JP5959204B2 - Mounting state determination device and mounting state determination method - Google Patents

Description

  The present invention relates to a mounting state determination device and a mounting state determination method for determining a mounting state and a non-mounting state of a capacitor in a circuit in which a plurality of capacitors are connected in parallel.

  As this type of mounting state determination method, a bypass capacitor mounting / non-mounting inspection method (hereinafter also referred to as “mounting inspection method”) disclosed by the applicant in Japanese Patent Application Laid-Open No. 2004-221574 is known. In this mounting inspection method, when inspecting whether or not a bypass capacitor (hereinafter also simply referred to as “capacitor”) is mounted between two solder pads, a probe (hereinafter referred to as “ The first probe) is brought into contact with the solder pad on the GND pattern side, and one of the two probes connected to the voltmeter (hereinafter also referred to as “second probe”) is brought into contact with the solder pad on the power supply pattern side. Let Next, the other of the two probes connected to the voltmeter (hereinafter also referred to as a “third probe”) is brought into contact with the second probe on the through hole or conductor pattern connected to the solder pad on the power supply pattern side. Contact a position away from the position. Subsequently, a voltage is generated in the voltage generator, and the voltage is supplied to the solder pad on the GND pattern side via the first probe. In this case, when a capacitor is mounted between the solder pads, a current flows between the second probe and the third probe through the capacitor, and therefore the voltage between them is measured by a voltmeter. That is, the voltmeter reading V is V ≠ 0. On the other hand, when the capacitor is not mounted between the solder pads, no current flows between the second probe and the third probe, so the reading V of the voltmeter is V = 0. That is, in this mounting inspection method, it is possible to grasp the mounting and non-mounting of the capacitor from the voltmeter reading. In addition, in this mounting inspection method, when a plurality of capacitors are connected in parallel, it is possible to individually grasp the mounting and non-mounting of each capacitor by inspecting each capacitor according to the above procedure. Yes.

  On the other hand, in this method, since it is necessary to bring each probe into contact with a solder pad for mounting each capacitor, and a through hole or a conductor pattern connected to the solder pad, all of a plurality of capacitors connected in parallel These solder pads, through-holes, and conductor patterns must be exposed on the surface of the substrate in order to grasp the mounting and non-mounting individually. For this reason, it may be difficult to perform an inspection by this mounting inspection method on a substrate on which they are not exposed (for example, an internal substrate in which a capacitor or a conductor pattern is internally provided).

  As a technique capable of solving such problems, the applicant has developed the following new mounting state determination method. In this mounting state determination method, an AC signal is supplied while changing the frequency to a circuit to be determined in which a plurality of capacitors are connected in parallel, and both signals are detected based on the detection signal and the AC signal detected at that time. Is measured at each frequency. Next, an upper limit value obtained by adding a predetermined value to a measured value for each frequency measured in the same procedure for a non-defective circuit in which each capacitor is correctly mounted, and a lower limit obtained by subtracting a predetermined value from each measured value A reference range defined by values is defined, and it is determined whether or not each measurement value measured for the circuit to be determined is within this reference range. Here, in a circuit in which a plurality of capacitors are connected in parallel, the number of capacitors is the same as the number of capacitors depending on each capacitor and an inductance component equivalent to each capacitor (a conductor pattern connected to the capacitor corresponds to this). Is formed. Further, when the capacitance and inductance values of the capacitors are different, the resonance frequency of each resonance circuit is different.

  On the other hand, when an AC signal is supplied to such a circuit having a plurality of resonance circuits while changing the frequency as described above, the phase difference rapidly increases at a frequency close to each resonance frequency of each resonance circuit. It is known that a turning point (reversing) (hereinafter, this point is also referred to as a “turning point”) appears. For this reason, for example, when one of the capacitors to be mounted on the circuit is not mounted, a turning point does not appear at a frequency close to the resonance frequency of the resonance circuit constituted by the capacitor, and the measured value is out of the reference range. It becomes. For this reason, in this new mounting state determination method, each capacitor is mounted by determining whether or not the measured value of the phase difference at the frequency at which the turning point should appear (frequency close to the resonance frequency) is within the reference range. Even when a solder pad or the like for exposure is not exposed on the surface of the substrate, it is possible to discriminate between mounting and non-mounting.

Japanese Unexamined Patent Publication No. 2004-221574 (page 6-7, FIG. 4-5)

  However, the new mounting state determination method developed by the applicant has the following problems to be improved. That is, in this mounting state determination method, it is necessary to measure the phase difference at all frequencies at which turning points should appear (frequency close to each resonance frequency unique to each resonance circuit included in the circuit to be determined). However, since the measurable frequency range of the measurement unit that measures the phase difference is limited, the resonance frequency may be outside the measurable frequency range depending on the configuration of the circuit to be discriminated. There is a problem that it is difficult to accurately determine the mounting state and the non-mounting state, and improvement of this point is desired.

  The present invention has been made to solve such a problem, and a mounting state determination device and a mounting state determination method capable of accurately determining the mounting state and non-mounting state of each capacitor in a circuit in which a plurality of capacitors are connected in parallel. The main purpose is to provide

Mounting state detecting apparatus according to claim 1, wherein to achieve the above object, a plurality of capacitors based on the detection signal detected with the supply of the AC signal to the circuit of the discrimination object to be connected in parallel the determination target circuit A measurement unit that measures electrical parameters for each frequency of the AC signal, and whether each capacitor is in a mounted state or not based on the measured frequency characteristics of the electrical parameters the mounting condition determination apparatus and a processing unit that executes discrimination processing, resistors, and a pseudo inductor circuit in which at least one of the resistor and the capacitor is formed on the variable with a capacitor and an operational amplifier, the determination target A switch for switching connection and non-connection of the pseudo inductor circuit between the circuit and the measurement unit, Each resonance frequency of each resonance circuit including each of the capacitors in the circuit to be discriminated can be changed by switching between connection and non-connection of the pseudo inductor circuit by an operation on the switch, and the pseudo Each resonance frequency can also be changed by an operation on the at least one in a state where the inductor circuit is connected .

Also, mounting state detecting apparatus according to claim 2, wherein, in the mounting state detecting apparatus according to claim 1 Symbol placement, the processing unit, in the determination process, the electrical parameters with an increase of the frequency starts to increase The presence / absence of a turning point is specified, and when each of the specified number of turning points and the number of capacitors to be mounted on the circuit are the same, it is determined that each capacitor is in a mounted state.

Also, mounting state determination method according to claim 3, wherein the electrically in the circuit of the determination target based on a detection signal in which a plurality of capacitors are detected with the supply of the AC signal to the circuit of the discrimination object to be connected in parallel A mounting state determination for measuring a parameter for each frequency of the AC signal and performing a determination process for determining whether each capacitor is in a mounted state or a non-mounted state based on the frequency characteristics of the measured electrical parameter In the method, when measuring the electrical parameter, a pseudo-inductor circuit including a resistor, a capacitor, and an operational amplifier, and at least one of the resistor and the capacitor is formed in a variable type, the circuit to be discriminated, and the A switch that switches connection and disconnection of the pseudo inductor circuit to and from the measurement unit. By switching connection and non-connection of the pseudo-inductor circuit by an operation on the switch, each resonance frequency of each resonance circuit including each capacitor in the circuit to be discriminated is changed, and the pseudo-inductor circuit is connected Each resonance frequency is also changed by an operation on the at least one in the state .

According to a fourth aspect of the present invention, there is provided the mounting state determination method according to the third aspect , wherein in the determination process, the presence / absence of a turning point at which the electrical parameter starts to increase as the frequency increases is specified. Then, when the number of the specified turning points is equal to the number of the capacitors to be mounted on the circuit, it is determined that the capacitors are in a mounted state.

The mounting state determination apparatus according to claim 1 and the mounting state determination method according to claim 3 are used for determination processing for determining a mounting state and a non-mounting state of each capacitor in a determination target circuit in which a plurality of capacitors are connected in parallel. When measuring the frequency characteristics of electrical parameters, each resonance of each resonance circuit that includes each capacitor by switching the connection and disconnection of the pseudo inductor circuit between the circuit to be discriminated and the measurement unit Change the frequency. Therefore, according to this implementation state determination device and a mounting condition determination method, pseudo inductor by switching the circuit connection and non-connection, each resonator within the measurable range of frequencies capable of measuring electrical parameters by the measurement section Can contain the frequency. Therefore, according to the mounting state determination device and the mounting state determination method, it is possible to reliably measure the electrical parameter at the resonance frequency (or a frequency close to the resonance frequency). As a result, the resonance frequency (or the resonance frequency is close to the resonance frequency). In the determination processing performed based on the frequency characteristics of the electrical parameter in (Frequency), it is possible to accurately determine the mounting state and the non-mounting state of each capacitor.

Further, according to the mounting state determination method of mounting state detecting apparatus according to claim 1, wherein and according to claim 3, resistors, that at least one of a resistor and a capacitor with a capacitor and an operational amplifier is present use pseudo inductor circuit of the variable With the pseudo inductor circuit connected , the inductance of the pseudo inductor circuit can be changed by operating at least one of the variable resistance and the variable capacitor to change each electrical parameter (resistance value or capacitance). Can be changed arbitrarily. Therefore, according to the mounting state determination device and the mounting state determination method, for example, when performing determination processing for a plurality of types of determination target circuits, the inductors having different inductances are exchanged according to the types of determination target circuits. Compared with the configuration and method to be used, the processing efficiency can be sufficiently improved because the inductor is not required to be replaced.

Further, in the mounting state determination device according to claim 2 and the mounting state determination method according to claim 4 , in the determination process, the presence or absence of a turning point at which the electrical parameter starts to increase as the frequency increases is specified and specified. When the number of turning points and the number of capacitors to be mounted on the circuit are the same, it is determined that each capacitor is mounted. Therefore, according to the mounting state determination apparatus and the mounting state determination method, for example, when the measured value of the electrical parameter and the capacitor at the frequency at which the turning point should appear (frequency close to the resonance frequency) are correctly mounted, Unlike the configuration and method for comparing the value of the phase difference to be measured at the frequency (predetermined reference value), since it is not necessary to specify the reference value, when performing discrimination processing for multiple types of circuits The processing efficiency can be further improved.

1 is a configuration diagram illustrating a configuration of a mounting state determination device 1. FIG. 3 is a perspective view of a circuit board 13. FIG. It is the WW sectional view taken on the line in FIG. 2 is an equivalent circuit diagram equivalently representing a circuit C constituted by conductor patterns 11 and 12 and capacitors 21a to 21c on a circuit board 13. FIG. It is a circuit diagram of the pseudo inductor circuit 2a. It is a frequency characteristic figure which shows the phase difference in the circuit C measured in the state which has not connected the pseudo inductor circuit 2a, and the frequency characteristic of an impedance. It is a frequency characteristic figure which shows the frequency characteristic of the phase difference and impedance of the circuit C measured in the state which set the inductance L0 of the pseudo inductor circuit 2a to 100 nH. It is a frequency characteristic figure which shows the frequency characteristic of the phase difference and impedance of the circuit C measured in the state which set the inductance L0 of the pseudo inductor circuit 2a to 10 nH.

  Hereinafter, embodiments of a mounting state determination device and a mounting state determination method will be described with reference to the accompanying drawings.

  First, the configuration of the mounting state determination device 1 will be described with reference to FIG.

  As shown in FIG. 1, the mounting state determination apparatus 1 includes a measurement unit 2, a pseudo inductor circuit 2a, a switch 2b, a storage unit 3, a processing unit 4, and a display unit 5, and a pair of circuit boards 13 shown in FIG. Mounting state (each capacitor 21a to 21c is a capacitor 21 when not distinguished from each other) (hereinafter, also referred to as "capacitor 21") to be connected in parallel by the conductor patterns 11 and 12 (three in this example as an example). Whether it is mounted or not mounted). In this case, the conductor patterns 11 and 12 are formed on the circuit board 13 in a predetermined pattern shape as shown in FIG. In this example, as an example, the conductor pattern 11 is formed in a planar pattern shape as an inner layer ground pattern of the circuit board 13. On the other hand, the conductor pattern 12 is formed in a linear pattern shape as a power line. Moreover, each capacitor | condenser 21a-21c is connected to the position prescribed | regulated previously in each conductor pattern 11 and 12, as shown to FIG. In this case, as an example, each of the capacitors 21 a to 21 c is connected to the conductor pattern 11 via the via 14 a and the land 15, and is connected to the conductor pattern 12 via the via 14 b and the land 15. Hereinafter, when the vias 14a and 14b are not particularly distinguished, they are also referred to as “via 14”.

  As shown in FIGS. 1 and 2, the measurement unit 2 has a pair of measurement points P1 and P2 defined on the conductor patterns 11 and 12 via a pair of probes 6 and 7, respectively (in this example, as shown in FIG. 2, the measurement points P <b> 1 and P <b> 2 are defined on the land 15 connected to the conductor patterns 11 and 12 through the vias 14 a and 14 b. Further, the measuring unit 2 is connected to the conductor patterns 11 and 12 from the probes 6 and 7, that is, to the circuit C (see FIGS. 2 and 3) configured by the conductor patterns 11 and 12 and the capacitors 21 a to 21 c. , While supplying the AC signal for measurement (as an example, an AC constant current, hereinafter also referred to as “measurement signal S1”) while sweeping (changing) the frequency, the conductor patterns 11 and 12 are supplied accordingly. A detection signal S2 (an AC voltage in this example) generated between them is detected via the probes 6 and 7. The measuring unit 2 measures the phase difference between the phase of the measurement signal S1 and the phase of the detection signal S2 for each frequency. That is, the measuring unit 2 measures a change in phase difference (a frequency characteristic of the phase difference) accompanying a change in the frequency of the measurement signal S1. Further, the measurement unit 2 outputs characteristic data D1 indicating the phase difference (frequency characteristic of the phase difference) measured for each frequency to the processing unit 4.

  The pseudo-inductor circuit 2a is a circuit (simulated inductor) that functions as a pseudo-inductor. As shown in FIG. 5, for example, a fixed resistor 31, a variable resistor 32 (variable resistor), and a variable capacitor 33 are used. (Variable type capacitor) and an operational amplifier 34. In this case, in the pseudo inductor circuit 2a, it is possible to change the inductance L0 by operating at least one of the variable resistor 32 and the variable capacitor 33 to change each electrical parameter (resistance value or capacitance). It has become.

  As shown in FIG. 1, for example, the switch 2b is arranged between the measurement unit 2 and the pseudo inductor circuit 2a, and when the switching operation is performed, between the measurement unit 2 and the circuit C (specifically, Switches between connection and non-connection of the pseudo-inductor circuit 2a between the measurement unit 2 and the probe 6).

  The storage unit 3 is configured by using a semiconductor memory or a hard disk device as an example, and stores an operation program for the processing unit 4 and the like.

  The processing unit 4 is configured using a CPU as an example, and executes a measurement process that causes the measurement unit 2 to perform the above-described measurement of the frequency characteristics. Further, the processing unit 4 executes a determination process for determining whether each capacitor 21 is in a mounted state or a non-mounted state based on the characteristic data D1 output from the measuring unit 2. In this case, in the determination process, the processing unit 4 executes a specific process for specifying the presence or absence of later described turning points Pt1 to Pt3 in the frequency characteristics, and whether each capacitor 21 is in the mounted state based on the result of the specific process. Determine whether it is not mounted. In addition, the processing unit 4 executes display processing for displaying the result of the discrimination processing on the display unit 5.

  Next, the frequency characteristic of the phase difference for the circuit C (change in the phase difference accompanying the change in the frequency of the measurement signal S1) will be specifically described.

  As shown in FIGS. 2 and 3, a circuit C in which a plurality (three in this example) of capacitors 21 a to 21 c are mounted between the conductor patterns 11 and 12 is expressed as an equivalent circuit shown in FIG. 4. In this equivalent circuit, L1 to L3 are the conductor patterns 11 and 12, and the inductances of the vias 14 that connect the capacitors 21a to 21c and the conductor patterns 11 and 12 (equivalently connected to the capacitors). (Hereinafter referred to as “inductance L” when the inductances L1 to L3 and the inductance L0 of the pseudo inductor circuit 2a are not distinguished from each other).

  Here, when a plurality of capacitors 21a to 21c are connected in parallel as in the circuit C, the capacitors 21a to 21c and the inductance components connected to the capacitors 21a to 21c (inductances L1 to L1 in the above equivalent circuit). L3) constitutes the same number (three in this example) of resonance circuits as the capacitors 21a to 21c. Further, when the capacitance of the capacitor and the value of the inductance L are different, the resonance frequency fs (fs1 to fs3) of each resonance circuit is different (see FIG. 6).

  Even when the capacitors 21a to 21c have the same capacitance, the lengths of the conductor patterns 11 and 12 from the measurement points P1 and P2 to the capacitors 21a to 21c are different, and the inductance L is different. Therefore, due to this, the resonance frequency fs of each resonance circuit constituted by each of the capacitors 21a to 21c and each inductance component is different.

  An AC signal as a measurement signal S1 is supplied to the circuit C having a plurality of resonance circuits having different resonance frequencies fs while changing the frequency, and a detection signal S2 generated along with the supply of the measurement signal S1 When the phase difference (electrical parameter for the circuit C) between the phase of the measurement signal S1 and the phase of the measurement signal S1 is measured, the frequency characteristic of the phase difference (change in phase difference accompanying the change in the frequency of the measurement signal S1) Are the turning points Pt1 to Pt3 at which the phase difference suddenly (at a rate of increase higher than a predetermined rate of increase) at a frequency close to each resonance frequency fs of each resonance circuit (see FIG. 6; hereinafter, when not distinguished) Also called “turning point Pt”. That is, the same number of turning points Pt as the number of capacitors (the number of resonance circuits) appear in the frequency characteristics of the phase difference.

  In the frequency characteristic diagram shown in FIG. 6 (waveform curve CL1 indicated by a solid line in the figure), the capacitance of the capacitor 21a is 1 μF, the capacitance of the capacitor 21b is 220 nF, and the capacitance of the capacitor 21c in the above equivalent circuit. When the inductances L1 to L3 are 12 nH, 3 nH, and 2 nH at 100 nF, the frequency characteristics of the phase difference between the phase of the measurement signal S1 measured by the measurement unit 2 and the phase of the detection signal S2 are shown.

  As apparent from the frequency characteristic diagram of FIG. 6, the frequency characteristic of the phase difference for the circuit C (equivalent circuit of FIG. 4) in which the capacitors 21 a to 21 c are correctly mounted has the same number as the number of capacitors 21 a to 21 c ( In this example, three turning points Pt1 to Pt3 appear at frequencies close to the resonance frequencies fs1 to fs3 (specifically, frequencies slightly lower than the resonance frequencies fs1 to fs3, respectively). When the capacitances of the capacitors 21a to 21c are different from each other as in this example, in principle, the resonance frequency fs corresponding to the capacitor 21 having a smaller capacitance becomes higher.

Assuming that the rate of increase is R1, the frequency of the measurement signal S1 is fm (Hz), and the phase difference is θ (°), the rate of increase R1 can be defined by the following equation (1) as an example. it can.
R1 = α × Δθ / Δ (log ₁₀ fm)... Formula (1)
(Α is a coefficient, and in the example of FIG. 6, 0.0067: Δ is a sign indicating an increase)
In this case, in the mounting state determination device 1 and the mounting state determination method, as an example, when the rate of increase R1 is 1.73 (tan 60 °) or more, that is, as shown in FIG. 6, the frequency is “log ₁₀ ”. A waveform curve CL1 indicating a change in phase difference accompanying a change in frequency is drawn on an XY plane defined by a coordinate axis (X axis) indicated by (common logarithm) and a coordinate axis (Y axis) indicating a phase difference by “°”. Sometimes, the turning point Pt is a point on the waveform curve CL1 at which the slope of the tangent in the waveform curve CL1 is 60 ° or more.

  Further, in the frequency characteristics of the phase difference when any one of the capacitors 21a to 21c is in the non-mounted state, only the turning point Pt corresponding to the mounted capacitor 21 appears, and the switching corresponding to the unmounted capacitor 21 is performed. The point Pt does not appear. Therefore, the turning point Pt in the frequency characteristic of the phase difference is specified, the number of the specified turning points Pt (hereinafter also referred to as “specific number”) and the number of capacitors 21 to be mounted (hereinafter also referred to as “specified number”). , It is possible to determine whether each capacitor 21 is in a mounted state or a non-mounted state. Specifically, when the specific number and the specified number are the same, it is determined that each capacitor 21 is in a mounted state, and when the specific number is less than the specified number, the same number of capacitors 21 as the number of the difference values. Is determined to be in a non-mounted state.

  Here, as described above, the smaller the capacitance of the capacitor 21, the higher the resonance frequency fs. Therefore, depending on the configuration of the circuit C, the frequency at which the turning point Pt appears (frequency close to the resonance frequency fs) is the measurement unit 2. May exceed the frequency range (hereinafter also referred to as “measurable frequency range A”: see FIG. 6) in which the phase difference (electrical parameter) can be measured. It becomes difficult to perform the discrimination process by the above method of specifying the number and comparing it with the specified number. In this case, the resonance frequency fs decreases as the inductance L increases. For this reason, in this mounting state determination device 1, it is possible to change each resonance frequency fs so that each resonance frequency fs falls within the measurable frequency range A of the measurement unit 2 using this characteristic. ing. Specifically, when the processing unit 4 executes the specific process based on the frequency characteristic measured for the non-defective circuit board 13 on which each capacitor 21 to be mounted is correctly mounted, the turning point Pt is specified. When the number is less than the specified number, or when the turning point Pt is not specified (when the specified number is 0), the resonance frequency fs may exceed the measurable frequency range A of the measurement unit 2 There is. In such a case, by operating the switch 2b, the pseudo inductor circuit 2a is connected between the measurement unit 2 and the circuit C via the probe 6 to reduce (change) the height of the resonance frequency fs. Thus, the resonance frequency fs is stored in the measurable frequency range A of the measurement unit 2.

  On the other hand, the larger the inductance L, the smaller the change in the phase difference at each resonance frequency fs (particularly the phase difference in the high frequency region), making it difficult to specify the turning point Pt. For this reason, when the inductance L0 is defined to be larger than necessary, even if each resonance frequency fs is within the measurable frequency range A of the measurement unit 2 as shown by the solid line in FIG. Identification becomes difficult, and the discrimination processing by the above method becomes difficult. In this mounting state discriminating apparatus 1, since the pseudo inductor circuit 2a including the variable resistor 32 and the variable capacitor 33 is adopted, at least one of the variable resistor 32 and the variable capacitor 33 is operated to set the inductance L0 of the pseudo inductor circuit 2a. It is possible to change. For this reason, in this mounting state discriminating apparatus 1, by changing the inductance L0 of the pseudo-inductor circuit 2a to an appropriate size, as shown by the solid line in FIG. It is possible to increase the change in the phase difference at each resonance frequency fs to the extent that the resonance frequency fs is contained and the turning point Pt can be specified.

  Next, the mounting which discriminate | determines using the mounting state determination apparatus 1 whether each capacitor | condenser 21 in the circuit C (refer FIG. 2) in which the three capacitors 21a-21c should be mounted is a mounting state or a non-mounting state. The state determination method will be described with reference to the drawings.

  The conductor patterns 11 and 12, the via 14, and the capacitors 21a to 21c constituting the circuit C are represented by the equivalent circuit shown in FIG. 4 as described above, and the capacitors 21a to 21c shown in FIG. Are 1 μF, 220 nF, and 100 nF, respectively, and the inductances L1 to L3 are 12 nH, 3 nH, and 2 nH, respectively.

  First, a preliminary test is performed on the circuit C on the non-defective circuit board 13 on which the three capacitors 21a to 21c are correctly mounted using the mounting state determination device 1. In this preliminary test, the processing unit 4 executes a measurement process when the mounting state determination apparatus 1 is instructed to start the process. In this measurement process, the processing unit 4 causes the measurement unit 2 to measure frequency characteristics. In this case, the measurement unit 2 measures and measures the phase difference between the phase of the measurement signal S1 input and output via the probes 6 and 7 and the phase of the detection signal S2 for each frequency of the measurement signal S1. The characteristic data D1 indicating the frequency characteristic is output to the processing unit 4.

  Next, the processing unit 4 executes a discrimination process. In this determination process, the processing unit 4 is configured so that the capacitors 21a to 21c are mounted or not mounted in the circuit C based on the frequency characteristics of the phase difference specified by the characteristic data D1 output from the measuring unit 2. Determine if it exists. Specifically, the processing unit 4 executes a specifying process for specifying the presence or absence of a turning point Pt at which the phase difference suddenly starts to increase at an increase rate equal to or higher than a predetermined increase rate as the frequency increases. More specifically, the processing unit 4 has a waveform curve CL1 in which the rate of increase R1 defined by the above formula (1) is 1.73 or more, that is, the waveform curve CL1 in which the slope of the tangent line in the waveform curve CL1 is 60 ° or more. When the upper point is searched and such a point is detected, the point is specified as the turning point Pt.

  Next, the processing unit 4 executes a discrimination process, and compares the number of specified turning points Pt (specific number) with the number of capacitors 21a to 21c to be mounted (specified number: 3 in this example). In this case, as shown in FIG. 6, when the three turning points Pt are specified, that is, when the specific number and the specified number are the same, the processing unit 4 includes the capacitors 21 a to 21 c. It is determined that it is mounted. Next, the processing unit 4 executes display processing and causes the display unit 5 to display the above determination result.

  Here, for example, assuming that the measurable frequency range A of the measuring unit 2 is 100 kHz to 9.5 MHz, the frequency corresponding to the turning point Pt3 shown in FIG. 6 exceeds 9.5 MHz, so this turning point Pt3 It becomes difficult for the measurement unit 2 to measure the phase difference at. As a result, since the processing unit 4 cannot specify the turning point Pt3 in the specifying process and the specified number is “2”, each of the capacitors 21a to 21c is mounted correctly, even though the three capacitors 21a to 21c are correctly mounted. There is a possibility that one of the capacitors 21a to 21c is determined to be in an unmounted state.

  At this time, the user operates the switch 2b to connect the pseudo inductor circuit 2a between the measurement unit 2 and the circuit C via the lobe 6 and reduce the height of each resonance frequency fs ( change). Next, the processing unit 4 is caused to execute the above-described measurement process, identification process, and determination process again. In this case, even if each resonance frequency fs falls within the measurable frequency range A due to the connection of the pseudo inductor circuit 2a, if the inductance L0 of the pseudo inductor circuit 2a is too large, as shown in FIG. The change in the phase difference at the resonance frequency fs (for example, the region B shown in the figure) becomes small. At this time, even in the specific process executed again, the processing unit 4 cannot specify the turning point Pt3, and the processing unit 4 determines whether or not the three capacitors 21a to 21c are correctly mounted. In the process, it is determined that one of the capacitors 21a to 21c is in an unmounted state.

  In such a case, the user operates one or both of the variable resistor 32 and the variable capacitor 33 in the pseudo-inductor circuit 2a to lower the inductance L0 of the pseudo-inductor circuit 2a. The process, the specific process, and the determination process are executed again. In this case, due to the decrease in the inductance L0, for example, as shown in FIG. 8, each resonance frequency fs falls within the measurable frequency range A and each turning point Pt1 to Pt3 can be specified. When the phase difference at is changed, the processing unit 4 specifies the three turning points Pt1 to Pt3 in the specifying process, and determines that the capacitors 21a to 21c are in the mounted state in the determining process. Thus, the preliminary test is completed.

  Next, the measurement process, the identification process, and the discrimination process for the circuit C in the circuit board 13 to be discriminated are executed. In this case, as described above, by connecting the pseudo inductor circuit 2a in which the inductance L0 is changed, each resonance frequency fs in the circuit C to be discriminated falls within the measurable frequency range A, and each of the turning points Pt1 to Pt3. The phase difference at each resonance frequency fs changes to such an extent that it can be specified. For this reason, as a result of accurately specifying the presence or absence of all the turning points Pt1 to Pt3 in the specifying process, the mounted state and the non-mounted state of each capacitor 21a to 21c are accurately determined in the determining process.

  The configuration and method for determining that each capacitor 21 is in the mounted state when the number of turning points Pt is the same as the specified number (the number of capacitors 21 provided in the circuit C) have been described above. When the resonance frequency fs (resonance frequency fs when the pseudo-inductor circuit 2a is connected) is known in advance, the processing at the resonance frequency fs known in advance is performed without executing the process of specifying the turning point Pt. A configuration and method for comparing the measured value of the phase difference with a predetermined reference value and determining that the capacitor 21 corresponding to the resonance frequency fs is mounted when the measured value is equal to or less than the reference value, for example. It can also be adopted.

As described above, in the mounting state determination device 1 and the mounting state determination method, the measurement signal S1 used for the determination process for determining the mounting state and the non-mounting state of each capacitor 21 in the circuit C in which the plurality of capacitors 21 are connected in parallel. When measuring the frequency characteristic of the phase difference (electrical parameter) between the circuit C and the detection signal S2, each capacitor is switched by switching between connection and non-connection of the inductor (pseudo inductor circuit 2a) between the circuit C and the measurement unit 2. Each resonance frequency fs of each resonance circuit including 21 is changed. For this reason, according to the mounting state determination apparatus 1 and the mounting state determination method, by switching connection and non-connection of the inductor,
Each resonance frequency fs (each frequency close to each resonance frequency fs at which each turning point Pt appears) can be stored in a measurable frequency range A in which the phase difference (electrical parameter) can be measured by the measurement unit 2. Therefore, according to the mounting state determination device 1 and the mounting state determination method, the phase difference at each turning point Pt (frequency close to the resonance frequency fs) can be reliably measured. As a result, the phase difference at each turning point Pt can be measured. In the determination process performed based on the frequency characteristics, the mounting state and the non-mounting state of each capacitor 21 can be accurately determined.

  Further, according to the mounting state determination apparatus 1 and the mounting state determination method, the pseudo-inductor circuit 2a including the variable resistor 32, the variable capacitor 33, and the operational amplifier 34 is used as an inductor, so that at least the variable resistor 32 and the variable capacitor 33 are included. The inductance L0 of the pseudo-inductor circuit 2a can be arbitrarily changed simply by operating one of them to change each electrical parameter (resistance value or capacitance). For this reason, according to the mounting state determination apparatus 1 and the mounting state determination method, for example, when performing the determination process for a plurality of types of circuits C, the configuration is such that an inductor having a different inductance is exchanged according to the type of the circuit C. Compared with the method, the processing efficiency can be sufficiently improved because the inductor is not required to be replaced.

  Further, in the mounting state determination device 1 and the mounting state determination method, in the determination process, the presence or absence of a turning point Pt at which an electrical parameter starts to increase with an increase in frequency is specified, and the number and circuit of the specified turning points Pt are determined. When the number of capacitors 21 to be mounted on C is the same, it is determined that each capacitor 21 is mounted. Therefore, according to the mounting state determination device 1 and the mounting state determination method, for example, the measured value of the phase difference (electrical parameter) at the frequency at which the turning point Pt should appear (the frequency close to the resonance frequency fs) and the capacitor 21 are Unlike configurations and methods that compare phase difference values (predefined reference values) that should be measured at that frequency when correctly implemented, there is no need to specify reference values, so multiple types of It is possible to further improve the processing efficiency when executing the discrimination processing for the circuit C.

  The mounting state determination device 1 and the mounting state determination method are not limited to the above configuration and method. For example, the example using the pseudo-inductor circuit 2a capable of changing the inductance L0 has been described above. However, by switching the connection and non-connection of the pseudo-inductor circuit in which the inductance L0 is defined (fixed) to one value in advance, each capacitor is switched. It is also possible to adopt a configuration and method for changing each resonance frequency fs of each resonance circuit including 21. Further, instead of the pseudo-inductor circuit 2a, a configuration and a method using a coil with another fixed inductance (another example of an inductor) may be employed.

  Further, a phase difference (an example of an electrical parameter) between the phase of the measurement signal S1 and the phase of the detection signal S2 is measured for each frequency of the measurement signal S1, and a change in the phase difference (a phase difference) associated with the change in frequency is measured. The configuration and the method for executing the discrimination processing based on the frequency characteristics) have been described above, but the impedance between the measurement points P1 and P2 (another example of the electrical parameter) is changed for each frequency while changing the frequency of the measurement signal S1. It is also possible to employ a configuration and a method in which a determination process is performed based on a change in impedance accompanying a change in frequency by measuring (frequency characteristics of impedance). Hereinafter, this configuration and method will be described. In the following description, the same components as those in the mounting state determination device 1 and the mounting state determination method described above are denoted by the same reference numerals, and redundant description is omitted.

  First, the frequency characteristic of the impedance of the circuit C (impedance change accompanying a change in the frequency of the measurement signal S1) will be described. The frequency characteristic diagram shown in FIG. 6 (the waveform curve CL2 indicated by a broken line in the figure) represents the frequency characteristic of the impedance measured by the measurement unit 2 at the measurement points P1 and P2 of the equivalent circuit (see FIG. 4). Yes. As is clear from this frequency characteristic diagram, the impedance frequency characteristic of the circuit C in which the capacitors 21a to 21c are correctly mounted has a sudden (preliminary) impedance at a frequency close to each resonance frequency fs of each resonance circuit (in advance). Three turning points Pt4 to Pt6 (the same number as the number of capacitors 21a to 21c) that turn upward (with a rising rate equal to or higher than a predetermined rising rate) (see FIG. 6; hereinafter, also referred to as “turning point Pt” when not distinguished) Appears.

Assuming that the increase rate is R2, the frequency of the measurement signal S1 is fm (Hz), and the impedance is Z (Ω), the increase rate R2 can be defined by the following equation (2) as an example. .
R2 = β × Δ (log ₁₀ Z) / Δ (log ₁₀ fm)... Formula (2)
(Β is a coefficient, 3.29 in the example of FIG. 6, 6.62 in the example of FIG. 7, 4.45 in the example of FIG. 8: Δ is a code indicating an increase)
In this case, in the mounting state determination device 1 and the mounting state determination method, as an example, when the rate of increase R2 is 1.73 (tan 60 °) or more, that is, as shown in FIG. 6, the frequency is “log ₁₀ ”. When a waveform curve CL2 indicating a change in impedance accompanying a change in frequency is drawn on an XY plane defined by a coordinate axis (X axis) indicated by (common logarithm) and a coordinate axis (Y axis) indicated by "log ₁₀ ". Further, a point on the waveform curve CL2 at which the slope of the tangent line in the waveform curve CL2 is 60 ° or more is set as a turning point Pt.

  Further, only the turning point Pt corresponding to the capacitor 21 in the mounted state appears in the frequency characteristics of the impedance when any of the capacitors 21a to 21c is in the non-mounted state, and the turning point corresponding to the capacitor 21 in the non-mounted state. Pt does not appear. For this reason, the turning point Pt in the frequency characteristic of the impedance is specified, and the number of specified turning points Pt (specific number) is compared with the number of capacitors 21 to be mounted (specified number). It is possible to determine whether the mounting state or the non-mounting state.

  Also in this configuration and method, as shown in FIG. 6, the frequency at which the turning point Pt appears (frequency close to the resonance frequency fs) is a measurable frequency range in which the measurement unit 2 can measure the impedance (electrical parameter). When A exceeds A, the pseudo-inductor circuit 2a is connected between the measurement unit 2 and the circuit C to lower the resonance frequency fs, so that the frequency at which the turning point Pt appears in the measurable frequency range A of the measurement unit 2 is included. be able to.

  Further, as indicated by a broken line in FIG. 7, the change in impedance at the frequency at which the turning point Pt should appear is reduced by setting the inductance L0 to a value larger than necessary, and it is variable when it is difficult to specify the turning point Pt. By operating at least one of the resistor 32 and the variable capacitor 33 to change the inductance L0 of the pseudo inductor circuit 2a to an appropriate size, as shown by a broken line in FIG. The frequency at which each turning point Pt should appear (a frequency close to the resonance frequency fs) can be stored, and the change in impedance at that frequency can be increased to the extent that the turning point Pt can be specified. Therefore, also in this configuration and method, the presence / absence of all the turning points Pt1 to Pt3 can be accurately specified in the specifying process. As a result, the mounting and non-mounting states of the capacitors 21a to 21c are accurately determined in the determination process. Can be determined.

  In this example in which the mounted state and unmounted state of the capacitor 21 are determined based on the frequency characteristics of the impedance, the resonance frequency fs corresponding to each capacitor 21 (resonance frequency fs when the pseudo inductor circuit 2a is connected) is also obtained. When it is known in advance, the measured value of the impedance at the resonance frequency fs that is known in advance is compared with a predetermined reference value without executing the process of specifying the turning point Pt. It is also possible to employ a configuration and method for determining that the capacitor 21 corresponding to the resonance frequency fs is in the mounted state when is below the reference value.

  In each of the above examples, the pseudo-inductor circuit 2a including the variable resistor 32 and the variable capacitor 33, that is, both the resistor and the capacitor use the variable pseudo-inductor circuit 2a. It is also possible to adopt a configuration and method in which only one of them uses a variable type pseudo inductor circuit.

DESCRIPTION OF SYMBOLS 1 Mounting state identification apparatus 2 Measurement part 2a Pseudo inductor circuit 2b Switch 4 Processing part 21a-21c Capacitor 32 Variable resistance 33 Variable capacitor 34 Operational amplifier A Measurable frequency range C Circuit fm Frequency fs Resonance frequency L0 Inductance Pt1-Pt6 Turning point S1 measurement Signal S2 detection signal

Claims (4)

A measuring unit that measures an electrical parameter of the circuit to be discriminated for each frequency of the AC signal based on a detection signal detected when an AC signal is supplied to the circuit to be discriminated to which a plurality of capacitors are connected in parallel. And a processing unit that executes a determination process for determining whether each capacitor is mounted or not based on the measured frequency characteristic of the electrical parameter. And
A pseudo-inductor circuit including a resistor, a capacitor, and an operational amplifier, and at least one of the resistor and the capacitor is variably formed; and connection and non-connection of the pseudo-inductor circuit between the circuit to be discriminated and the measurement unit A switch for switching the connection,
Each resonance frequency of each resonance circuit including each of the capacitors in the circuit to be discriminated can be changed by switching between connection and non-connection of the pseudo inductor circuit by an operation on the switch, and A mounting state discriminating apparatus configured to be able to change each resonance frequency by an operation on the at least one in a state where a pseudo inductor circuit is connected . In the determination process, the processing unit specifies whether or not there is a turning point at which the electrical parameter starts to increase as the frequency increases, and the number of the specified turning points and the capacitor to be mounted on the circuit claim 1 Symbol placement of the mounting state detecting apparatus wherein it is determined that the capacitor is mounted state when the number and the same number of. Based on the detection signal detected along with the supply of the AC signal to the circuit to be discriminated in which a plurality of capacitors are connected in parallel, the electrical parameters of the circuit to be discriminated are measured for each frequency of the AC signal, A mounting state determination method for executing a determination process for determining whether each of the capacitors is in a mounted state or a non-mounted state based on the measured frequency characteristic of an electrical parameter,
When measuring the electrical parameter, a pseudo-inductor circuit that includes a resistor, a capacitor, and an operational amplifier and at least one of the resistor and the capacitor is variably formed, and between the discrimination target circuit and the measurement unit Each of the capacitors in the circuit to be discriminated by switching between connection and non-connection of the pseudo-inductor circuit by an operation on the switch, using a switch that switches connection and non-connection of the pseudo-inductor circuit to A mounting state determination method in which each resonance frequency of each resonance circuit to be changed is changed, and each resonance frequency is also changed by an operation on the at least one in a state where the pseudo inductor circuit is connected . In the determination process, it is determined whether or not there is a turning point at which the electrical parameter increases as the frequency increases, and the number of the specified turning points and the number of capacitors to be mounted on the circuit are the same. The mounting state determination method according to claim 3 , wherein it is determined that each of the capacitors is in a mounted state.

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