through the selected memory cell current Isel that flows through the selected memory cell M22 and the unselected memory cell array. It becomes the sum of the non-selected memory cell current War.
- a voltage applied between the selected bit line BL2 and the selected word line WL2 is applied to the memory cell M22, and a selected memory cell current Isel flows according to the resistance state of the memory cell M22.
- a voltage applied between the selected bit line BL2 and the selected word line WL2 is applied to the non-selected memory cell array.
- the bit line voltage Vblr applied to the bit line BL2 is divided and applied in accordance with the respective impedances of the unselected memory cells M11, M12, M13, M21, M23, M31, M32, and M33.
- the non-selected memory cells M11, M12, M13, M21, M23, M31, M32, and M33 in the non-selected memory cell array are normal memory cells, only a voltage lower than the threshold voltage VF is applied to each current control element. Therefore, each current control element is turned off, and the non-selected memory cell current Game hardly flows in the non-selected memory cell array. That is, the selected bit line current Ibl is almost the same as the selected memory cell current Isel, and the resistance state of the selected memory cell M22 can be read.
- the selected memory cell M22 is a normal memory cell
- the bit line voltage Vblr shown in (Equation 3) is applied to the memory cell M22
- a voltage exceeding the threshold voltage VF is applied to the current control element D22. Therefore, the current control element D22 is turned on.
- the selected bit line current Ibl flows through the resistance change element R22. Since the selected bit line current Ibl has a different current value depending on the resistance state (high resistance state or low resistance state) of the variable resistance element R22, the read circuit 206 determines the current value of the selected bit line current Ibl, so that the memory Whether the cell M22 is in a high resistance state or a low resistance state can be read out.
- the current control element D22 of the selected memory cell M22 when the current control element D22 of the selected memory cell M22 is destroyed, the current control element D22 can be regarded as a conductive state, and all the bit line voltage Vblr is applied to the resistance change element R22. For this reason, the selected bit line current Ibl flows more than the memory cell current that flows in the case of a normal memory cell regardless of whether the memory cell M22 is in a low resistance state or a high resistance state. Therefore, the resistance state of the memory cell cannot be read. Therefore, it is necessary to detect whether or not the current control element D22 is destroyed in the cell characteristic determination mode.
- the Vss potential is applied to the word line WL2 selected by the word line selection circuit 203, and the bit line selection circuit 204 is selected.
- the bit line voltage Vblt shown in (Equation 4) is applied to the bit line BL2 selected in (4), and the non-selected bit lines BL1 and BL3 and the non-selected word lines WL1 and WL3 are brought into a high impedance state.
- bit line voltage Vblt that is lower than the bit line voltage Vblr in the normal read mode by the threshold voltage VF of the reference current control element RD10 (substantially the same threshold voltage as the current control element D22) is applied to the bit line BL2.
- the non-selected bit lines BL1 and BL3 and the non-selected word lines WL1 and WL3 are in a high impedance state.
- the present invention is not limited thereto, and is not limited to between the selected bit line BL2 and the selected word line WL2. You may set to the voltage value below the applied voltage.
- the selected bit line current Ibl ′ flowing through the selected bit line is the selected memory cell current Isel ′ flowing through the selected memory cell M22 and the unselected memory cell current Fish ′ flowing through the unselected memory cell array.
- a voltage applied between the selected bit line BL2 and the selected word line WL2 is applied to the memory cell M22, and a selected memory cell current Isel 'flows according to the cell characteristic state of the memory cell M22.
- a voltage applied between the selected bit line BL2 and the selected word line WL2 is applied to the non-selected memory cell array.
- any combination is equivalently connected in three stages in series.
- the bit line voltage Vblt applied to the bit line BL2 is divided and applied according to the respective impedances of the unselected memory cells M11, M12, M13, M21, M23, M31, M32, and M33. Therefore, when the non-selected memory cells M11, M12, M13, M21, M23, M31, M32, and M33 in the non-selected memory cell array are normal memory cells, only a voltage lower than the threshold voltage VF is applied to each current control element. Therefore, each current control element is turned off, and the non-selected memory cell current Zin ′ hardly flows through the non-selected memory cell array. That is, the selected bit line current Ibl ′ is almost the same as the selected memory cell current Isel ′, and the cell characteristic state of the selected memory cell M22 can be read.
- the current control element D22 When the selected memory cell M22 is a normal memory cell, when the bit line voltage Vblt shown in (Equation 4) is applied to the memory cell M22, the current control element D22 has a voltage equal to or lower than the threshold voltage VF. Is applied, the current control element D22 is turned off. Thereby, almost no current flows through the selected bit line current Ibl ′ regardless of the resistance state of the resistance change element R22.
- the current control element D22 of the memory cell M22 when the current control element D22 of the memory cell M22 is destroyed, the current control element D22 can be regarded as a conductive state, and the bit line voltage Vblt is all applied to the resistance change element R22.
- the read circuit 206 when the threshold voltage is applied to the resistance change element R22, for example, the maximum off-state current of the normal current control element in the low resistance state, that is, the normal current control element in the low resistance state.
- the current control element can be regarded as being in the OFF state, a case where a current greater than the maximum value of the current flowing through the current control element flows may be determined as “the memory cell M22 is destroyed”.
- the selected bit line current Ibl 'does not flow through the resistance change element R22, and thus it cannot be determined whether or not the memory cell M22 is destroyed.
- variable resistance nonvolatile memory device 200 using the bidirectional current control element, in the cell characteristic determination mode, at least when the variable resistance element of the selected memory cell is in the low resistance state, It is possible to determine whether the current control element of the selected memory cell is in a normal state or a destructive state, and a defective address can be specified.
- the resistance change element of the selected memory cell is in the high resistance state, the state of the current control element of the selected memory cell cannot be correctly determined.
- the cell By performing the characteristic determination mode, it is possible to determine whether the state of the current control element of the selected memory cell is normal or destroyed.
- the defective address can be specified by determining the current of the selected memory cell M22. Further, for example, even if there are defective cells exceeding 2 bits such as M12, M11, and M23, since there are only defective cells of 2 bits or less on the leakage current path of (1) to (4), it is not selected. The memory cell array current War does not flow, and the defective address can be specified similarly. If all three bits on the same leakage current path are defective cells, most of the memory cells in the memory cell array have the same defect. It is possible to find.
- FIG. 9 is a table (mode-specific truth table) showing each setting state and the state of the terminal SAOUT of the reading circuit 206 in the normal reading mode and the cell characteristic determination mode.
- L is the first logic output in this embodiment, and indicates that the sense amplifier 300 outputs the L potential when the resistance state of the memory cell is in the low resistance state.
- H is a second logic output in this embodiment, and indicates that the output of the sense amplifier 300 outputs an H potential when the resistance state of the memory cell is in a high resistance state.
- the current control element of the memory cell is turned on, and the memory cell current flowing through the memory cell is determined by the resistance state of the resistance change element of the memory cell.
- the potential of the terminal SAIN of the sense amplifier 300 of the read circuit 206 changes from the H potential to the L potential via the bit line BL and the bit line selection circuit 204.
- the resistance change element of the memory cell is in a low resistance state, the memory cell current increases, and the potential of the terminal SAIN quickly changes to the L potential.
- the resistance change element of the memory cell is in a high resistance state, The memory cell current is decreased, and the potential of the terminal SAIN is slowly changed to the L potential or is maintained at the H potential.
- the comparison circuit 310 when the potential of the terminal SAIN and the terminal SAREF is compared by the comparison circuit 310 at a predetermined output timing, if the potential of the terminal SAIN is lower, the L potential is output to the output terminal SAOUT and it is determined that the current flowing through the memory cell is small. If the potential at the terminal SAIN is higher, the H potential is output to the output terminal SAOUT, and it is determined that the current flowing through the memory cell is large. That is, if the sense amplifier 300 outputs an L potential, the state of the memory cell indicates a low resistance state, and if the output of the sense amplifier 300 outputs an H potential, the state of the memory cell indicates a high resistance state.
- the current control element of the selected memory cell is a destroyed cell
- most of the voltage applied to the memory cell is applied to the resistance change element, so that even if the resistance change element is in a high resistance state A large amount of memory cell current may flow. That is, if the variable resistance element is in the low resistance state, the output of the sense amplifier 300 is L potential, and the state of the memory cell indicates the low resistance state, but if the variable resistance element is in the high resistance state, Since the output becomes the L potential or the H potential, the resistance state of the memory cell cannot be accurately determined.
- the resistance state of the memory cell can be determined by the output potential of the sense amplifier 300.
- the resistance state of the memory cell cannot be determined.
- the current control element of the memory cell is turned off, so that the memory cell current flowing through the memory cell is almost independent of the resistance state of the resistance change element of the memory cell. Not flowing.
- this memory cell current is determined by the sense amplifier 300 of the read circuit 206 via the bit line BL and the bit line selection circuit 204, the output of the sense amplifier 300 becomes the H potential regardless of the resistance state of the resistance change element. Output.
- the current control element of the selected memory cell is a destroyed cell
- most of the voltage applied to the memory cell is applied to the resistance change element, so that even if the resistance change element is in a high resistance state A large amount of memory cell current may flow.
- the output of the sense amplifier 300 becomes the L potential, and it can be determined that the current control element is destroyed, but the variable resistance element is in the high resistance state.
- the output of the sense amplifier 300 becomes the L potential or the H potential depending on the resistance value of the variable resistance element, the cell characteristic state of the memory cell cannot be accurately determined.
- the state of the current control element of the memory cell is in a normal state by performing the cell characteristic determination mode after setting the resistance change element in a low resistance state in advance. It can be determined whether it is in a destructive state.
- the resistance change element is set in a low resistance state in advance, if a current of a predetermined value or more does not flow through the current control element, it is possible to clearly determine that the current control element is normal.
- the resistance change element R11 changes to the low resistance state.
- the state of the current control element of the memory cell can be determined. That is, if the resistance change element is in a low resistance state and a current of a predetermined value or more flows through the current control element, it can be determined that the current control element of the memory cell has a short circuit abnormality.
- the predetermined value may be the value of the maximum off-state current described above.
- the state of the current control element of the memory cell cannot be accurately determined.
- the cell characteristic determination mode is implemented after the resistance change element is in the low resistance state. By doing so, it is possible to determine whether the state of the current control element of the memory cell is normal or destroyed.
- a memory cell determined to have a current control element in a destroyed state may not be used, or may be subjected to a predetermined repair process or the like.
- FIG. 10a is an example of a determination flow in the cell characteristic determination mode that does not depend on the state of the resistance change element of the memory cell.
- step S101 when the reading circuit 206 is set to the cell characteristic determination mode (step S101), SW1 of the bit line voltage switching circuit 400 is turned off and SW2 is turned on. As a result, the output terminal OUT2 of the bit line control voltage generation circuit 500 is selected, and the cell characteristic determination clamp voltage Vct is applied to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 300.
- At least one memory cell of the memory cell array 202 is selected by the word line selected by the word line selection circuit 203 and the bit line selected by the bit line selection circuit 204 (step S102). Further, a read operation is performed on the selected memory cell (step S103).
- step S104 the voltage output to the terminal SAOUT of the sense amplifier 300 is determined (step S104), and if it is L potential, it is determined that the current control element of the memory cell is destroyed (step S105). If the potential is H, it is determined that the cell is a normal cell or a cell in which no breakdown of the current control element is detected (step S106). Then, after determining all memory cell regions (step S107), the cell characteristic determination mode is terminated.
- FIG. 10B is an example of a determination flow in the cell characteristic determination mode after the state of the resistance change element of the memory cell is first set to the low resistance state.
- the memory cell to be subjected to the cell characteristic determination is set to a low resistance state (step S200), and then the read circuit 206 is set to the cell characteristic determination mode (step S201).
- SW1 of the bit line voltage switching circuit 400 is set. Is turned off and SW2 is turned on.
- the output terminal OUT2 of the bit line control voltage generation circuit 500 is selected, and the cell characteristic determination clamp voltage Vct is applied to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 300.
- At least one memory cell of the memory cell array 202 is selected by the word line selected by the word line selection circuit 203 and the bit line selected by the bit line selection circuit 204 (step S202). Further, the above-described cell characteristic determination operation (cell characteristic read operation) is performed on the selected memory cell (step S203).
- step S204 the voltage output to the terminal SAOUT of the sense amplifier 300 is determined (step S204), and if it is L potential, it is determined that the current control element of the memory cell is destroyed (step S205). If the potential is H, it is determined as a normal cell (step S206). Then, after determining all memory cell regions (step S207), the cell characteristic determination mode is terminated.
- (Modification of the first embodiment) 11a to 11c are circuit diagrams showing modifications of the bit line control voltage generation circuit 500 of the read circuit 206 of the nonvolatile memory device according to the first embodiment of the present invention.
- the bit line control voltage generation circuit 501 shown in FIG. 11a is an example in which the reference resistance change element RE10 of the bit line control voltage generation circuit 500 of FIG. 6 is changed to a fixed resistance element RR21.
- the resistance value of the fixed resistance element RR21 is set to one of the resistance values of the reference resistance change element RE10 from the low resistance state to the high resistance state.
- only one fixed resistance element is described, but a plurality of fixed resistance elements may be provided and switched independently by a switch.
- the bit line control voltage generation circuit 501 outputs to OUT1 and OUT2.
- the read clamp voltage Vcr and the cell characteristic determination clamp voltage Vct can be easily generated. Further, by using the fixed resistance element RR21 having a small variation in resistance value, variations in the read clamp voltage Vcr and the cell characteristic determination clamp voltage Vct can be reduced, and the state of the memory cell can be detected with higher accuracy. .
- the bit line control voltage generation circuit 502 shown in FIG. 11b changes the reference resistance change element RE10 of the bit line control voltage generation circuit 500 of FIG. 6 to a fixed resistance element RR22, and controls the reference current control of the bit line control voltage generation circuit 500.
- the resistance value of the fixed resistance element RR22 is set to one of the resistance values of the reference resistance change element RE10 from the low resistance state to the high resistance state, and the resistance value of the fixed resistance element RR12 is the threshold voltage of the reference current control element RD11.
- a voltage corresponding to VF is set to such a resistance value that is applied to both ends of the fixed resistance element RR12.
- the bit line control voltage generation circuit 503 shown in FIG. 11c changes the reference resistance change element RE10 and the NMOS transistor N10 of the bit line control voltage generation circuit 500 of FIG.
- the reference current control element RD10 is a fixed resistance element RR13.
- the resistance value of the fixed resistance element RR23 is set such that a voltage corresponding to the threshold voltage Vtn of the NMOS transistor and the voltage applied to the reference resistance change element RE10 is applied to the fixed resistance element RR23.
- the resistance value of the fixed resistance element RR13 is set to a resistance value such that a voltage corresponding to the threshold voltage VF of the reference current control element RD11 is applied to both ends of the fixed resistance element RR13.
- FIGS. 11a to 11c are modifications of the bit line control voltage generation circuit 500 according to the first embodiment.
- a voltage exceeding the threshold voltage of the current control element is output to the output terminal OUT1.
- the output terminal OUT2 may have a circuit configuration that outputs a voltage equal to or lower than the threshold voltage of the current control element of the memory cell.
- the reference fixed resistance element may be a resistance change element.
- variable resistance nonvolatile memory device (Second Embodiment) Next, a variable resistance nonvolatile memory device according to a second embodiment of the present invention will be described.
- FIG. 12 is a circuit diagram showing an example of the configuration of the readout circuit 206 in the present embodiment.
- the same reference numerals are used for the same components as in the previous drawings, and the description thereof is omitted.
- the read circuit 206 shown in FIG. 12 includes a sense amplifier 301, a bit line voltage switching circuit 400, and a bit line control voltage generation circuit 504.
- the sense amplifier 301 includes a comparison circuit 310, a current mirror circuit 321, and a bit line voltage control transistor N1 (bit line voltage limiting circuit).
- the current mirror circuit 321 includes a PMOS transistor P1, a PMOS transistor P2, a PMOS transistor P3, a PMOS transistor P4, and a constant current circuit 330.
- the source terminals of the PMOS transistor P1, the PMOS transistor P2, the PMOS transistor P3, and the PMOS transistor P4 of the current mirror circuit 321 are connected to the power source, the gate terminals are connected to each other, and the PMOS transistor P1.
- the other terminal of the constant current circuit 330 is grounded.
- the drain terminal of the PMOS transistor P2 is connected to one input terminal (for example, + terminal) of the comparison circuit 310 and the drain terminal of the bit line voltage control transistor N1.
- the drain terminal of the PMOS transistor P3 and the drain terminal of the PMOS transistor P4 are connected to the bit line control voltage generation circuit 504, respectively.
- the gate terminal of the bit line voltage control transistor N1 is connected to the output terminal of the bit line voltage switching circuit 400, and the source terminal of the bit line voltage control transistor N1 is connected to the bit line selection circuit 204 via the terminal BLIN of the read circuit 206. Connected with.
- the other terminal (eg, ⁇ terminal) of the comparison circuit 310 is connected to the terminal SAREF of the read circuit 206, and the output terminal of the comparison circuit 310 is connected to the data signal input / output circuit 207 via the terminal SAOUT of the read circuit 206. And output data to the outside.
- the voltage applied to the gate terminal of the bit line voltage control transistor N1 is generated by the bit line control voltage generation circuit 504.
- the bit line control voltage generation circuit 504 includes a read clamp voltage generation circuit 510 that generates a read clamp voltage Vcr and a cell characteristic determination clamp voltage generation circuit 520 that generates a cell characteristic determination clamp voltage Vct.
- the read clamp voltage generation circuit 510 includes an NMOS transistor N14 and a reference memory cell RM14.
- the reference memory cell RM14 is configured by connecting a reference resistance change element RE14 and a reference current control element RD14 in series.
- the drain terminal and gate terminal of the NMOS transistor N14 are connected to the drain terminal of the PMOS transistor P3 of the current mirror circuit 321 and to the output terminal OUT1 of the bit line control voltage generation circuit 504, and the read clamp voltage Vcr. Is output from the output terminal OUT1.
- the source terminal of the NMOS transistor N14 is connected to one terminal of the reference resistance change element RE14 of the reference memory cell RM14, and the other terminal of the reference resistance change element RE14 is connected to one terminal of the reference current control element RD14.
- the other terminal of the reference current control element RD14 is grounded.
- the cell characteristic determination clamp voltage generation circuit 520 includes an NMOS transistor N24 and a reference fixed resistance element RR24.
- the drain terminal and gate terminal of the NMOS transistor N24 are connected to the drain terminal of the PMOS transistor P4 of the current mirror circuit 321 and to the output terminal OUT2 of the bit line control voltage generation circuit 504, and the cell characteristic determination clamp voltage Vct is set. Output from the output terminal OUT2.
- the source terminal of the NMOS transistor N24 is connected to one terminal of the reference fixed resistance element RR24, and the other terminal of the reference fixed resistance element RR24 is grounded.
- the reference current control element RD14 and the reference resistance change element RE14 of the reference memory cell RM14 are current control elements D11, D12, D13,... And resistance change elements R11, R12, R13 included in the memory cell array 202.
- the reference fixed resistance element RR24 is set to a resistance value of the resistance change elements R11, R12, R13,... Included in the memory cell array 202 in a low resistance state or a high resistance state.
- the reference fixed resistance element RR24 may be a resistance change element.
- the reference resistance change element RE14 can be set to a high resistance state or a low resistance state in the same manner as the resistance change elements included in the memory cell array 202. In order to detect at least the memory cell in the low resistance state, it is desirable to set the resistance values of the reference resistance change element RE10 and the reference fixed resistance element RR24 to the average resistance value of the memory cell array 202 in the high resistance state. .
- the reference memory cell RM14 can be realized with the same configuration as the memory cells M11, M12, M13,... Included in the memory cell array 202, and thus detects the state of the memory cell with higher accuracy.
- the fixed resistance element RR24 having a small variation in resistance value, variations in the read clamp voltage Vcr and the cell characteristic determination clamp voltage Vct can be reduced, and the state of the memory cell can be detected with higher accuracy. can do.
- FIG. 13 is a circuit diagram showing an example of the configuration of the read circuit 206 in the present embodiment, and includes at least two cell characteristic determination clamp voltage generation circuits 520 in FIG. Further, in the present embodiment, a case in which two cell characteristic determination clamp voltage generation circuits are configured will be described, but three or more cell characteristic determination clamp voltage generation circuits may be configured.
- the read circuit 206 shown in FIG. 13 includes a sense amplifier 302, a bit line voltage switching circuit 401, and a bit line control voltage generation circuit 505.
- the sense amplifier 302 includes a comparison circuit 310, a current mirror circuit 322, and a bit line voltage control transistor N1 (bit line voltage limiting circuit).
- the current mirror circuit 322 includes a PMOS transistor P1, a PMOS transistor P2, a PMOS transistor P3, a PMOS transistor P4, a PMOS transistor P5, and a constant current circuit 330.
- the source terminals of the PMOS transistor P1, the PMOS transistor P2, the PMOS transistor P3, the PMOS transistor P4, and the PMOS transistor P5 of the current mirror circuit 322 are connected to the power supply, and the gate terminals are connected to each other.
- the drain terminal of the PMOS transistor P1 and one terminal of the constant current circuit 330 are connected.
- the other terminal of the constant current circuit 330 is grounded.
- the drain terminal of the PMOS transistor P2 is connected to one input terminal (for example, + terminal) of the comparison circuit 310 and the drain terminal of the bit line voltage control transistor N1.
- the drain terminal of the PMOS transistor P3, the drain terminal of the PMOS transistor P4, and the drain terminal of the PMOS transistor P5 are connected to the bit line control voltage generation circuit 505, respectively.
- the gate terminal of the bit line voltage control transistor N1 is connected to the output terminal of the bit line voltage switching circuit 401, and the source terminal of the bit line voltage control transistor N1 is connected to the bit line selection circuit 204 via the terminal BLIN of the read circuit 206. Connected with.
- the other terminal (eg, ⁇ terminal) of the comparison circuit 310 is connected to the terminal SAREF of the read circuit 206, and the output terminal of the comparison circuit 310 is connected to the data signal input / output circuit 207 via the terminal SAOUT of the read circuit 206. And output data to the outside.
- load currents Ild4 and Ild5 are determined from the PMOS transistor P4 and the PMOS transistor P5, respectively.
- the voltage applied to the gate terminal of the bit line voltage control transistor N1 is generated by the bit line control voltage generation circuit 505.
- the bit line control voltage generation circuit 505 includes a read clamp voltage generation circuit 510 that generates a read clamp voltage Vcr, a cell characteristic determination clamp voltage generation circuit 521 that generates a first cell characteristic determination clamp voltage Vct1, and a second cell.
- the cell characteristic determination clamp voltage generation circuit 522 generates the characteristic determination clamp voltage Vct2.
- the read clamp voltage generation circuit 510 includes an NMOS transistor N14 and a reference memory cell RM14.
- the reference memory cell RM14 is configured by connecting a reference resistance change element RE14 and a reference current control element RD14 in series.
- the drain terminal and gate terminal of the NMOS transistor N14 are connected to the drain terminal of the PMOS transistor P3 of the current mirror circuit 322 and to the output terminal OUT1 of the bit line control voltage generating circuit 505, and the read clamp voltage Vcr. Is output from the output terminal OUT1.
- the source terminal of the NMOS transistor N14 is connected to one terminal of the reference resistance change element RE14 of the reference memory cell RM14, and the other terminal of the reference resistance change element RE14 is connected to one terminal of the reference current control element RD14.
- the other terminal of the reference current control element RD14 is grounded.
- the cell characteristic determination clamp voltage generation circuit 521 includes an NMOS transistor N25 and a reference fixed resistance element RR25.
- the drain terminal and gate terminal of the NMOS transistor N25 are connected to the drain terminal of the PMOS transistor P4 of the current mirror circuit 322 and to the output terminal OUT2 of the bit line control voltage generation circuit 505, and the first cell characteristic determination clamp
- the voltage Vct1 is output from the output terminal OUT2.
- the source terminal of the NMOS transistor N25 is connected to one terminal of the reference fixed resistance element RR25, and the other terminal of the reference fixed resistance element RR25 is grounded.
- the cell characteristic determination clamp voltage generation circuit 522 includes an NMOS transistor N26 and a reference fixed resistance element RR26.
- the drain terminal and the gate terminal of the NMOS transistor N26 are connected to the drain terminal of the PMOS transistor P5 of the current mirror circuit 322 and to the output terminal OUT3 of the bit line control voltage generation circuit 505, and the second cell characteristic determination clamp The voltage Vct2 is output from the output terminal OUT3.
- the source terminal of the NMOS transistor N26 is connected to one terminal of the reference fixed resistance element RR26, and the other terminal of the reference fixed resistance element RR26 is grounded.
- the reference current control element RD14 and the reference resistance change element RE14 of the reference memory cell RM14 are current control elements D11, D12, D13,... And resistance change elements R11, R12, R13 included in the memory cell array 202.
- the reference fixed resistance elements RR25 and RR26 are set to the resistance values of the resistance change elements R11, R12, R13,... Included in the memory cell array 202 in the low resistance state or the high resistance state.
- the reference fixed resistance elements RR25 and RR26 may be resistance change elements.
- the reference resistance change element RE14 can be set to a high resistance state or a low resistance state in the same manner as the resistance change elements included in the memory cell array 202. In order to detect at least the memory cell in the low resistance state, the resistance values of the reference resistance change element RE14 and the reference fixed resistance elements RR25 and RR26 should be set to the average resistance value of the memory cell array 202. Is desirable.
- the determination clamp voltage Vct2 is Vre (substantially the same applied voltage as the resistance change elements R11, R12, R13,...) Applied to the reference resistance change element RE14, and the threshold voltages of the NMOS transistors N14, N25, N26 are Vtn.
- the threshold voltage is almost the same as that of the NMOS transistor N1
- the threshold voltage of the reference current control element RD14 is applied to VF (substantially the same threshold voltage as the current control elements D11, D12, D13, etc.
- the reference fixed resistance elements RR25 and RR26 are Vre1 and Vre2 If each equation (5), (6), represented by formula (7).
- Vcr Vre + Vtn + VF (Formula 5)
- Vct1 Vr1 + Vtn (Formula 6)
- Vct2 Vr2 + Vtn (Formula 7)
- the NMOS transistors N14, N25, and N26 are configured with the same transistor size as the bit line voltage control transistor N1 of the sense amplifier 302, and the PMOS transistors P3, P4, and P5 of the sense amplifier 302 are configured with the same transistor size as the PMOS transistor P2.
- the NMOS transistor N14 and the PMOS transistor P3 may be reduced in size while maintaining the size ratio of the bit line voltage control transistor N1 and the PMOS transistor P2.
- the NMOS transistor N25 and the PMOS transistor P4, and the NMOS transistor N26 and the PMOS transistor P5 may be reduced in size while maintaining the size ratio between the bit line voltage control transistor N1 and the PMOS transistor P2.
- the threshold voltage Vtn of the bit line voltage control transistor N1 is simulated based on the voltage from the output terminal OUT1 to the terminal BLIN of the read circuit 206 (that is, the bit line voltage when the memory cell is read). Higher voltage is output. Also, the difference between the output terminal OUT2 and the voltage Vre1 applied to the reference resistance change element RR25 and the voltage Vre1 applied to the reference resistance change element RE14 is lower than the output terminal OUT1 by the threshold voltage VF of the reference current control element RD14. A total voltage of the voltages (Vre ⁇ Vre1) is output.
- the difference between the output terminal OUT3 and the voltage Vre2 applied to the reference resistance change element RR26 and the voltage Vre2 applied to the reference resistance change element RE14 is lower than the output terminal OUT1 by the threshold voltage VF of the reference current control element RD14.
- a total voltage of the voltages (Vre ⁇ Vre2) is output.
- the bit line voltage switching circuit 401 includes switches SW1, SW2, and SW3.
- One terminal of the switch SW1 of the bit line voltage switching circuit 401 is connected to the output terminal OUT1 of the bit line control voltage generation circuit 505, and one terminal of the switch SW2 is connected to the output terminal OUT2 of the bit line control voltage generation circuit 505.
- One terminal of the switch SW3 is connected to the output terminal OUT3 of the bit line control voltage generation circuit 505.
- the other terminals of the switch SW1, the switch SW2, and the switch SW3 are connected to each other and to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 302.
- the bit line voltage switching circuit 401 sets the read clamp voltage Vcr at the output terminal OUT1 of the bit line control voltage generation circuit 505 by turning SW1 on and SW2 and SW3 off. Output to the gate terminal of the transistor N1.
- the first cell of the output terminal OUT2 of the bit line control voltage generation circuit 505 is set by turning off SW1, turning on one of SW2 and SW3, and turning off the other.
- the characteristic determination clamp voltage Vct1 or the second cell characteristic determination clamp voltage Vct2 at the output terminal OUT3 is output to the gate terminal of the transistor N1.
- bit line voltage switching circuit 401 applies the read clamp voltage Vcr to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 302 in the normal read mode, and the first cell characteristic determination clamp voltage in the cell characteristic determination mode. Vct1 or the second cell characteristic determination clamp voltage Vct2 is applied.
- the voltage applied to the bit line does not exceed a voltage lower than the voltage applied to the gate terminal of the bit line voltage control transistor N1 by the threshold voltage Vtn of the transistor N1.
- the bit line voltage Vblr applied to the line and the bit line voltage Vblt1 (SW1: on state, SW2 off state) and Vblt2 (SW1: off state, SW2 on state) applied to the bit line in the cell characteristic determination mode are: These can be represented by (Equation 8), (Equation 9), and (Equation 10), respectively.
- Vblr ⁇ Vre + VF (Formula 8) Vblt1 ⁇ Vre1 (Formula 9) Vblt2 ⁇ Vre2 (Formula 10)
- the current control element included in the memory cell array 202 is turned on, and the memory cell state is changed. Can be detected.
- the characteristics of the current control element having various variations can be detected by switching and applying a plurality of voltages equal to or lower than the threshold voltage VF of the current control element to the bit line.
- FIG. 14 is an example of a determination flow in the cell characteristic determination mode using the nonvolatile memory device according to the third embodiment. This determination flow will be described assuming that the first and second clamp voltages can be set by taking the circuit diagram described in FIG. 13 as an example.
- step S300 when the cell characteristic determination mode is set (step S300), SW1 of the bit line voltage switching circuit 401 is turned off.
- step S301 in order to set the first cell characteristic determination clamp voltage (step S301), SW2 of the bit line voltage switching circuit 401 is turned on and SW3 is turned off, so that the bit line control voltage generating circuit 505 The output terminal OUT2 is selected, and the first cell characteristic determination clamp voltage Vct1 is applied to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 302.
- step S302 at least one memory cell of the memory cell array 202 is selected by the word line selected by the word line selection circuit 203 and the bit line selected by the bit line selection circuit 204 (step S302).
- step S303 The above-described cell characteristic determination operation (cell characteristic read operation) is performed on the memory cell (step S303). Then, the output voltage of the sense amplifier 302 is determined (step S304). If the potential is L, it is determined that the current control element of the memory cell is destroyed (step S305). If the potential is H, the cell is a normal cell. A determination is made as a cell in which no breakdown of the current control element has been detected (step S306). If all the cell characteristic determination clamp voltages are detected (Yes in step S307), all the memory cell regions are determined (step S309), and then the cell characteristic determination mode is terminated, and all the cell characteristic determinations are performed. If detection by the clamp voltage has not been performed (No in step S307), the next cell characteristic determination clamp voltage (after the second cell characteristic determination clamp voltage) is switched (step S308), and the read operation (step S303) and thereafter Repeat the flow.
- step S304 the output voltage of the sense amplifier 302 is determined (step S304). If the potential is L, it is determined
- the state of the memory cell can be sequentially detected with a plurality of cell characteristic determination operation voltages, so that the variation of the threshold voltage of the current control element of the memory cell is evaluated. can do.
- the cell characteristic determination clamp voltage starts evaluation from a low cell characteristic determination clamp voltage and then sets a higher cell characteristic determination clamp voltage. This is because, when a high cell characteristic determination clamp voltage is initially set, if the current control element of the memory cell is destroyed, the set high cell characteristic determination clamp voltage is applied to the resistance change element of the memory cell, This is because the state of the resistance change element may change when the write voltage of the resistance change element is exceeded. In particular, when the variable resistance element changes to the high resistance state, there is a case where the destruction state of the memory cell is not detected, as described in the truth table for each mode in FIG. In addition, it is more preferable that the voltage applied in the cell characteristic determination mode is applied with a polarity that changes the memory cell to a low resistance state.
- variable resistance nonvolatile memory device (Fourth embodiment) Next, a variable resistance nonvolatile memory device according to a fourth embodiment of the present invention will be described.
- FIG. 15 is a circuit diagram showing an example of the configuration of the read circuit 206 in this embodiment. As shown in FIG. 15, an example of the configuration using at least two voltage sources in the bit line control voltage generation circuit 506 is shown. Is shown. In this embodiment, the case where two voltage sources are used is described. However, three or more voltage sources may be used and the bit line voltage switching circuit 400 may be switched.
- the read circuit 206 shown in FIG. 15 includes a sense amplifier 303, a bit line voltage switching circuit 400, and a bit line control voltage generation circuit 506.
- the bit line control voltage generation circuit 506 includes voltage sources VPP1 and VPP2.
- the voltage source VPP1 outputs the read clamp voltage Vcr from the output terminal OUT1 of the bit line control voltage generation circuit 506, and the voltage source VPP2 outputs the cell characteristic determination clamp voltage Vct from the output terminal OUT2 of the bit line control voltage generation circuit 506. To do.
- the voltage sources VPP1 and VPP2 may be incorporated in the nonvolatile memory device or supplied from an external power source.
- the sense amplifier 303 includes a comparison circuit 310, a current mirror circuit 323, and a bit line voltage control transistor N1 (bit line voltage limiting circuit).
- the current mirror circuit 323 includes a PMOS transistor P1, a PMOS transistor P2, and a constant current circuit 330.
- the source terminals of the PMOS transistor P1 and the PMOS transistor P2 of the current mirror circuit 323 are connected to the power supply, the gate terminals are connected to each other, and the drain terminal of the PMOS transistor P1 and one of the constant current circuit 330 are connected to each other. Connected to the terminal.
- the other terminal of the constant current circuit 330 is grounded.
- the drain terminal of the PMOS transistor P2 is connected to one input terminal (for example, + terminal) of the comparison circuit 310 and the drain terminal of the bit line voltage control transistor N1.
- the gate terminal of the bit line voltage control transistor N1 is connected to the output terminal of the bit line voltage switching circuit 400, and the source terminal of the bit line voltage control transistor N1 is connected to the bit line selection circuit 204 via the terminal BLIN of the read circuit 206.
- the other terminal (eg, ⁇ terminal) of the comparison circuit 310 is connected to the terminal SAREF of the read circuit 206, and the output terminal of the comparison circuit 310 is connected to the data signal input / output circuit 207 via the terminal SAOUT of the read circuit 206. And output data to the outside.
- the voltage applied to the gate terminal of the bit line voltage control transistor N1 is supplied from the voltage source VPP1 or the voltage source VPP2.
- the voltage source VPP1 generates a read clamp voltage Vcr shown in (Expression 1)
- the voltage source VPP2 generates a cell characteristic determination clamp voltage Vct shown in (Expression 2).
- the bit line voltage switching circuit 400 includes switches SW1 and SW2. One terminal of the switch SW1 of the bit line voltage switching circuit 400 is connected to the voltage source VPP1, and one terminal of the switch SW2 is connected to the voltage source VPP2. The other terminals of the switches SW1 and SW2 are connected to each other, and are connected to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 303. When the sense amplifier 303 is in the normal read mode, the bit line voltage switching circuit 400 outputs the read clamp voltage Vcr of the voltage source VPP1 to the gate terminal of the transistor N1 by turning SW1 on and SW2 off.
- SW1 is turned off and SW2 is turned on to output the cell characteristic determination clamp voltage Vct of the voltage source VPP2 to the gate terminal of the bit line voltage control transistor N1. That is, the bit line voltage switching circuit 400 applies the read clamp voltage Vcr to the gate terminal of the bit line voltage control transistor N1 of the sense amplifier 303 in the normal read mode, and applies the cell characteristic determination clamp voltage Vct in the cell characteristic determination mode. To do.
- the voltage applied to the bit line does not exceed a voltage lower than the voltage applied to the gate terminal of the bit line voltage control transistor N1 by the threshold voltage Vtn of the transistor N1.
- the bit line voltage Vblr applied to the line and the bit line voltage Vblt applied to the bit line in the cell characteristic determination mode can be expressed by (Equation 3) and (Equation 4), respectively. By using it, the state of the memory cell can be detected with higher accuracy.
- variable resistance nonvolatile memory device Next, a variable resistance nonvolatile memory device according to a fifth embodiment of the present invention will be described.
- FIG. 16 is a circuit diagram showing an example of the configuration of the readout circuit 206 in this embodiment.
- the read circuit 206 shown in FIG. 16 includes a sense amplifier 304, a bit line voltage switching circuit 400, and a bit line control voltage generation circuit 507.
- the bit line control voltage generation circuit 507 includes a voltage source VPP and a reference current control element RD15.
- the voltage source VPP outputs a read clamp voltage Vcr from the output terminal OUT1 of the bit line control voltage generation circuit 507.
- the voltage source VPP is connected to one terminal of the reference current control element RD15.
- the other terminal of the reference current control element RD15 is connected to the output terminal OUT2 of the bit line control voltage generation circuit 507, and the reference current control element RD15 outputs a cell characteristic determination clamp voltage Vct.
- the voltage source VPP may be incorporated in a nonvolatile memory device or supplied from an external power source.
- the sense amplifier 304 includes a comparison circuit 310, a current mirror circuit 323, a bit line voltage control transistor N1 (bit line voltage limiting circuit), a bit line precharge transistor N11, and a bit line voltage detection circuit 600. Yes.
- the current mirror circuit 323 includes a PMOS transistor P1, a PMOS transistor P2, and a constant current circuit 330. The source terminals of the PMOS transistor P1 and the PMOS transistor P2 of the current mirror circuit 323 are connected to the power supply, the gate terminals are connected to each other, and the drain terminal of the PMOS transistor P1 and one of the constant current circuit 330 are connected to each other. Connected to the terminal. The other terminal of the constant current circuit 330 is grounded.
- the drain terminal of the PMOS transistor P2 is connected to one input terminal (for example, + terminal) of the comparison circuit 310 and the drain terminal of the bit line voltage control transistor N1.
- the gate terminal of the bit line voltage control transistor N1 is connected to the gate terminal of the bit line precharge transistor N11 and to the output terminal BDOUT of the bit line voltage detection circuit 600.
- the source terminal of the bit line voltage control transistor N1 is connected to the bit line selection circuit 204 via the terminal BLIN of the read circuit 206, and the source terminal of the bit line precharge transistor N11 and the bit line voltage detection circuit 600 It is connected to the input terminal BDIN.
- the drain terminal of the bit line precharge transistor N11 is connected to the power supply voltage.
- the other terminal (eg, ⁇ terminal) of the comparison circuit 310 is connected to the terminal SAREF of the readout circuit 206, and the output terminal of the comparison circuit 310 is connected to the data signal input / output via the terminal SAOUT of the readout circuit 206. It is connected to the circuit 207 and outputs data to the outside.
- the bit line voltage detection circuit 600 is an inverter element composed of a PMOS transistor P10 and an NMOS transistor N13.
- the source terminal of the PMOS transistor P10 is connected to the bit line voltage switching circuit 400 via the terminal VDDBD of the bit line voltage detection circuit 600.
- the gate terminal of the PMOS transistor P10 is grounded.
- the drain terminal of the PMOS transistor P10 is connected to the output terminal BDOUT of the bit line voltage detection circuit 600 and to the drain terminal of the NMOS transistor N13.
- the gate terminal of the NMOS transistor N13 is connected to the input terminal BDIN of the bit line voltage detection circuit 600, and the source terminal of the NMOS transistor N13 is grounded.
- the bit line voltage switching circuit 400 includes switches SW1 and SW2. One terminal of the switch SW1 of the bit line voltage switching circuit 400 is connected to the output terminal OUT1 of the bit line control voltage generation circuit 507, and one terminal of the switch SW2 is connected to the output terminal OUT2 of the bit line control voltage generation circuit 507. It is connected. The other terminals of the switches SW1 and SW2 are connected to each other and to the terminal VDDBD of the bit line voltage detection circuit 600 of the sense amplifier 304.
- the bit line control voltage generation circuit 507 includes a voltage source VPP and a reference current control element RD15.
- the voltage source VPP generates a read clamp voltage Vcr expressed by (Equation 1), and outputs the read clamp voltage Vcr via the output terminal OUT1 of the bit line control voltage generation circuit 507.
- One terminal of the reference current control element RD15 is connected to the voltage source VPP, and the other terminal is connected to the output terminal OUT2 of the bit line control voltage generation circuit 507, so that the cell characteristic determination shown in (Expression 2) is performed.
- a clamp voltage Vct is generated.
- the cell characteristic determination clamp voltage Vct output from the output terminal OUT2 of the bit line control voltage generation circuit 507 is a voltage obtained by dropping the read clamp voltage Vcr output from the output terminal OUT1 by the threshold voltage VF of the reference current control element RD15. .
- the bit line voltage switching circuit 400 In the normal read mode of the sense amplifier 304, the bit line voltage switching circuit 400 outputs the read clamp voltage Vcr to the terminal VDDBD of the bit line voltage detection circuit 600 by turning SW1 on and SW2 off. In the cell characteristic determination mode, SW1 is turned off and SW2 is turned on, so that the cell characteristic determination clamp voltage Vct is output to the terminal VDDBD of the bit line voltage detection circuit 600.
- the bit line voltage detection circuit 600 detects the potential of the bit line at the input terminal BDIN via the terminal BLIN of the sense amplifier 304.
- the NMOS transistor N13 is turned off, and the voltage supplied from the terminal VDDBD is supplied to the bit line voltage control transistor N1 via the output terminal BDOUT. Is applied to the gate terminal of the bit line precharge transistor N11 and the bit line potential is changed from the voltage applied to the gate terminal of the bit line voltage control transistor N1 to the threshold voltage of the bit line voltage control transistor N1. Precharged to a voltage dropped by Vtn.
- the NMOS transistor N13 When the potential of the bit line exceeds the threshold voltage of the bit line voltage detection circuit 600, the NMOS transistor N13 is turned on, and the voltage at the output terminal BDOUT of the bit line voltage detection circuit 600 is lowered, thereby controlling the bit line voltage control.
- the transistor N1 and the bit line precharge transistor N11 are turned off. That is, when the potential of the bit line is equal to or lower than the threshold voltage of the bit line voltage detection circuit 600, the bit line can be precharged to a predetermined potential at high speed by the bit line precharge transistor N11.
- the voltage applied to the bit line is precharged to a predetermined potential by the bit line precharge transistor N11, so that the state of the memory cell can be detected at high speed.
- the current control element and the resistance change element may be connected in the opposite upper and lower connection relation, or the upper and lower connection relation between the first resistance change layer and the second resistance change layer.
- the upper and lower connection relations of the lower electrode and the upper electrode may be reversed.
- the non-selected bit lines BL1 and BL3 and the non-selected word lines WL1 and WL3 are in a high impedance state.
- the present invention is not limited to this, and between the selected bit line BL2 and the selected word line WL2 You may set to the voltage value below the voltage applied to.
- the materials of the upper electrode, the lower electrode, the first variable resistance layer, and the second variable resistance layer in the above embodiment are merely examples, and other materials may be used.
- the metal oxide layer of the resistance change element has a laminated structure of tantalum oxide, the above-described effects of the present invention are manifested only when the metal oxide layer is tantalum oxide.
- the variable resistance element may be of any other configuration or material as long as it is an element that reversibly transits at least two resistance values.
- bidirectional current control element is described as the current control element in the above embodiment, a unidirectional diode may be used.
- the current control element in the above embodiment may be a PN diode, a Schottky diode, or a Zener diode.
- variable resistance nonvolatile memory device having a cross-point configuration detects the address of a defective cell of a memory cell using a current control element having bidirectional characteristics, and By performing the analysis, it is useful for realizing a highly reliable memory.
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Abstract
Description
[メモリセル]
図1は、本発明の第1の実施の形態におけるメモリセルの構成図の一例である。図1に示すメモリセル30は、電流制御素子10と、抵抗変化素子20とで構成されている。
図5は、第1の実施の形態における抵抗変化型不揮発性記憶装置200の構成図を示すものである。図5に示すように、本実施の形態に係る抵抗変化型不揮発性記憶装置200は、基板上にメモリ本体部201を備えている。メモリ本体部201は、メモリセルアレイ202と、ワード線選択回路203と、ビット線選択回路204と、データの書き込みを行うための書き込み回路205と、データの読み出しを行うための読み出し回路206とを備えている。
Vct = Vre + Vtn (式2)
Vblt ≦ Vre (式4)
(2) M12→M13→M23
(3) M32→M31→M21
(4) M32→M33→M23
図11a~図11cは、本発明の第1の実施の形態における不揮発性記憶装置の読み出し回路206のビット線制御電圧発生回路500の変形例を示す回路図である。
次に、本発明の第2の実施の形態における抵抗変化型不揮発性記憶装置について説明をする。
次に、本発明の第3の実施の形態における抵抗変化型不揮発性記憶装置について説明をする。
Vct1 = Vr1 + Vtn (式6)
Vct2 = Vr2 + Vtn (式7)
Vblt1 ≦ Vre1 (式9)
Vblt2 ≦ Vre2 (式10)
次に、本発明の第4の実施の形態における抵抗変化型不揮発性記憶装置について説明をする。
次に、本発明の第5の実施の形態における抵抗変化型不揮発性記憶装置について説明をする。
20、101 抵抗変化素子
21 第1の抵抗変化層
22 第2の抵抗変化層
23 下部電極
24 上部電極
30、102、1280 メモリセル
50 下部配線
51 上部配線
200 抵抗変化型不揮発性記憶装置
201 メモリ本体部
202 メモリセルアレイ
203 ワード線選択回路(メモリセル選択回路)
204 ビット線選択回路(メモリセル選択回路)
205 書き込み回路
206 読み出し回路
207 データ信号入出力回路
208 アドレス信号入力回路
209 制御回路
300 センスアンプ
310 比較回路(検知回路)
400、401 ビット線電圧切り替え回路
500、502、503、504、505、506、507 ビット線制御電圧発生回路
600 ビット線電圧検知回路(電圧検知回路)
BL1、BL2、BL3 ビット線
D11、D12、D13、D21、D22、D23、D31、D32、D33 電流制御素子
M11、M12、M13、M21、M22、M23、M31、M32、M33 メモリセル
R11、R12、R13、R21、R22、R23、R31、R32、R33 抵抗変化素子
WL1、WL2、WL3 ワード線
Claims (17)
- 抵抗変化型不揮発性記憶装置の検査方法であって、
前記抵抗変化型不揮発性記憶装置は、
低抵抗状態と高抵抗状態の少なくとも2つの状態に変化する抵抗変化素子と、前記抵抗変化素子と直列に接続され印加電圧が所定の閾値電圧を超えると導通状態とみなせる電流が流れる電流制御素子とで構成される複数のメモリセルを有し、複数のワード線と複数のビット線との立体交差点に前記複数のメモリセルが配置されたメモリセルアレイと、
前記複数のワード線から少なくとも1つを選択し、前記複数のビット線から少なくとも1つを選択することにより、メモリセルを選択するメモリセル選択回路と、
選択されたメモリセルの前記電流制御素子に前記閾値電圧より高い第1電圧、および、前記閾値電圧より低い第2電圧が印加されるように、前記選択されたメモリセルに電圧を印加することによって、選択された前記メモリセルの抵抗状態を読み出す読み出し回路と、を備え、
前記第2電圧による前記メモリセルの抵抗状態の読み出しのときに、前記電流制御素子に所定値以上の電流が流れるならば、前記電流制御素子が短絡異常を有していると判定する工程と、
前記第1電圧による前記メモリセルの抵抗状態の読み出しのときに、前記抵抗変化素子の状態が低抵抗状態か高抵抗状態かを判定する工程と、を含む
抵抗変化型不揮発性記憶装置の検査方法。 - 前記第2電圧は、前記第1電圧より前記閾値電圧の電圧値だけ低い
請求項1に記載の抵抗変化型不揮発性記憶装置の検査方法。 - 前記電流制御素子が短絡異常を有していると判定する工程の前に、
前記メモリセルに対し低抵抗状態の書き込み動作を行う工程をさらに含み、
前記電流制御素子に前記所定値以上の電流が流れないならば、前記電流制御素子が正常であると判定する
請求項1または2に記載の抵抗変化型不揮発性記憶装置の検査方法。 - 前記第2電圧により前記メモリセルの抵抗状態を読み出した後、前記第1電圧により前記メモリセルの抵抗状態を読み出す
請求項1~3のいずれか1項に記載の抵抗変化型不揮発性記憶装置の検査方法。 - 前記所定値は、低抵抗状態の正常な前記電流制御素子に前記閾値電圧を印加したときであって前記電流制御素子をオフ状態とみなせる場合の、前記電流制御素子に流れる電流の最大値である
請求項1~4のいずれか1項に記載の抵抗変化型不揮発性記憶装置の検査方法。 - 第1の平面内において互いに平行に配置された複数のワード線と、
前記第1の平面に平行な第2の平面内において互いに平行に、かつ、前記ワード線と立体交差するように配置された複数のビット線と、
低抵抗状態と高抵抗状態の少なくとも2つの状態に変化する抵抗変化素子と、前記抵抗変化素子と直列に接続され印加電圧が所定の閾値電圧を超えると導通状態とみなせる電流が流れ電流制御素子とで構成される複数のメモリセルを有し、前記複数のワード線と前記複数のビット線との立体交差点に前記複数のメモリセルが配置されたメモリセルアレイと、
前記複数のワード線から少なくとも1つを選択し、前記複数のビット線から少なくとも1つを選択することにより、メモリセルを選択するメモリセル選択回路と、
選択された前記メモリセルの抵抗状態を読み出す読み出し回路と、を備え、
前記読み出し回路は、
前記閾値電圧より高い第1電圧と、前記閾値電圧より低い第2電圧を発生し、それぞれ第1出力端子および第2出力端子から出力するビット線制御電圧発生回路と、
前記ビット線制御電圧発生回路に接続され、前記第1電圧と前記第2電圧とを切り替えて出力するビット線電圧切り替え回路と、
出力端子が前記メモリ選択回路に接続され、制御端子が前記ビット線電圧切り替え回路に接続されたビット線電圧制限回路と、
前記ビット線電圧制限回路の制御端子に印加される電圧により前記選択されたビット線に印加される電圧が決定され、前記選択されたメモリセルに前記選択されたワード線、および前記選択されたビット線を介して流れる電流を検知する検知回路と、を有し、
前記検知回路は、
前記第1電圧による前記メモリセルの抵抗状態の読み出しのときに、選択された前記メモリセルが低抵抗状態のときは第1の論理出力を出力し、高抵抗状態のときは第2の論理出力を出力し、
前記第2電圧による前記メモリセルの抵抗状態の読み出しのときに、選択された前記メモリセルにおいて前記電流制御素子が短絡異常を有していれば、前記抵抗変化素子が低抵抗状態のときに第1の論理出力を出力し、高抵抗状態のときに第1または第2の論理出力を出力する
抵抗変化型不揮発性記憶装置。 - 前記ビット線電圧制限回路は、N型MOSトランジスタからなり、前記ビット線電圧制限回路の前記出力端子は、前記N型MOSトランジスタのソースおよびドレインの一方であり、前記ビット線電圧制限回路の前記制御端子は、前記N型MOSトランジスタのゲートである
請求項6に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧より前記閾値電圧の電圧値だけ低い
請求項6に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧と基準電位である接地電位との間の電圧分圧として生成され、前記ビット線制御電圧発生回路の前記第1出力端子と前記第2出力端子との間に、電流制御素子が接続されている
請求項6~8のいずれか1項に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧と基準電位である接地電位との間の電圧分圧として生成され、前記ビット線制御電圧発生回路の前記第1出力端子と前記第2出力端子との間に固定抵抗素子が接続され、
前記固定抵抗素子の抵抗値は、前記第1電圧と前記第2電圧の電位差が前記閾値電圧に等しくなるように設定されている
請求項6に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧と基準電位である接地電位との間の電圧分圧として生成され、前記ビット線制御電圧発生回路の接地電位と前記第2出力端子との間に、ドレインとゲートが接続されたN型MOSトランジスタと抵抗素子とが直列接続されている
請求項6~10のいずれか1項に記載の抵抗変化型不揮発性記憶装置。 - 前記抵抗素子は、前記メモリセルと同じ構造の抵抗変化素子で形成され、低抵抗状態または高抵抗状態のいずれかに設定されている
請求項11に記載の抵抗変化型不揮発性記憶装置。 - 前記抵抗素子は、固定抵抗素子で形成され、
前記固定抵抗素子の抵抗値は、前記抵抗変化素子の低抵抗状態の抵抗値と高抵抗状態の抵抗値の間の抵抗値に設定されている
請求項11に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧と基準電位である接地電位との間の電圧分圧として生成され、前記ビット線制御電圧発生回路の接地電位と前記第2出力端子との間に固定抵抗素子が接続され、
前記固定抵抗素子の抵抗値は、前記第1電圧と前記第2電圧の電位差が前記閾値電圧に等しくなるように設定されている
請求項6~10のいずれか1項に記載の抵抗変化型不揮発性記憶装置。 - 前記第2電圧は、前記第1電圧と基準電位である接地電位との間の電圧分圧として生成され、前記ビット線制御電圧発生回路の前記第1出力端子と前記第2出力端子との間に、前記メモリセルと同じ構造の電流制御素子と抵抗変化素子とが直列接続されている
請求項6に記載の抵抗変化型不揮発性記憶装置。 - 前記ビット線制御電圧発生回路は、前記第1電圧を発生する第1電圧源と、前記第2電圧を発生する第2電圧源を有する
請求項6に記載の抵抗変化型不揮発性記憶装置。 - 前記読み出し回路は、さらに、前記選択されたビット線の電圧を検知する電圧検知回路を備える
請求項6に記載の抵抗変化型不揮発性記憶装置。
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