JP2010008178A - Apparatus, method and program for controlling connector connection - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus, a method and a program for controlling a connector connection, which reliably determine and treat a state of a terminal between a pair of connectors. <P>SOLUTION: A first printed-circuit board 401 and a second printed-circuit board 402 are mutually connected through connectors 203, 204. A first printed-circuit board side switch 423 is initially configured to select a constant voltage generating section 208, and a current detecting section 215 detects current flowing on the second printed-circuit board 402 side and gives a notice to an malfunction detecting section 223. If the value of the current is within an allowance, first and second printed-circuit board side switches 423, 443 select ordinary circuit 411, 431 sides, otherwise an alarm is output. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a connector connection control device, a connector connection control method, and a connector connection control program for connecting connectors used on a printed circuit board or the like.

  For example, the printed circuit board is connected to a connector of another printed circuit board such as a mother board to supply power and signals between them. The connector is used between various electrical components, but generally, there is a tendency for the size of the connector to be reduced and the types of signals transmitted between printed circuit boards to be increased with the miniaturization of the apparatus. For this reason, various connector connection control devices for confirming whether or not the connectors are electrically connected to each other have been proposed as related techniques of the present invention. In the first related technology, one printed circuit board sends a specific signal pattern to the other printed circuit board via the connector, and the other printed circuit board receives the signal pattern to confirm the connection.

  FIG. 9 shows the configuration of the connector connection control device according to the first related technique. The connector connection control device 100 includes two printed circuit boards, a first printed circuit board 101 and a second printed circuit board 102. The first printed circuit board 101 has a female first connector 103 disposed at the end thereof. In the second printed circuit board 102, a male second connector 104 that can be inserted into and removed from the first connector 103 is disposed at an end facing the first connector 103.

  For ease of explanation, it is assumed that the first printed circuit board 101 is a parent printed circuit board that supplies power, such as a mother board of a personal computer. In the case of this example, the second printed circuit board 102 is a printed circuit board on the child side connected to add a necessary function to the first printed circuit board 101 as a mother board.

  The first printed circuit board 101 includes a first control device 105 for controlling the connection between the first and second connectors 103 and 104, and the second printed circuit board 102 also includes a second control device 105 for this purpose. A control device 106 is provided. In addition, the second printed circuit board 102 includes a control unit 107 that operates in a state where the connection of the pair of connectors 103 and 104 is confirmed. The first control device 105 includes a signal generation unit 108 that generates a signal pattern unique to the control device. The second control device 106 includes a detection unit 109 that detects the signal pattern. ing.

  The other end of the signal transmission line 111 having one end connected to the output side of the signal generation unit 108 is connected to a predetermined engagement portion 112 of the first connector 103. In addition, a pin (terminal) 113 arranged at a position corresponding to the engaging portion (terminal) 112 in the second connector 104 is connected to one end of the signal receiving line 114. The other end of the signal receiving line 114 is connected to an input terminal (not shown) in the detection unit 109.

  The detection unit 109 registers a signal pattern sent from the first control device 105 in advance, and when this arrives, the detection unit 109 outputs a detection signal to the detection determination signal line 116 from an output terminal (not shown). Yes. The detection determination signal line 116 is connected to the control unit 107. Therefore, the control unit 107 can confirm that the first printed circuit board 101 is connected to the second printed circuit board 102 and perform predetermined control on this condition.

  The detection determination signal line 116 is connected to one end of a detection notification line 117 for feeding back a detection result to the first printed circuit board 101 side. The other end of the detection notification line 117 is connected to the other pin 118 of the second connector 104. Another engaging portion 119 of the first connector 103 arranged at a position corresponding to the pin 118 is connected to one end of the notification receiving line 121. The other end of the notification reception line 121 is connected to an input terminal (not shown) of the first control device 105. Thereby, the first control device 105 can confirm that the first printed circuit board 101 and the second printed circuit board 102 are connected, and can perform predetermined control on the condition.

  There has also been proposed a second related technique in which connection between printed circuit boards is confirmed by simply passing a current between both connectors without transmitting such a signal pattern (for example, Patent Document 1). reference).

  FIG. 10 shows a state before connection of the connector connection control device according to the second related technique. The connector connection control device 140 includes two printed circuit boards, a first printed circuit board 141 and a second printed circuit board 142. The first printed circuit board 141 has a female first connector part 143 disposed at the end thereof. In the second printed circuit board 142, a male second connector portion 144 that can be inserted into and removed from the first connector portion 143 is disposed at an end facing the first connector portion 143.

  The first connector portion 143 includes a pin engaging portion 145 used for normal signal transmission, and first and second pin engaging portions 146 and 147 arranged on both sides thereof. Among these, the first pin engaging portion 146 is grounded by the ground wire 148, and the second pin engaging portion 147 is connected to the connection determining portion 151 by the current transmission line 149. The determination result of the connection determination unit 151 is input to the control unit 153 via the determination result output line 152.

  On the other hand, the second connector portion 144 of the second printed circuit board 142 is provided with a plurality of pins 155 for transmitting normal signals corresponding to the pin engaging portions 145. In addition, first and second pins 156 and 157 are arranged at both ends of the place where the plurality of pins 155 are arranged so as to correspond to the first and second pin engaging portions 146 and 147. These first and second pins 156 and 157 are connected by a conductive wire 158.

  In such a connector connection control device 140 according to the second related technology, it is assumed that at least one of them is moved so that the second connector portion 144 is attached to the first connector portion 143 as indicated by an arrow 159. As a result, the first pin engaging portion 146 is electrically connected to the first pin 156, and the second pin engaging portion 147 is electrically connected to the second pin 157. Thereby, the 2nd pin engaging part 147 is connected to the earth by the conducting wire 158, and becomes an earth potential. In this state, the pin engaging portion 145 and the pin 155 are also electrically connected.

The connection determination unit 151 includes a grounded emitter switching transistor for output of a determination result (not shown). The collector of this transistor is connected to a pull-up resistor (not shown) and a determination result output line 152. The gate of the transistor is connected to another pull-up resistor (not shown). For this reason, when the second pin engaging portion 147 is connected to the ground, the gate potential is lowered and the transistor is turned on, and the signal level of the determination result output line 152 is changed from H (high) level to L (low). ) Change to level. The controller 153 inputs the change in the logic level of the determination result output line 152 and determines that the second printed circuit board 142 is connected.
JP 2001-338725 A (paragraphs 0016 to 0022, FIGS. 6 and 7)

  Thus, in the second related technology, a specific signal line between the first printed circuit board 141 and the second printed circuit board 142 is formed by the conductive wire 158 connected between the first and second pins 156 and 157. It is only confirmed whether there is any electrical connection. Also in the first related technology, the detection unit 109 transmits a signal pattern between the signal transmission line 111 and the signal reception line 114, and thus the signal lines of the first connector 103 and the second connector 104 are connected. They are only checking for electrical connections. That is, in both related technologies, even if the connection between the connectors is incomplete, this cannot be detected. Therefore, when a potential change occurs due to an incomplete connection between a pin and a terminal such as an engaging portion between a pair of connectors, this cannot be dealt with conventionally, and a circuit through the connector This has been a cause of reducing the reliability of the operation of the apparatus.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a connector connection control device, a connector connection control method, and a connector connection control program that can reliably determine and process the terminal connection state between a pair of connectors.

  In the present invention, (a) a first substrate including a first connector having a plurality of terminals and constant voltage applying means for applying a constant voltage to an arbitrary terminal of the first connector; ) The second connector having a plurality of terminals connected to the plurality of terminals of the first connector, respectively, and the constant voltage applying means in the second connector. A second substrate having current detecting means for detecting a current flowing in a terminal corresponding to a terminal to which a voltage is applied; and (c) the current detecting means arranged on the first or second substrate. Current value determining means for determining whether the detected current is within a predetermined allowable current value range, and when the current value determining means is determined to be within the allowable current value range, 1 connector and 2nd Connection connector causes provided in the connector connecting the controller and a connector connection control unit that includes a connector connection state determining means for determining the success of the process.

  In the present invention, (a) a first connector in which a plurality of terminals are arranged, a first terminal connected to an arbitrary terminal of the first connector, and alternatively the first terminal described above. A first connector side switch having second and third terminals to be connected, and a constant voltage applying means for applying a constant voltage to the first terminal of the first connector side switch connected to the second terminal. And a first circuit board that includes a normal circuit that is connected to the third terminal of the first connector-side switch and that performs either or both of signal transmission and reception via the third terminal; A second connector having a plurality of terminals connected to each of the plurality of terminals of the first connector, and a first connector side switch in the second connector. Apply constant voltage as described above A second substrate provided with current detecting means for detecting a current flowing through a terminal corresponding to a terminal to which a constant voltage is applied by the stage; and (c) disposed on the first or second substrate described above. A current for determining whether the current detected by the current detecting means is within a predetermined allowable current value range in a state where the first connector side switch connects the first terminal and the second terminal. A value determining means and a connector connection for determining that the connection between the first connector and the second connector is normally performed when it is determined that the current value determining means is within the allowable current value range. When the state determining means and the connector connection state determining means determine that the connection between the first connector and the second connector has been normally performed, the above-described operation is performed for the first connector side switch. It is provided first terminal and a first connector-side switch control unit and the connector connection control unit provided with a for connecting the third terminal to the connector connection control device.

  Further, in the present invention, (a) a constant voltage applying step for applying a constant voltage to an arbitrary terminal of the first connector in which a plurality of terminals are arranged, and (b) a constant voltage applied to the first connector in the constant voltage applying step. Corresponding to an arbitrary terminal of the first connector in the second connector in which a plurality of terminals connected to each of the plurality of terminals of the first connector are arranged in a state where the first connector is applied. A current detection data receiving step for receiving current detection data for detecting a current value flowing through the terminal to be received from a terminal other than the above-mentioned arbitrary terminal of the first connector; and (c) receiving at the current detection data receiving step. A current value determination step for determining whether the current value indicated by the detected current data is within a predetermined allowable range; and (d) the current value detected at the current value determination step is within the allowable range. And without thereby and a warning output step of outputting a warning to the connector connection control method when it is determined.

  Furthermore, according to the present invention, a computer arranged on a first printed circuit board having a first connector having a plurality of terminals arranged therein is used as a connector connection control program as follows: (a) the first printed circuit board described above. From the specific terminal of the second connector of the second printed circuit board that can be inserted into and removed from the first connector, it flows into the second printed circuit board through the terminal of the first connector corresponding to the terminal other than this terminal. Current detection data reception processing for receiving current detection data for detecting the detected current value, and (b) determining whether the current value indicated by the current detection data received in this current detection data reception processing is within a predetermined allowable range And (c) an alarm output process for outputting an alarm when it is determined that the current value detected in the current value determination process is not within the allowable range. It is characterized in.

  As described above, according to the present invention, when a pair of connectors are connected, a voltage is applied between these predetermined terminals to cause a current to flow, and the current value is detected on the receiving side, and this is an allowable value range. It was decided to determine whether it was within. For this reason, it is possible to determine whether or not the connection is performed well as compared with the conventional method in which the presence / absence of conduction is simply determined, and the reliability of the connection can be improved.

  In addition, since the terminals used to check the connection status of the connector can be connected to the normal circuit after that, not only the connector terminals can be used effectively, but also the connection of the terminals themselves used by the normal circuit is determined. The reliability of the circuit operation after the connection of the pair of connectors can be improved.

  Next, the present invention will be described together with embodiments.

  FIG. 1 shows the configuration of the connector connection control device according to the first embodiment of the present invention. The connector connection control device 200 includes a first printed circuit board 201 and a second printed circuit board 202 arranged so as to be freely inserted into and removed from the first printed circuit board 201. The first printed circuit board 201 has a female first connector 203 disposed at the end thereof. In the second printed circuit board 202, a male second connector 204 that can be inserted into and removed from the first connector 203 is disposed at an end facing the first connector 203. In the present embodiment, the first printed circuit board 201 is a parent printed circuit board that supplies power, such as a personal computer motherboard. The second printed circuit board 202 is a printed circuit board on the child side connected to add a necessary function to the first printed circuit board 201 as a mother board.

  The first printed circuit board 201 includes a first control device 205 for controlling the connection between the first and second connectors 203 and 204, and the second printed circuit board 202 also includes a second control device 205 for this purpose. A control device 206 is provided. The second printed circuit board 202 includes a control unit 207 that controls each unit in the circuit board according to the connection state of the pair of connectors 203 and 204. The first control device 205 includes a constant voltage generator 208 that generates a predetermined constant voltage that is set in advance. The output side of the signal line 211 is connected to one end of the signal line 211. The other end of the signal line 211 is connected to a predetermined engaging portion 212 of the first connector 203. Further, a pin (terminal) 213 arranged at a position corresponding to the engaging portion (terminal) 212 in the second connector 204 is connected to one end of the signal line 214. The other end of the signal line 214 is connected to an input terminal (not shown) in the current detection unit 215 arranged in the second control device 206.

  The current detection unit 215 detects a current value flowing from the signal line 214 and outputs current detection data 216 corresponding to the detected current value to one end of the current value notification line 217. The other end of the current value notification line 217 is connected to an input terminal (not shown) of the control unit 207. The current value notification line 217 is connected to one end of a detection notification line 218 for feeding back the detection result to the first printed circuit board 201 side. The other end of the detection notification line 218 is connected to the other pin 219 of the second connector 204. The other engaging portion 221 in the first connector 203 disposed at a position corresponding to the pin 219 is connected to one end of the notification receiving line 222. The other end of the notification reception line 222 is connected to an input terminal (not shown) of the abnormality detection unit 223 of the first control device 205. When an abnormality is detected in the current sent to the second printed circuit board 202, the abnormality detection unit 223 can perform control corresponding to the abnormality. For one of these controls, a constant voltage control line 224 is connected between the abnormality detection unit 223 and the constant voltage generation unit 208.

  The first printed circuit board 201 stores a CPU (Central Processing Unit) and a memory as a storage medium for storing a control program executed by the CPU (not shown). The CPU performs control for confirming connector connection on the first printed circuit board 201 side by executing a control program.

  FIG. 2 shows the configuration of the current detection unit according to this embodiment. The current detection unit 215 includes a current detector 231 that detects a current value flowing from the signal line 214, and an analog-to-digital (A / D) that converts the detection result 232 as an analog value output from the current detector 231 into a digital signal. -Digital) converter 233. The converted current detection data 216 is output to the current value notification line 217 and the detection notification line 218. Here, the current detector 231 can be constituted by, for example, a resistor for passing a current and a voltage measurement circuit for measuring a voltage at both ends of the resistor.

  FIG. 3 shows the configuration of the control unit according to this embodiment. The control unit 207 is output from the current detection data 216 output from the A / D converter 233 illustrated in FIG. 2 via the current value notification line 217 and the reference current value storage unit 241 that stores current values in the allowable range. The comparator 243 for comparing the reference current value data 242 as a digital signal to be inputted, and the comparison output 244 of the comparator 243 are inputted to turn on / off each circuit (not shown) in the second printed circuit board 202 shown in FIG. An in-substrate circuit control unit 245 that performs off-control is provided.

  Here, the comparator 243 outputs a comparison output 244 that turns on each circuit in the second printed circuit board 202 only when a current value in the above-described allowable range with a current value of “0” or more flows. Is output. At this time, the in-board circuit control unit 245 sets each circuit in the second printed circuit board 202 to an energized state, and otherwise sets it to a cut-off state.

  The control unit 207 configured as described above is not necessarily configured by hardware components, and may be configured entirely or partially by software using a CPU or a memory storing a control program (not shown). Good. Of course, when the second printed circuit board 202 is provided with a CPU for performing other processing, this CPU may also be used for the processing of the control unit 207.

FIG. 4 is a diagram for explaining the concept of the allowable range of current values in the present embodiment. The output voltage of the constant voltage generator 208 is V _1, and the resistance value of the voltage drop detection resistor 251 in the current detector 231 is R ₂ . At this time, the voltage V ₂ across the resistor 251 is measured, and the measured current I ₂ of the current detector 231 is obtained. The resistance value at the time of connection of the engaging part 212 of the first connector 203 shown in FIG. 1 and the pin 213 corresponding to this of the second connector 204 is R ₃ .

When the engagement portion 212 and the pin 213 are connected sufficiently satisfactorily, the resistance value R ₃ is approximated to zero. The current I ₂ of the current detector 231 at this time is expressed by the following equation (1).
I ₂ = (R ₂ + R ₃ ) / V ₁ ≈R ₂ / V ₁ (1)

On the other hand, no current flows through the resistor 251 when the engaging portion 212 and the pin 213 are not connected. Therefore, the current I ₂ of the current detector 231 at this time is expressed by the following equation (2).
I ₂ = 0 (2)

In addition to the above, the engaging portion 212 and the pin 213 may be electrically connected in an incomplete state. For example, the engaging portion 212 and the pin 213 are not physically connected, but there are other materials having a certain degree of conductivity between them, or a beard-like conductive material is present. There may be intervening cases. When electrical connection is made in such an incomplete state, a resistance value R ₃ that cannot be regarded as zero exists between the engaging portion 212 and the pin 213. In such a case, the current I ₂ detected by the current detector 231 can be expressed by the following equation (3).
I ₂ = (R ₂ + R ₃ ) / V ₁ >> R ₂ / V ₁ (3)

The state before the first connector 203 and the second connector 204 shown in FIG. 1 are connected is expressed by equation (2), and when the connector is normally connected, it is expressed by (1). When the current I ₂ represented by the expression (3) is detected, there is a high possibility that other engagement portions and pins are not normally connected in the first connector 203 and the second connector 204. . Therefore, the current value in the allowable range in the present embodiment is set to a current range represented by equation (1) and not including the values represented by equations (2) and (3). This is the upper limit value and the lower limit value of the current I ₂ represented by the reference current value data 242 (FIG. 3), and is a value obtained by various experiments. When the current I ₂ is within the allowable current value range, the comparator 243 (FIG. 3) outputs a comparison output 244 (FIG. 3) for turning on each circuit in the second printed circuit board 202. It will be.

On the other hand, as shown in FIG. 1, the current detection data 216 representing the current I ₂ detected by the current detection unit 215 is sent to the detection notification line 218 as it is. Then, the information is input from the notification reception line 222 to the abnormality detection unit 223 of the first control device 205. At this time, the current detection data 216 is transmitted via the pin 219 and the engaging portion 221. Since the current detection data 216 is a digital signal, the signal content does not change even if there is a resistance component in the middle. For this reason, the abnormality detection unit 223 can determine whether or not the first connector 203 and the second connector 204 are connected and whether or not an abnormality has occurred. When the output voltage of the constant voltage generator 208 varies, it is possible to monitor whether or not the voltage output to the signal line 211 shows an abnormal value.

  FIG. 5 shows the state of the connector connection confirmation control on the first printed circuit board side in the first embodiment. This will be described with reference to FIG.

  The CPU arranged on the first printed circuit board 201 side performs a confirmation process as to whether the timing for confirming the connection process with the second printed circuit board 202 has arrived (step S301). For example, if a magnet is disposed on the second connector 204 side and a magnetic sensor is disposed at a predetermined position on the first printed circuit board 201 side, the second printed circuit board 202 has approached for connection. Can be detected. When a power source such as a battery is present on the second printed circuit board 202 side, the potential is detected via a predetermined engaging portion (not shown) by connecting the first connector 203 and the second connector 204. Can detect this timing. Further, this timing is detected by supplying power from the first printed circuit board 201 side to the second connector 204 side and detecting this via a predetermined engagement portion (not shown) of the first connector 203. May be.

  When the timing for confirming the connection process comes by the above method or another method (Y), the CPU operates the constant voltage generator 208 to start its output (step S302). Then, it is determined whether or not the current detection data 216 obtained by the current detection unit 215 on the second printed circuit board 202 side performing the detection operation is received before the time set for a predetermined timeout has elapsed (step S303). Step S304). When the current detection data 216 can be received before the time-out (step S304: N, step S303: Y), the operation of the constant voltage generator 208 is stopped at that time (step S305). Then, the current detection data 216 received in step S303 is analyzed to check whether the current value flowing through the signal line 214 is within the above-described allowable range (step S306). As a result, if the current value flowing through the signal line 214 is within the allowable range (Y), it is determined that the first printed circuit board 201 and the second printed circuit board 202 are normally connected (step S307). ), The process ends (END).

  On the other hand, if the current value is outside the allowable range (step S306: N), it is determined that the connection between the first printed circuit board 201 and the second printed circuit board 202 is incomplete ( Step S308), a predetermined error process is executed (step S309), and the process ends (END). In the error processing, for example, an alarm indicating that the second printed circuit board 202 is to be reconnected is output from the apparatus on the first printed circuit board 201 side. If a timeout occurs in step S304 (Y), the operation of the constant voltage generator 208 is stopped at that time (step S310), and the connection between the first printed circuit board 201 and the second printed circuit board 202 is established. It is determined that it is not completed (step S308). Then, predetermined error processing is executed (step S309), and the processing is ended (END).

  According to the connector connection control apparatus 200 of the embodiment described above, the first control device 105 on the first printed circuit board 201 side has two connection locations of the first connector 203 and the second connector 204. The current is sent and the current detection data 216 is received. For this reason, it is possible to reliably determine the state of the connection location such as other pins of the first connector 203 and the second connector 204. In addition, since the output of the constant voltage generator 208 is performed only when necessary, it contributes to power saving.

  <Modification of the first embodiment>

FIG. 6 shows a modification of the first embodiment described above. In this modified example, a connector normal connection confirmation unit 261 is provided in the second printed circuit board 202 shown in FIG. The allowable voltage output circuit 270 in the connector normal connection confirmation unit 261 outputs an upper limit value V _U and a lower limit value V _D of the allowable voltage corresponding to the current value in the allowable range. Of these, the upper limit value V _U is input to the first comparison terminal of the first comparator 271, and the lower limit value V _D is input to the second comparison terminal of the second comparator 272. The other end of the signal line 214 having one end connected to the pin 213 (FIG. 1) is input to the second comparison terminal of the first comparator 271 and the first comparison terminal of the second comparator 272, respectively. It is like that.

  The first and second comparators 271 and 272 are at the H level when the voltage input to the first comparison terminal is equal to or higher than the voltage input to the second comparison terminal, and are set to the L level at other times. The comparison result signals 273 and 274 are output. These comparison result signals 273 and 274 are input to respective input terminals of the 2-input AND gate 275. From the output terminal of the 2-input AND gate 275, a comparison output 244 that is H level when each circuit in the second printed circuit board 202 shown in FIG. 1 is turned on and is L level at other times is output. It has come to be.

It is assumed that the connector normal connection confirmation unit 261 of such a modification has normally connected the engagement unit 212 shown in FIG. 1 and the pin 213 corresponding thereto. In this case, the voltage at the connection point between the signal line 214 having one end connected to the pin 213 and the resistor 251 is within the range between the upper limit value V _U and the lower limit value V _D of the allowable voltage. Therefore, in this state, the first and second comparators 271 and 272 both output H level signals as the comparison result signals 273 and 274, and the second printed circuit board 202 is output from the output terminal of the two-input AND gate 275. An H level comparison output 244 for turning on each circuit is output.

On the other hand, it is assumed that the engaging portion 212 and the pin 213 corresponding to the engaging portion 212 are not connected, or that the electrical connection is made in a form in which a predetermined resistance exists. In such a case, the voltage at the connection point between the signal line 214 and the resistor 251 is divided by the resistor and the resistor 251, and thus becomes lower than the lower limit value V _D of the allowable voltage. As a result, the comparison result signal 274 output from the second comparator 272 changes to the L level, and the output terminal of the two-input AND gate 275 changes the level of the L-level to turn off each circuit in the second printed circuit board 202. A comparison output 244 is output. The comparison output 244 is not only input to the in-board circuit control unit 245 shown in FIG. 3 but also supplied to the detection notification line 218 shown in FIG. 1 to the abnormality detection unit 223 in the first printed circuit board 201. It may be input.

  According to the modification of the first embodiment, the A / D converter 233 shown in FIG. 2 is unnecessary. Therefore, the connector connection control device 200 can be manufactured at a low cost by this amount.

  In the first embodiment described above and its modifications, the signal lines 211 and 214 may be used as dedicated signal lines for checking the abnormality of the first and second printed circuit boards 201 and 202. However, it can be used in some cases also as a power supply line for supplying power from the first printed circuit board 201 to the second printed circuit board 202.

  <Second Embodiment>

  FIG. 7 shows the configuration of the connector connection control device according to the second embodiment of the present invention. In FIG. 7, the same parts as those in FIG.

  The connector connection control device 400 according to the second embodiment includes a first printed circuit board 401 and a second printed circuit board 402 that can be inserted into and removed from the first printed circuit board 401. The first printed circuit board 401 has a female first connector 203 disposed at the end thereof. The second printed circuit board 402 has a male second connector 204 that can be inserted into and removed from the first connector 203 at an end facing the first connector 203. Also in this embodiment, the first printed circuit board 401 is a parent printed circuit board that supplies power, such as a personal computer motherboard. The second printed circuit board 402 is a child printed circuit board that is connected to add a necessary function to the first printed circuit board 401 as a mother board.

  The first printed circuit board 401 includes a first control device 405 for controlling the connection between the first and second connectors 203 and 204, and the second printed circuit board 402 also includes a second control device 405. A control device 406 is provided. In addition, the second printed circuit board 402 includes a control unit 407 that controls each unit in the circuit board according to the connection state of the pair of connectors 203 and 204.

  The first control device 405 includes a normal circuit 411 as a circuit that transmits and receives signals to and from the second printed circuit board 402 in addition to the constant voltage generator 208. The normal circuit 411 is a circuit that has been conventionally used for communication with the second printed circuit board 402. The first printed circuit board side first signal line 421 having one end connected to the constant voltage generator 208 and the first printed circuit board side second signal line 422 having one end connected to the normal circuit 411 are connected to the first printed circuit board 411. It is connected to one end side of the substrate side switch 423. One end of the signal line 211 is connected to the other end side of the first printed circuit board side switch 423. The first printed circuit board side switch 423 is connected to the abnormality detection unit 223 via the switching control line 424, and the first printed circuit board side switch 423 is the first until the normal connection between the first connector 203 and the second connector 204 is confirmed. After selecting the first printed circuit board side first signal line 421 and confirming the normal connection, the first printed circuit board side second signal line 422 is selected and the switching control of the connection with the signal line 211 is performed. It is like that.

  On the other hand, the second control device 406 includes a normal circuit 431 as a conventional circuit that transmits and receives signals to and from the first printed circuit board 401 in addition to the current detection unit 215. The second printed circuit board side first signal line 441 having one end connected to the current detection unit 215 and the second printed circuit board side second signal line 442 having one end connected to the normal circuit 431 are the second printed circuit board. It is connected to one end side of the side switch 443. One end of a signal line 214 is connected to the other end side of the second printed circuit board side switch 443. The other end of the control line 444 connected to the control terminal of the second printed circuit board switch 443 is connected to the control unit 407. The control unit 407 sends normal connection confirmation data to the control line 444 in a state where the normal connection between the first connector 203 and the second connector 204 is confirmed. In this case, the second printed circuit board side switch 443 The second printed circuit board side second signal line 442 is connected to the signal line 214. In other cases, the second printed circuit board side switch 443 connects the second printed circuit board side first signal line 441 to the signal line 214.

  In the connector connection control device 400 of the second embodiment, the first printed circuit board 401 stores a CPU and a memory as a storage medium for storing a control program executed by the CPU (not shown). Yes. The CPU performs control for confirming connector connection on the first printed circuit board 401 side by executing a control program.

  FIG. 8 shows the control operation on the first printed circuit board side of the connector connection control device in the second embodiment. This will be described with reference to FIG.

  The CPU disposed on the first printed circuit board 401 side instructs the start of the operation of the constant voltage generation unit 208 as an initial setting, and the first printed circuit board side with respect to the first printed circuit board side switch 423. The selection of the first signal line 421 is instructed (step S501). After that, it waits for the current detection data 216 on the second printed circuit board 402 side to be received by the abnormality detection unit 223 via the notification reception line 222 (step S502).

  When the current detection unit 215 outputs the current detection data 216 by the electrical connection between the engagement unit 212 and the pin 213 and the abnormality detection unit 223 receives this (Y), the abnormality detection unit 223 receives the current detection data 216. By analyzing and checking whether the value of the current flowing through the signal line 214 is within the above-described allowable range, it is determined whether the first printed board 401 and the second printed board 402 are normally connected (step S503). ). When the value of the current flowing through the signal line 214 is within the allowable range and the connection between the first printed circuit board 401 and the second printed circuit board 402 is confirmed to be normal (Y), a constant voltage is generated at this stage. The operation of the unit 208 is stopped. At the same time, the first printed circuit board side switch 423 is instructed to select the first printed circuit board side second signal line 422 (step S504). That is, in a state where the connection of the pair of connectors 203 and 204 is confirmed, the normal circuit 411 is connected to the second printed circuit board 402 side, and processing for confirming the connector connection on the first printed circuit board 401 side is performed. End (end).

  In the state where the first connector 203 and the second connector 204 are connected, the normal connection is not suddenly confirmed in step S503. In addition, the connection between the first connector 203 and the second connector 204 may be incompletely terminated for some reason as described above. In such a case (step S503: N), it is determined whether or not the time deferred for the connection process between the first connector 203 and the second connector 204 has elapsed as a timeout (step S505). In the time before timeout (N), the process returns to step S502 to newly receive current detection data, and whether the first printed circuit board 401 and the second printed circuit board 402 are normally connected thereby. Is determined (step S503). By this process, when the operator takes a time required for the connection between the first connector 203 and the second connector 204, it can be continuously determined whether or not the connection is normally performed.

  When a time-out occurs (step S505: Y), predetermined error processing is executed (step S506), and a series of processing ends (end). In the error processing, for example, an alarm indicating that the second printed circuit board 402 is to be reconnected is output from the apparatus on the first printed circuit board 401 side.

  According to the second embodiment of the present invention described above, the connection is normal using the engaging portion 212 and the pin 213 used for normal signal transmission in the first connector 203 and the second connector 204. Confirm that it is. Therefore, if the present invention is applied to an important signal transmission path, it can be surely known that the first connector 203 and the second connector 204 are well connected in the signal transmission path. . In addition, since it is not necessary to provide the connector with an engaging portion that is used only for confirmation of connection or a pin corresponding to this, it is possible to reduce the size and cost of the connector.

  In the second embodiment, the constant voltage generator 208 and the normal circuit 411 are switched with respect to the pair of engaging portions 212 and the pins 213 in the first connector 203 and the second connector 204. However, it is not limited to this. For example, the printed circuit board side switches 423 are arranged so as to correspond to the engaging portions of a plurality of pairs or all pairs of the first connector 203 and the second connector 204, respectively, and these are also individually connected between the connectors. It is possible to determine whether the connection has been made normally.

  In the above-described embodiment, the case where the first printed circuit boards 201 and 401 are parent printed circuit boards that supply power, such as a mother board, has been described. However, the present invention is not limited to this. That is, the present invention can be similarly applied to confirmation of connection between general connectors.

It is a block diagram showing the structure of the connector connection control apparatus in the 1st Embodiment of this invention. It is a block diagram showing the structure of the electric current detection part in 1st Embodiment. It is a block diagram showing the structure of the control part in 1st Embodiment. It is explanatory drawing which shows the concept of the electric current value of the tolerance | permissible_range in 1st Embodiment. It is a flowchart showing the mode of the connector connection confirmation control in the 1st printed circuit board side in 1st Embodiment. It is a block diagram which shows the principal part of the 2nd printed circuit board in the modification of 1st Embodiment. It is a block diagram showing the structure of the connector connection control apparatus in the 2nd Embodiment of this invention. It is the flowchart which showed the control operation by the side of the 1st printed circuit board of the connector connection control apparatus in 2nd Embodiment. It is a block diagram showing the structure of the connector connection control apparatus by the 1st related technique of this invention. It is a top view showing the principal part before the connection of the connector connection control apparatus by the 2nd related technique of this invention.

Explanation of symbols

200, 400 Connector connection control device 201, 401 First printed circuit board 202, 402 Second printed circuit board 203 First connector 204 Second connector 205 First control device 206 Second control device 207 Control unit 208 Voltage generating part 212, 221 Engaging part (terminal)
213, 219 pins (terminal)
215 Current detection unit 223 Abnormality detection unit 231 Current detector 233 A / D converter 241 Reference current value storage unit 243 Comparator 245 In-board circuit control unit 270 Allowable voltage output circuit 271 First comparator 272 Second comparator 275 2 Input AND gates 411 and 431 Normal circuit 423 First printed circuit board side switch 443 Second printed circuit board side switch

Claims (9)

A first board comprising a first connector having a plurality of terminals and a constant voltage applying means for applying a constant voltage to an arbitrary terminal of the first connector;
A constant voltage is applied by a second connector having a plurality of terminals arranged corresponding to the plurality of terminals of the first connector, respectively, and the constant voltage applying means in the second connector. A second substrate provided with current detection means for detecting a current flowing in a terminal corresponding to the corresponding terminal;
A current value determining means arranged on the first or second substrate and determining whether the current detected by the current detecting means is within a predetermined allowable current value range; and A connector connection control unit including a connector connection state determination unit that determines that the connection between the first connector and the second connector is normally performed when it is determined that the current is within the allowable current value range; A connector connection control device. A first connector in which a plurality of terminals are arranged, and second and third terminals that connect the first terminal to an arbitrary terminal of the first connector and are alternatively connected to the first terminal A first connector side switch comprising: a constant voltage applying means connected to the second terminal of the first connector side switch to apply a constant voltage thereto; and the first connector side switch of the first connector side switch. A first substrate including a normal circuit connected to the third terminal and performing either or both of signal transmission and reception via the third terminal;
A second connector having a plurality of terminals connected to each of the plurality of terminals of the first connector, and the first connector side switch in the second connector; A second substrate comprising current detection means for detecting a current flowing in a terminal corresponding to a terminal to which a constant voltage is applied by the constant voltage application means;
The current detected by the current detection means in a state where the first connector-side switch is connected to the first terminal and the second terminal and is disposed on the first or second board, and a predetermined allowable current value. Current value determining means for determining whether the current value is within the range of the current value, and when it is determined that the current value determination means is within the range of the allowable current value, the connection between the first connector and the second connector is normal. Connector connection state determination means for determining that the connection has been made, and when the connector connection state determination means determines that the connection between the first connector and the second connector has been performed normally, the first connector side A connector connection control device comprising: a connector connection control unit including a first connector side switch switching control means for connecting the first terminal and the third terminal to the switch.   An arbitrary terminal of the first connector is a terminal arranged at one end of the first connector, the connector connection control unit is arranged on the second substrate, and the determination result is the first The connector connection control device according to claim 1, wherein the connector connection control device is transmitted to the first substrate via a terminal disposed at the other end of the connector.   The first board executes a predetermined error process when the connector connection state determination unit of the connector connection control unit does not determine that the connection between the first connector and the second connector is normally performed. The connector connection control device according to claim 1, further comprising an error processing execution unit.   The first connector-side switch is arranged on the first board in a number corresponding to a part or all of the plurality of terminals of the first connector, and the connector connection control unit is configured to connect each of these terminals. 3. The connector connection control device according to claim 2, wherein it is determined whether or not the connection between the first connector and the second connector is normally performed. A constant voltage application step of applying a constant voltage to an arbitrary terminal of the first connector in which a plurality of terminals are arranged;
In the second connector in which a plurality of terminals are connected to correspond to the plurality of terminals of the first connector in a state where a constant voltage is applied to the first connector in the constant voltage application step. A current detection data receiving step for receiving current detection data obtained by detecting a current value flowing through a terminal corresponding to an arbitrary terminal of the first connector from a terminal other than the arbitrary terminal of the first connector;
A current value determination step for determining whether the current value indicated by the current detection data received in the current detection data reception step is within a predetermined allowable range;
A connector connection control method comprising: an alarm output step for outputting an alarm when it is determined that the current value detected in the current value determination step is not within an allowable range. When the first connector is disposed on the first printed circuit board and the second connector is disposed on the second printed circuit board, the current value detected in the current value determining step is within an allowable range. An application stopping step of stopping application of a constant voltage to an arbitrary terminal of the first connector in the constant voltage applying step when determined to be;
A connection switching step of connecting a normal circuit communicating with a circuit in the second printed circuit board to an arbitrary terminal of the first connector whose application is stopped in the application stopping step. A connector connection control method according to claim 6. A computer disposed on a first printed circuit board having a first connector having a plurality of terminals disposed thereon,
The terminal of the first connector corresponding to a terminal other than this terminal from a specific terminal of the second connector of the second printed board that can be inserted into and removed from the first connector of the first printed board. A current detection data receiving process for receiving current detection data for detecting a current value flowing into the second printed circuit board;
A current value determination process for determining whether the current value indicated by the current detection data received in the current detection data reception process is within a predetermined allowable range;
A connector connection control program for executing an alarm output process for outputting an alarm when it is determined that the current value detected in the current value determination process is not within an allowable range. When it is determined in the current value determination process that the current value indicated by the current detection data is within a predetermined allowable range, the current flowing into the second printed board instead of the current flowing into the second printed circuit board 9. The connector connection control program according to claim 8, further comprising a connection switching process for connecting a normal circuit communicating with a circuit in the second printed circuit board.

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