JP2012093261A - Semiconductor circuit, semiconductor device, failure diagnosis method, and failure diagnosis program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a semiconductor circuit, a semiconductor device, a failure diagnosis method, and a failure diagnosis program, capable of self-diagnosing the failure of the switch of a selection circuit.SOLUTION: To diagnose the failure of the high potential side SW of a cell selection SW 20, a low potential side SW and the high potential side SW are all turned OFF (in all OFF-state) to detect an output voltage Vout. In the case of output voltage Vout=0 V, no failure on the high potential side SW is determined. In the case of output voltage Vout≠0 V, a failure on the high potential side SW is determined. To diagnose a failure on the low potential side SW, a test switch TSW5 is turned ON in the all OFF-state, and a voltage VREF is supplied from a voltage supply unit 24 to a wire 25 to determine an output voltage Vout. In the case of output voltage Vout=1/2 VREF, no failure on the low potential side SW is determined. In the case of output voltage Vout≠1/2 VREF, a failure on the low potential side SW is determined.

Description

  The present invention relates to a semiconductor circuit, a semiconductor device, a failure diagnosis method, and a failure diagnosis program, and more particularly, to a battery monitoring semiconductor circuit, a semiconductor device, a failure diagnosis method, and a failure diagnosis program.

  In general, as a large-capacity, high-output battery used for driving a motor of a hybrid vehicle or an electric vehicle, a battery in which a plurality of batteries (battery cells) are connected in series (a specific example is a lithium ion battery) Is used). A battery monitoring system for monitoring the voltage of the battery of the battery is known.

  A conventional battery monitoring system includes a battery cell group including a plurality of battery cells, and a semiconductor circuit that monitors the voltage of the battery cells included in the battery cell group.

  As a semiconductor circuit for monitoring the voltage of such a battery cell, for example, as in the battery voltage detection device described in Patent Document 1, a switch connected to the low potential side of each battery cell to be monitored and a high potential A switch connected to the low potential side of the battery cell to be selected and a selection circuit that turns on the switch connected to the high potential side when selecting a battery cell, and a selection 2. Description of the Related Art A semiconductor circuit including a differential amplifier that outputs a difference between a high-potential side potential and a low-potential side potential of a battery cell selected by the circuit to an A / D converter, and an amplifier such as a level shifter is known. .

JP 2007-285714 A

  In such a semiconductor circuit of the battery monitoring system described in Patent Document 1 and the like, a failure (leakage) of a switch of a selection circuit that selects a battery cell is regarded as a problem. Therefore, there is a demand for a function of accurately detecting such a switch leak in the selection circuit and performing self-diagnosis.

  An object of the present invention is to provide a semiconductor circuit, a semiconductor device, a failure diagnosis method, and a failure diagnosis program that can self-diagnose a failure of a switch of a selection circuit.

  To achieve the above object, a semiconductor circuit according to claim 1 includes a plurality of high potential switches respectively connected to a high potential side of each of a plurality of batteries, and a low potential side of each of the plurality of batteries. A plurality of low potential switches connected to each other, and when instructed to select any one of the plurality of batteries, the high potential switch connected to the high potential side of the battery to be selected and the low potential A selection circuit that turns on a low-potential switch connected to the side, and a high-potential voltage on the high-potential side of the battery selected by the selection circuit, and the low-potential of the battery selected by the selection circuit A low-potential voltage on the side, and a differential detection circuit that outputs a voltage value of a difference between the high-potential voltage and the low-potential voltage, and the high-potential voltage when performing a fault diagnosis of the low-potential switch The difference detection Comprising a wire for inputting the road, the high-potential side voltage supply means for supplying a fault diagnosis voltage.

  The semiconductor device according to claim 10, comprising a plurality of batteries connected in series and a selection circuit that selects any one of the plurality of batteries. And the semiconductor circuit described in 1. above.

  The failure diagnosis method according to claim 11 includes a plurality of high potential switches respectively connected to a high potential side of each of a plurality of batteries, and a plurality of low potential switches respectively connected to a low potential side of each of the plurality of batteries. A potential switch, and when instructed to select any one of the plurality of batteries, the high potential switch connected to a high potential side of the battery to be selected and the high potential switch connected to a low potential side A selection circuit that turns on the low potential switch, and a high potential voltage on the high potential side of the battery selected by the selection circuit, and a low potential voltage on the low potential side of the battery selected by the selection circuit And a difference detection circuit that outputs a voltage value of a difference between the high potential voltage and the low potential voltage, and when performing a fault diagnosis of the low potential switch, the high potential voltage is converted to the difference detection circuit. Enter in And a high-potential-side voltage supply means for supplying a failure diagnosis voltage to the wiring for connecting the high-potential switch and the low-potential switch of the selection circuit to an off state, and detecting the difference The first step of detecting the output of the circuit, and the output of the difference detection circuit detected in the first step is a value in a predetermined range that is considered to be 0, the high potential switch has failed. A failure diagnosis step of the high-potential switch comprising: a second step of determining that the high-potential switch is not present; turning off all the high-potential switch and the low-potential switch of the selection circuit; The fault diagnosis voltage is supplied to the wiring for inputting the high potential voltage to the difference detection circuit by the third step, and the output of the difference detection circuit is detected by the third step and the third step. A fourth step of determining that the low-potential switch is not faulty when the output of the difference detection circuit is a value in a predetermined range determined in advance. A failure diagnosis step.

  The failure diagnosis program according to claim 12 includes a plurality of high potential switches respectively connected to a high potential side of each of a plurality of batteries, and a plurality of low potential switches respectively connected to a low potential side of each of the plurality of batteries. A potential switch, and when instructed to select any one of the plurality of batteries, the high potential switch connected to a high potential side of the battery to be selected and the high potential switch connected to a low potential side A selection circuit that turns on the low potential switch, and a high potential voltage on the high potential side of the battery selected by the selection circuit, and a low potential voltage on the low potential side of the battery selected by the selection circuit And the difference detection circuit for outputting a voltage value of the difference between the high potential voltage and the low potential voltage, and the difference detection of the high potential voltage when performing a fault diagnosis of the low potential switch. In circuit For causing a computer to execute a process of diagnosing a failure of the high potential switch and the low potential switch of a semiconductor circuit having a high potential side voltage supply means for supplying a failure diagnosis voltage to a wiring for power supply A failure diagnosis program, the first step of detecting the output of the difference detection circuit by turning off the high potential switch and the low potential switch of the selection circuit, and the difference detected by the first step A step of diagnosing the high-potential switch, comprising: a second step of determining that the high-potential switch has not failed when the output of the detection circuit is a value in a predetermined range that is considered to be 0. And turning off the high potential switch and the low potential switch of the selection circuit, and applying the fault diagnosis voltage by the high potential side voltage supply means. A third step of supplying a high potential voltage to a wiring for inputting the difference detection circuit and detecting an output of the difference detection circuit, and an output of the difference detection circuit detected by the third step, A fourth step of determining that the low-potential switch has not failed when the value is within a predetermined range, a process comprising: a failure diagnosis step of the low-potential switch; It is intended to be executed by a computer.

  According to the present invention, it is possible to self-diagnose a failure of the switch of the selection circuit.

It is a circuit diagram which shows an example of schematic structure of the battery monitoring system which concerns on 1st Embodiment. 1 is a circuit diagram showing an example of a schematic configuration of a semiconductor circuit according to a first embodiment. It is a flowchart which shows an example of the flow of the failure diagnosis operation | movement which concerns on 1st Embodiment. It is a circuit diagram which shows an example of schematic structure of the semiconductor circuit which concerns on 2nd Embodiment. It is a flowchart which shows an example of the flow of the failure diagnosis operation | movement which concerns on 2nd Embodiment. 6 is a flowchart illustrating an example of a continuation of the example of the flow of the failure diagnosis operation illustrated in FIG. 5.

  [First Embodiment]

  Hereinafter, a battery monitoring system according to a first embodiment of the present invention will be described in detail with reference to the drawings.

  First, the configuration of the battery monitoring system of the present embodiment will be described. An example of a schematic configuration of the battery monitoring system of the present embodiment is shown in FIG. The battery monitoring system 10 of the present embodiment shown in FIG. 1 includes a battery cell group 12 including a plurality of battery cells, a semiconductor circuit 14 that measures and monitors the voltage of each battery cell in the battery cell group 12, and a determination. And a circuit 16.

  The determination circuit 16 performs failure diagnosis by determining whether or not the cell selection SW 20 (see FIG. 2, details will be described later) of the semiconductor circuit 14 has failed based on the output voltage Vout output from the semiconductor circuit 14. It has a function. In the present embodiment, the determination circuit 16 includes a microcomputer, and includes a CPU (Central Processing Unit) 17, a memory 18 including a ROM and a RAM, a nonvolatile storage unit 19 including a flash memory and the like. In addition, the CPU 17 has a function of performing failure diagnosis by executing a program stored in the memory 18.

  In the present embodiment, leakage (current leakage) of the low potential side SW and high potential side SW (see FIG. 2, both of which will be described later in detail) provided in the cell selection SW 20 or fixing in the on state (in the on state) A state in which a current flows due to a state in which the current does not return is referred to as a failure.

  FIG. 2 shows an example of a schematic configuration of the semiconductor circuit 14 of the present embodiment. In the present embodiment, as a specific example, the battery cell group 12 includes four cells C (C1 to C4) whose voltage value is set to 3.5 V, and is on the low potential side of the lowest cell C1. The voltage value is set to the ground level (0 V).

  The semiconductor circuit 14 shown in FIG. 2 includes a cell selection SW 20, a level shifter 22, and a voltage supply unit 24.

  Cell selection SW20 is a switch SW0, SW1_1, SW2_1, SW3_1 (hereinafter collectively referred to as low potential side SW) connected to the low potential side of each of cells C (C1 to C4) included in battery cell 12. And switches SW1_2, SW2_2, SW3_2, and SW4 (hereinafter collectively referred to as the high potential side SW) connected to the high potential side. Based on the input control signal, the internal SW ( This has a function of selecting a designated cell C (C1 to C4) by switching on / off of SW0 to SW4).

  The level shifter 22 includes resistors R1 to R4 and a level shifter amplifier 30 (hereinafter referred to as level shifter 30), and a cell C (C1 to C4) selected by the cell selection SW 20 is provided as a non-inverting terminal of the level shifter 30. The high potential side potential (high potential voltage) is input to the inverting terminal, and the low potential side potential (low potential voltage) is input to the inverting terminal. The difference between the high potential voltage and the low potential voltage is output to the output voltage Vout. Output as. The output voltage Vout output from the level shifter 22 is converted into a digital value by an A / D (analog / digital) converter (not shown) and output to the outside of the semiconductor circuit 14. The determination circuit 16 shown in FIG. 1 receives the output voltage Vout converted to a digital value by the A / D converter. In addition, an upper limit value for conversion is generally set for the A / D converter, and in this embodiment, an A / D converter having an upper limit value of 4.7 V is used as a specific example.

  In the present embodiment, as a specific example, the level shifter 30 of the level shifter 22 uses an operational amplifier whose drive voltage is the ground level (0 V) to VDD (4.7 V), and the resistances of the resistors R1 to R4. The value is the same value. Therefore, the output voltage Vout output from the level shifter 22 has a value in the range of 0 to 4.7V.

  The voltage supply unit 24 has a function of supplying the voltage VREF (4.7 V) to the wiring 25 for inputting the high potential voltage of each cell C (C1 to C4) to the non-inverting terminal of the level shifter 30. The voltage supply unit 24 has a function of supplying the voltage VREF to the wiring 25 by turning on the test switch TSW5 by the control signal input from the determination circuit 16 when determining the failure of the cell selection SW20. Yes.

  Next, a failure diagnosis operation for performing failure diagnosis of the low potential side SW and the high potential side SW of the cell selection SW 20 using the semiconductor circuit 14 of the present embodiment will be described.

  FIG. 3 shows a flowchart of an example of the flow of the failure diagnosis operation of the present embodiment. When performing the fault diagnosis operation, the determination circuit 16 executes a program stored in advance in a predetermined area of the memory 18 by the CPU 17. In the initial state, the test switch TSW5 of the voltage supply unit 24 is in an off state.

  First, in order to determine the failure of the high potential side SW, in step 100, all the cells C1 to C4 are connected with all the switches (low potential side SW and high potential side SW) of the cell selection SW20 turned off. It is not in a state. In the next step 102, the output voltage Vout output from the level shifter 22 in this state is detected.

  In the next step 104, it is determined whether or not the detected output voltage Vout = 0V. In the level shifter 22, since neither the low-potential voltage nor the high-potential voltage is input from any of the cells C1 to C4, the output voltage Vout = 0V if there is no failure in the high-potential side SW of the cell selection SW20. On the other hand, when there is a failure on the high potential side SW, the voltage is input to the non-inverting terminal of the level shifter 22 (level shifter 30), so that the output voltage Vout ≠ 0V. Therefore, if the output voltage Vout = 0V, the determination is affirmative and the process proceeds to step 106. In step 106, it is determined that there is no failure in the high potential side SW, and the process proceeds to step 110. On the other hand, if the output voltage Vout is not 0V, the determination is negative and the process proceeds to step 108. In step 108, it is determined that there is a failure in the high potential side SW, and the process proceeds to step 110.

  When there is a failure in the low potential side SW, even if a voltage is input to the inverting terminal of the level shifter 22 (level shifter 30), if no failure occurs in the high potential side SW, the output voltage Vout = non-inverting terminal input ( High potential voltage) −inverting terminal input (low potential voltage). In the level shifter 22, when non-inverting terminal input−inverting terminal input ≦ 0V, the output voltage Vout = 0V. As described above, since the output voltage Vout = 0V as described above, it is not possible to determine whether or not the low potential side SW is out of order. Therefore, next, the failure of the low potential side SW is determined.

  In order to determine the failure of the low potential side SW, in step 110, the test switch TSW5 is turned on. As a result, the voltage VREF is supplied to the wiring 25. In the next step 112, the output voltage Vout output from the level shifter 22 in this state (the low potential side SW and the high potential side SW are in the off state and the test switch TSW5 is in the on state) is detected.

  In the next step 114, it is determined whether or not the detected output voltage Vout = 1 / 2VREF. In the level shifter 22, since the voltage VREF is supplied to the input on the non-inverting terminal side, the voltage VREF obtained by dividing the voltage VREF by the resistors R1 and R2 is supplied to the non-inverting terminal of the level shifter 30. Accordingly, if there is no failure in the low potential side SW of the cell selection SW 20, the output voltage Vout = 1 / 2VREF. On the other hand, when there is a failure in the low potential side SW, the voltage is input to the non-inverting terminal of the level shifter 22 (level shifter 30), so that the output voltage Vout ≠ 1 / 2VREF. Therefore, when the output voltage Vout = 1 / 2VREF, the determination is affirmative and the process proceeds to step 116. In step 116, it is determined that there is no failure in the low potential side SW, and the present process is terminated. On the other hand, if the output voltage Vout is not 1 / 2VREF, the determination is negative and the process proceeds to step 118. In step 118, it is determined that there is a failure in the low-potential side SW, and this process ends.

  When the output voltage Vout = 1 / 2VREF described above, the output voltage Vout = VREF− even when the low potential side SW has a failure and a voltage of 1 / 2VREF is input to the inverting terminal side input of the level shifter 22. Since 1 / 2VREF = 1 / 2VREF, it cannot be distinguished from this case.

  Therefore, it is preferable to supply a ground potential to the low potential side of the level shifter 22 and detect a failure of the low potential side SW based on the output voltage Vout output according to the difference between the voltage VREF and the ground potential. If the ground potential is supplied to the low potential side of the level shifter 22, the output voltage Vout = VREF−ground potential (0 V) = VREF when there is no failure in the low potential side SW. When there is a failure on the side, the output voltage Vout = VREF−the inverting terminal input voltage, and the output voltage Vout <voltage VREF is surely satisfied. As described above, when a voltage of ½ VREF is input to the inverting terminal side input of the level shifter 22 due to the failure of the low potential side SW, the output voltage Vout = VREF−1 / 2VREF. The value of the voltage Vout is definitely different. Therefore, by adopting such a configuration and detection method, it is possible to reliably determine the failure of the low potential side SW.

  In the present embodiment, as described above, the ground potential is supplied to the low potential side of the level shifter 22, and the failure of the low potential side SW is based on the output voltage Vout output according to the difference between the voltage VREF and the ground potential. In this case, it is preferable that the voltage supplied from the voltage supply unit 24 (voltage VREF in the present embodiment) does not exceed the output limit value of the level shifter 30. When the voltage supplied from the voltage supply unit 24 exceeds the limit value of the output of the level shifter 30, there is a failure in the low potential side SW, and the output output from the level shifter 30 even if the voltage is input to the inverting terminal Since the voltage Vout is the output voltage Vout = non-inverting terminal−inverting terminal, the input voltage of the non-inverting terminal is large, and the output limit value of the non-inverting terminal−inverting terminal ≧ level shifter 30 (4.7 V in this embodiment). This is because the output voltage Vout = the limit value (4.7 V) of the output of the level shifter 30 may be obtained.

  As described above, in the semiconductor circuit 14 of the battery monitoring system 10 of the present embodiment, when the failure diagnosis of the high potential side SW of the cell selection SW 20 is performed, all of the low potential side SW and the high potential side SW are turned off ( The output voltage Vout in the all-off state is detected, and it is determined whether or not the detected output voltage Vout is 0V. When the output voltage Vout = 0V, it is determined that the high potential side SW has no failure, and when the output voltage Vout ≠ 0V, it is determined that the high potential side SW has failed. Further, when performing failure diagnosis of the low potential side SW, the test switch TSW5 is turned on with all the off states supplied, the voltage VREF is supplied from the voltage supply unit 24 to the wiring 25, and the output voltage Vout is detected in this state, It is determined whether or not the detected output voltage Vout is ½ VREF. When the output voltage Vout = 1 / 2VREF, it is determined that the low potential side SW has no failure, and when the output voltage Vout ≠ 1 / 2VREF, it is determined that the low potential side SW has failed.

  The failure of the low potential side SW cannot be determined as described above by simply detecting the output voltage Vout when the low potential side SW and the high potential side SW are all in the OFF state. In the embodiment, since the voltage supply unit 24 supplies the voltage VREF to the non-inverting terminal side input of the level shifter 22, it is possible to determine the failure of the low potential side SW.

  Therefore, the battery monitoring system 10 according to the present embodiment can self-diagnose the failure (leakage and sticking in the on state) of the low potential side SW and the high potential side SW of the cell selection SW 20.

  When the low potential side SW is out of order, a voltage is input to the input on the inverting terminal side of the level shifter 22 and the output voltage Vout output from the level shifter 30 is non-inverting terminal input−inverting terminal input. When the input voltage of the inverting terminal is large, the output voltage Vout becomes the limit value (4.7 V) regardless of the failure state of the low potential side SW, and it is possible to appropriately diagnose the failure state of the low potential side SW. There are cases where it is not possible. Therefore, it is preferable that the voltage supplied from the voltage supply unit 24 (voltage VREF in the present embodiment) does not exceed the limit value of the output of the level shifter 30 (4.7 V in the present embodiment).

  In the failure diagnosis of the present embodiment (see FIG. 3), the failure of the low potential side SW is determined after the determination of the failure of the high potential side SW, but the order of determination is not limited to this, After determining the failure of the low potential side SW, the determination of the failure of the high potential side SW may be performed.

  In the failure diagnosis of this embodiment (see FIG. 3), after determining that there is a failure on the high potential side SW, the failure determination on the low potential side SW is further performed. If it is determined that there is, the process may be terminated without determining the failure of the low potential side SW.

  The semiconductor circuit 14 and the determination circuit 16 may be formed on the same substrate or may be formed on separate substrates. The determination circuit 16 may output a determination result to the outside or may store the determination result inside.

  [Second Embodiment]

  Hereinafter, a battery monitoring system (semiconductor circuit) which is a semiconductor device according to a second embodiment of the present invention and a failure diagnosis operation will be described in detail with reference to the drawings.

  In the first embodiment, for example, when the level shifter 22 (level shifter 30) or the A / D converter subsequent to the level shifter 22 is not operating normally, failure diagnosis of the low potential side SW and the high potential side SW is performed. May not be able to do properly. Therefore, the battery monitoring system of the present embodiment further has a self-diagnosis function of whether the level shifter 22 (level shifter 30) is operating normally (is not abnormal).

  The battery monitoring system (semiconductor circuit) and the failure diagnosis operation of the present embodiment include substantially the same configuration and operation as those of the first embodiment, and therefore substantially the same configuration and operation as those of the first embodiment. These parts are denoted by the same reference numerals and detailed description thereof is omitted.

  Since the battery monitoring system of the present embodiment has the same configuration as the battery monitoring system 10 of the first embodiment shown in FIG. 1, the description thereof is omitted here. FIG. 4 shows an example of a schematic configuration of the semiconductor circuit 15 of the present embodiment. The semiconductor circuit 15 of the present embodiment further has a function of supplying the voltage VSS to the wiring 29 for inputting the low potential voltage of the cells C (C1 to C4) to the inverting terminal side input of the level shifter 22. 26 and a voltage supply unit 28 having a function of supplying the voltage VREF to the wiring 29. In the present embodiment, as an example, the voltage VSS is a voltage value on the low potential side of the lowest cell (cell C1) of the battery cell group 12 (in this embodiment, the ground level = 0 V). Furthermore, a test switch TSW8 having a function of short-circuiting the output of the level shifter 30 and the non-inverting terminal is provided.

  The voltage supply units 24, 26, and 28 of the present embodiment are each configured to include a resistance element and a switching element (test switches TSW5, TSW6, and TSW7). In the present embodiment, the resistor R5 of the voltage supply unit 26 is a resistance element having a resistance value larger than the on-resistance value of one switching element (for example, the switch SW0) included in the cell selection SW20.

  5 and 6 show a flowchart of an example of the failure diagnosis operation of the present embodiment. In the failure diagnosis operation of the present embodiment, as in the first embodiment, first, a failure of the high potential side SW of the cell selection SW 20 is determined. Step 200 corresponds to step 100 of the first embodiment (FIG. 3), step 202 corresponds to step 102, and step 204 corresponds to step 104. If there is no failure in the high potential side SW and no failure in the test switch TSW5, the output voltage Vout = 0V. Therefore, as in the first embodiment, when the output voltage Vout = 0V, the determination is affirmative. In step 206, it is determined that there is no failure in the high potential side SW and the test switch TSW5, and the process proceeds to step 210. On the other hand, if the output voltage Vout is not 0V, the determination is negative and the process proceeds to step 208. In step 208, the high potential side SW and the test switch TSW5 (or either the high potential side SW and the test switch TSW5) are faulty. It is determined that there is, and the process proceeds to Step 210.

  In the present embodiment, next, the operation determination of the intermediate range of the level shifter 22 (level shifter 30) and the A / D converter is performed.

  In step 210, the test switch TSW5 and the test switch TSW8 are turned on. As a result, the voltage VREF is supplied to the wiring 25. Here, the reason why the test switch TSW8 is turned on is to eliminate the influence of the failure of the low potential side SW connected to the inverting terminal side input of the level shifter 22 and the voltage supply units 26 and 28. When the low potential side SW and the voltage supply units 26 and 28 are out of order, the voltage is supplied to the inverting terminal side input of the level shifter 22, and therefore the level shifter is removed by the test switch TSW 8 in order to eliminate the influence of the voltage. 30 output and the non-inverting terminal are short-circuited.

  In the next step 212, the output voltage Vout output from the level shifter 22 in this state (the low potential side SW and the high potential side SW are in the off state and the test switch TSW5 and the test switch TSW8 are in the on state) is detected.

  In the next step 214, it is determined whether or not the detected output voltage Vout = 1 / 2VREF. In the level shifter 22, since the voltage VREF is supplied to the input on the non-inverting terminal side, 1/2 VREF obtained by dividing the voltage VREF by the resistors R1 and R2 is supplied to the non-inverting terminal of the level shifter 30. Therefore, if the operation of the level shifter 22 (and the A / D converter) is normal and normal, the output voltage Vout = 1 / 2VREF. On the other hand, when there is an abnormality, the output voltage Vout ≠ ½VREF. Therefore, if the output voltage Vout = 1 / 2VREF, the determination is affirmative and the process proceeds to step 216. In step 216, it is determined that there is no abnormality in the voltage detection operation in the intermediate range of the level shifter 22 (and the A / D converter). Proceed to 220. On the other hand, if the output voltage Vout is not 1 / 2VREF, the determination is negative and the process proceeds to step 218. In step 218, it is determined that there is an abnormality in the voltage detection operation in the intermediate range of the level shifter 22 (and the A / D converter). Proceed to step 220.

  In the present embodiment, next, the failure of the low potential side SW is determined. In step 220, the test switch TSW8 is turned off, and in the next step 222, the output voltage Vout output from the level shifter 22 is detected. The step 222 corresponds to the step 112 of the first embodiment. As in the first embodiment, the low potential side SW and the high potential side SW are in the off state, and the test switch TSW5 is in the on state. The output voltage Vout output from the level shifter 22 is detected.

  In the next step 224, it is determined whether or not the detected output voltage Vout = 1 / 2VREF. If there is no failure in the low potential side SW of the cell selection SW 20 and there is no failure in the test switch TSW6 and the test switch TSW7, the output voltage Vout = 1 / 2VREF. Therefore, as in the first embodiment, the output voltage Vout In the case of = 1 / 2VREF, the determination is affirmative and the process proceeds to step 226. In step 226, it is determined that there is no failure in the low potential side SW, the test switch TSW6, and the test switch TSW7, and the process proceeds to step 230 (FIG. 6). On the other hand, if the output voltage Vout is not 1 / 2VREF, the determination is negative and the process proceeds to step 228. In step 228, the low potential side SW and the test switch TSW6, the test switch TSW7 (or the high potential side SW and the test switch TSW6, It is determined that any of the test switches TSW7 has a failure, and the process proceeds to step 230.

  Note that there is a failure in the low potential side SW and the test switch TSW6 and the test switch TSW7 (or any of the high potential side SW and the test switch TSW6 and the test switch TSW7), and the inverting terminal side input of the level shifter 22 is 1 / 2VREF. When a voltage is input, the output voltage Vout = VREF−½VREF = ½VREF. Since the output voltage Vout = 1/2 VREF is thus obtained, this case cannot be determined as it is. For this reason, in this embodiment, the following process is further performed to appropriately determine the failure of the low potential side SW, the test switch TSW6, and the test switch TSW7.

  In the next step 230, the test switch TSW7 is turned on, and in the next step 232, the output voltage Vout output from the level shifter 22 is detected. In Step 232, the output voltage Vout output from the level shifter 22 is detected when the low potential side SW and the high potential side SW are in the off state and the test switch TSW5 and the test switch TSW7 are in the on state. That is, the output voltage Vout is detected in a state where the voltage VREF is supplied to both the non-inverting terminal side input and the inverting terminal side input of the level shifter 22.

  In the next step 234, it is determined whether or not the detected output voltage Vout = 0V. If the operation of the level shifter 22 (and the A / D converter) is normal and normal, the output voltage Vout = VREF−VREF = 0V. Further, when the low potential side SW, the test switch TSW6, and the test switch TSW7 are out of order and a voltage of 1/2 VREF is input to the inverting terminal side input of the level shifter 22, the output voltage Vout> 0V. Accordingly, when the output voltage Vout = 0V, the determination is affirmative and the process proceeds to step 236, where there is no abnormality in the voltage detection operation in the intermediate range of the level shifter 22 (and the A / D converter), the low potential side SW, the test switch TSW5, the test It is determined that there is no failure in the switch TSW7, and the process proceeds to step 244. On the other hand, if the output voltage Vout ≠ 0V, the result is negative and the process proceeds to step 238. In this embodiment, since the output voltage Vout never becomes less than 0V, the output voltage Vout> 0V. Therefore, in step 238, the low potential side SW, the test switch TSW5, the test switch TSW7 (or the low potential side) It is determined that there is a failure in any of SW and test switch TSW5 or test switch TSW7, and the process proceeds to step 240.

  In the present embodiment, next, the operation determination of the maximum range of the level shifter 22 (level shifter 30) and the A / D converter is performed.

  In step 240, the test switch TSW7 is turned off, and in the next step 242, the test switch TSW6 is turned on. Thus, the voltage VREF is supplied to the wiring 25 by the voltage supply unit 24 to the non-inverting terminal side input of the level shifter 22, and the inverting terminal of the level shifter 22 is grounded to VSS (ground) by the test switch TSW6.

  In the next step 244, the output voltage Vout output from the level shifter 22 in this state (the low potential side SW and the high potential side SW are in the off state and the test switch TSW5 and the test switch TSW6 are in the on state) is detected.

  In the next step 246, it is determined whether or not the detected output voltage Vout = VREF. If the operation of the level shifter 22 (and A / D converter) is normal and normal, the output voltage Vout = VREF-0 = VREF. On the other hand, if there is an abnormality, the output voltage Vout ≠ VREF. In the present embodiment, the resistance value of the resistor R5 of the voltage supply unit 26 is larger than the on-resistance value of each switching element included in the cell selection SW20, so that the low-potential side SW and the test switch TSW7 fail. Is present, the voltage is input to the inverting terminal side input of the level shifter 22, so that the output voltage Vout ≠ VREF.

  Therefore, when the output voltage Vout = VREF, the determination is affirmative and the process proceeds to step 248. In step 248, there is no abnormality in the voltage detection operation of the maximum range of the level shifter 22 (and the A / D converter), and the low potential side SW And it determines with there being no failure of the test switch TSW7, and complete | finishes this process. On the other hand, if the output voltage Vout is not VREF, the result is negative and the process proceeds to step 250. In step 250, there is an abnormality in the voltage detection operation of the maximum range of the level shifter 22 (and the A / D converter), and the low potential side SW and It is determined that there is a failure in the test switch TSW7 (or the voltage detection operation of the maximum range of the level shifter 22 (and A / D converter), either the low potential side SW or the test switch TSW7), and this process is terminated.

  As described above, in the semiconductor circuit 15 of the battery monitoring system 10 of this embodiment, the voltage supply unit 26 that supplies the VSS (ground) potential to the inverting terminal side input of the level shifter 22 and the voltage supply unit that supplies the voltage VREF. 28 is further provided, it can be confirmed whether the detection operation of the level shifter 22 (level shifter 30) and the A / D converter is normally performed.

  Therefore, the battery monitoring system 10 of the present embodiment can more appropriately self-diagnose a failure (leakage and sticking in the on state) of the low potential side SW and the high potential side SW of the cell selection SW 20.

  Note that the potential supplied by the voltage supply unit 26 is preferably a ground potential of 0 V (voltage value on the low potential side of the cell C1C1). In the present embodiment, the test switch TSW6 is turned on and the ground potential is supplied from the voltage supply unit 26 in the processing of steps 240 to 250 described above. However, when the supplied potential is not the ground potential, the output voltage Vout However, there is a case where it is not possible to distinguish whether the output voltage Vout is not equal to VREF due to the abnormal operation of the level shifter 22 and the failure of the low potential side SW and the test switch TSW7. On the other hand, when the ground potential is supplied as in the present embodiment, the output voltage Vout ≠ VREF is satisfied only when the level shifter 22 operates abnormally and the low-potential side SW and the test switch TSW7 fail. This is preferable because it can be easily performed.

  In the failure diagnosis (see FIGS. 5 and 6) of the present embodiment, the determination of the failure of the high potential side SW, the operation determination of the intermediate range of the level shifter 22, the determination of the failure of the low potential side SW, the minimum range of the level shifter 22 However, the order of each determination operation is not particularly limited, and the order may be changed.

  Also in the present embodiment, as in the first embodiment, when there is a failure or an abnormal operation as a result of the determination, the processing may be terminated without performing other determination operations.

  The semiconductor circuit 15 and the determination circuit 16 may be formed on the same substrate, or may be formed on separate substrates.

  In the first embodiment and the second embodiment, the high potential voltage and the low potential voltage of the cells C (C1 to C4) are input, and the difference between the high potential voltage and the low potential voltage is calculated as the output voltage Vout. Although the level shifter 30 is used as the difference detection circuit that outputs the signal, the present invention is not limited to this, and the difference detection circuit is not particularly limited as long as it can detect the difference between the high potential voltage and the low potential voltage.

  The number of cells C and voltage values shown in the first embodiment and the second embodiment are examples, and can be changed within a range not departing from the gist of the present invention. Needless to say.

  In the first and second embodiments, the failure determination of the low potential side SW and the high potential side SW of the cell selection SW 20 of the semiconductor circuits 14 and 15 that select the cell C from the battery cell group 12 is performed. Although the case where the operation of the level shifter 22 is determined has been described, the present invention is not limited to this, and the present invention is applicable to a system for measuring a similar voltage other than the cell C.

DESCRIPTION OF SYMBOLS 10 Battery monitoring system 12 Battery cell group 14, 15 Semiconductor circuit 16 Determination circuit 20 Cell selection SW
22 Level shifter 30 Level shifter 24, 26, 28 Voltage supply unit SW0, SW1_1, SW2_1, SW3_1 Low potential side SW
SW1_2, SW2_2, SW3_2, SW4 High potential side SW
TSW5, TSW6, TSW7, TSW8 Test switch

Claims (12)

A plurality of high potential switches respectively connected to a high potential side of each of the plurality of batteries; and a plurality of low potential switches respectively connected to a low potential side of each of the plurality of batteries. A selection circuit that turns on a high-potential switch connected to a high-potential side and a low-potential switch connected to a low-potential side of a battery to be selected when instructed to select any one of
The high potential voltage on the high potential side of the battery selected by the selection circuit is input, and the low potential voltage on the low potential side of the battery selected by the selection circuit is input, and the high potential voltage and the low potential voltage are input. A difference detection circuit that outputs a voltage value of a difference from the potential voltage;
A high potential side voltage supply means for supplying a failure diagnosis voltage to a wiring for inputting the high potential voltage to the level shifter when performing a failure diagnosis of the low potential switch;
A semiconductor circuit comprising   2. The semiconductor circuit according to claim 1, wherein the voltage supplied by the high potential side voltage supply means is a voltage that does not exceed an upper limit value of an output of the difference detection circuit.   3. The semiconductor circuit according to claim 1, further comprising a low-potential side first voltage supply unit configured to supply the failure diagnosis voltage to a wiring for inputting the low-potential voltage to the difference detection circuit. Low potential side second voltage supply means for supplying a voltage having a voltage value smaller than the failure diagnosis voltage to a wiring for inputting the low potential voltage to the difference detection circuit;
Short-circuit means for short-circuiting the output side of the difference detection circuit and the input side to which the low potential voltage is input,
The semiconductor circuit of any one of Claims 1-3 provided with these.   5. The semiconductor circuit according to claim 4, wherein the low-potential-side second voltage supply means supplies a voltage having the same voltage value as the low-potential side of the lowest battery among the plurality of batteries.   When the high-potential switch and the low-potential switch of the selection circuit are all in an off state, the high-potential switch is diagnosed based on a voltage value output from the difference detection circuit; and A failure diagnosis circuit for performing a failure diagnosis of the low potential switch based on a voltage value output from the difference detection circuit when the failure diagnosis voltage is supplied from the high potential side voltage supply means in a fully off state; The semiconductor circuit according to any one of claims 1 to 5.   The failure diagnosis circuit further performs failure diagnosis of the low-potential switch, is supplied with the failure diagnosis voltage from the high-potential-side voltage supply means in the all-off state, and from the low-potential-side first voltage supply means The semiconductor circuit according to claim 6, which is performed based on a voltage value output from the difference detection circuit when a failure diagnosis voltage is supplied.   The failure diagnosis circuit performs failure diagnosis of the difference detection circuit in the all-off state, the failure diagnosis voltage is supplied from the high potential side voltage supply means, and the failure is supplied from the low potential side first voltage supply means. The voltage value output from the difference detection circuit when a diagnosis voltage is supplied, the failure diagnosis voltage is supplied from the high-potential-side voltage supply means in the all-off state, and the difference is supplied by the short-circuit means. The voltage value output from the difference detection circuit when the output side of the detection circuit and the input side to which the low potential voltage is input are short-circuited, and the failure from the high potential side voltage supply means in the all-off state And a voltage value output from the difference detection circuit when a voltage having a voltage value smaller than the failure diagnosis voltage is supplied from the low potential side second voltage supply means. Z Performed, the semiconductor circuit according to claim 6 or claim 7.   The difference detection circuit outputs the voltage value of the difference between the high potential voltage and the low potential voltage while the high potential voltage is input to the non-inverting terminal and the low potential voltage is input to the inverting terminal. The semiconductor circuit according to claim 1, wherein the semiconductor circuit is a level shifter. A plurality of batteries connected in series;
The semiconductor circuit according to any one of claims 1 to 9, further comprising a selection circuit that selects any one of the plurality of batteries.
A semiconductor device comprising: A plurality of high potential switches respectively connected to a high potential side of each of the plurality of batteries; and a plurality of low potential switches respectively connected to a low potential side of each of the plurality of batteries. A selection circuit that turns on the high potential switch connected to the high potential side of the battery to be selected and the low potential switch connected to the low potential side when instructed to select any one of A high potential voltage on the high potential side of the battery selected by the selection circuit, and a low potential voltage on the low potential side of the battery selected by the selection circuit are input, and the high potential voltage A differential detection circuit that outputs a voltage value that is a difference from the low potential voltage and a wiring for inputting the high potential voltage to the differential detection circuit when performing a fault diagnosis of the low potential switch. Supply voltage In a semiconductor circuit having a high-potential voltage supply means that the,
A first step of detecting the output of the difference detection circuit by turning off the high potential switch and the low potential switch of the selection circuit, and the output of the difference detection circuit detected by the first step, A second step of determining that the high-potential switch has not failed when the value is within a predetermined range that is considered to be 0, and a fault diagnosis step of the high-potential switch,
All of the high potential switch and the low potential switch of the selection circuit are turned off, and the failure diagnosis voltage is input to the differential detection circuit by the high potential side voltage supply means. A third step of detecting the output of the difference detection circuit, and when the output of the difference detection circuit detected by the third step is within a predetermined range, A fourth step of determining that the potential switch has not failed, and a failure diagnosis step of the low potential switch,
A fault diagnosis method comprising: A plurality of high potential switches respectively connected to a high potential side of each of the plurality of batteries; and a plurality of low potential switches respectively connected to a low potential side of each of the plurality of batteries. A selection circuit that turns on the high potential switch connected to the high potential side of the battery to be selected and the low potential switch connected to the low potential side when instructed to select any one of A high potential voltage on the high potential side of the battery selected by the selection circuit, and a low potential voltage on the low potential side of the battery selected by the selection circuit are input, and the high potential voltage A differential detection circuit that outputs a voltage value that is a difference from the low potential voltage and a wiring for inputting the high potential voltage to the differential detection circuit when performing a fault diagnosis of the low potential switch. Supply voltage A fault diagnosis program to be executed by the high-potential-side voltage supply means that, the high voltage switch and the process of diagnosing a failure of the low potential switching of the semiconductor circuit provided with the computer,
The first step of detecting the output of the difference detection circuit by turning off the high potential switch and the low potential switch of the selection circuit, and the output of the difference detection circuit detected by the first step is 0 A second step of determining that the high-potential switch has not failed when the value is within a predetermined range that is considered to be, a fault diagnosis step of the high-potential switch,
The high potential switch and the low potential switch of the selection circuit are turned off, and the failure diagnosis voltage is supplied to the wiring for inputting the high potential voltage to the difference detection circuit by the high potential side voltage supply means. A third step of detecting the output of the difference detection circuit; and if the output of the difference detection circuit detected by the third step is a value within a predetermined range, the low potential A fourth step of determining that the switch has not failed, and a failure diagnosis step of the low potential switch,
A failure diagnosis program for causing a computer to execute a process comprising:

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