JP3740340B2 - Signal transmission device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention has an output jack for transmitting signals or an input jack for receiving signals, and reduces unnecessary power consumption according to the connection status between the plug and the jack, and the connection status between the plug and the jack and the operation status of the internal circuit. Signal transmission that detects the mismatch and notifies the userEquipmentTo do.
[0002]
[Prior art]
The demand for digital equipment is increasing due to the recent development of multimedia. Digitalization of equipment makes it possible to handle all kinds of information such as video, audio, and text without any barriers. Equipment that used to be a completely different category in the past exchanges information by communication, and can be used anytime and anywhere. The environment where information to do is obtained is being prepared.
[0003]
On the other hand, it is also required to reduce energy consumption in order to make effective use of limited resources and create a beautiful environment where people can live with peace of mind.
[0004]
A digital device can perform very complicated processing compared to an analog device, but has a problem of increased power consumption. In particular, in digital transmission using multimedia, there is a part where it is difficult to configure a CMOS circuit with a very high operating frequency and low power consumption.
[0005]
There are roughly two methods for solving this problem. The first method is to rationalize the circuit and reduce the overall power consumption. The second method is to cut down the power supply of a circuit that does not need to operate in the operation mode of the apparatus and reduce power consumption.
[0006]
As a specific example of the first method, there are a method of reducing the process rules of the integrated circuit being used, a method of reducing the number of input / output circuits with high power consumption by combining a plurality of integrated circuits into one. However, this generally requires a great deal of money and time.
[0007]
As a specific example of the second method, there is a method of shutting off the power of a circuit that is not used so that unnecessary power is not consumed. For example, in a television or a VTR, power is supplied only to a portion that receives a signal from a remote controller in a standby mode, and the remaining circuits are all shut off. Unlike the first method, this method can be realized relatively easily and inexpensively and has a great effect. Therefore, this method is used in various devices.
[0008]
This second method is also an important method in communication. Nowadays, with the progress of multimedia, various devices have some kind of communication means, but there are devices that are rarely used in connection with other devices under normal use conditions. For example, in the case of a camera-integrated VTR, an image may be transmitted by connecting a cable for IEEE 1394, which is a serial interface standard, to a computer. Usually, a camera-integrated VTR is used alone. It is given as.
[0009]
In the case of such a device, in a normal use state in which data transmission is not performed, turning off a circuit for communication is an effective means for reducing power consumption. However, if an operation unit is provided and a human performs manual operation, an erroneous operation or forgetting to turn off the power occurs. In addition, in a device using a battery, forgetting to turn off the communication circuit power will shorten the operating time, and therefore the possibility of occurrence of a malfunction that cannot be used when the user wants to use is increased.
[0010]
In order to solve the above problems, several techniques have been proposed in the past for automatically detecting whether another device is connected to the device and controlling the power supply of the communication circuit.
[0011]
As a first prior art, there is one disclosed in JP-A-7-57819. A schematic configuration of the connector with a connection confirmation function in this publication will be described below with reference to FIG.
[0012]
In FIG. 7, reference numeral 1 is a jack, 2 is a plug that is detachably connected to the jack 1, 3 is a light emitting element installed at the back end of the jack 1, and 4 is a light detected by the light emitting element 3. The light receiving element 5 is connected to the jack 1 so that a signal can be input to or output from the external device via the jack 1. The optical sensor driving circuit 5 is connected to the light emitting element 3 and the light receiving element 4. 7 is an internal power supply for supplying power to the internal circuit 6 and the optical sensor driving circuit 5, 8 is a control circuit connected to the light receiving element 4 and confirming the connection state, and 9 is an internal circuit 6 and an apparatus power supply 7. Is a switch for switching between a state in which power is supplied to the internal circuit 6 and a state in which it is shut off based on a command from the control circuit 8.
[0013]
The relationship among the jack 1, the light emitting element 3, and the light receiving element 4 is configured as follows. That is, when the plug 2 is not inserted into the jack 1 or when the plug 2 is not inserted sufficiently, the light emitted from the light emitting element 3 is incident on the light receiving element 4, and conversely, it is correctly inserted into the jack 1. In this state, the emitted light from the light emitting element 3 is shielded by the plug 2 in the inserted state and is not incident on the light receiving element 4.
[0014]
The optical sensor drive circuit 5 is constantly supplied with power from the apparatus power supply 7. The same applies to the control circuit 8.
[0015]
The control circuit 8 receives the detection signal from the light receiving element 4 and controls the switch 9. That is, when the light receiving element 4 detects that light is incident, the control circuit 8 controls the switch 9 to be in a connected state, and supplies power from the apparatus power supply 7 to the internal circuit 6 via the switch 9. The internal circuit 6 transmits a signal from the jack 1 via the plug 2 and a cable (not shown), or receives a signal transmitted from the cable (not shown) via the plug 2 and the jack 1 as necessary. To do.
[0016]
When it is detected that the incident light with respect to the light receiving element 4 is blocked, the control circuit 8 controls the switch 9 to be cut off, and cuts off the power supply from the apparatus power supply 7 to the internal circuit 6.
[0017]
As described above, when the plug 2 is correctly inserted into the jack 1 and the light from the light emitting element 3 to the light receiving element 4 is blocked, the control circuit 8 recognizes that the plug 2 is connected to the jack 1 and turns the switch 9 on. Connecting. When the plug 2 is removed from the jack 1 or when the plug 2 is not properly inserted, the control circuit 8 shuts off the switch 9 and stops the power supply from the apparatus power supply 7 to the internal circuit 6. This reduces unnecessary power consumption.
[0018]
As a second prior art, there is one disclosed in JP-A-5-62739. The structure of the coaxial cable connector in this publication will be described below with reference to FIG.
[0019]
In FIG. 8, reference numeral 10 is a jack, 11 is a plug that is detachably connected to the jack 10, 11a is a male contact, 11b is an insulating cylinder, and 12 is electrically connected to the male contact 11a. In the plug 11, 19 is an insulator block, 17 is a flange integral with the jack 10 that forms the base end of the jack 10, and 13 is in contact with the flange 12 when the plug 11 is normally connected to the jack 10. A probe unit 18 is an insulating spacer interposed between the flange 17 and the probe unit 13. The probe portion 13, the spacer 18, and the flange 17 of the jack 10 are commonly attached to the insulator block 19. Reference numeral 16 denotes a conductor that is passed through the insulator block 19 and is connected to a female contact (not shown) that is electrically connected to the jack 10 inside the jack 10. Reference numeral 13 a denotes a probe section 13. , 17a is a tab integrally formed on the flange 17, 14 is an electric wire connected to the tab 13a of the probe section 13, and 15 is an electric wire connected to the tab 17a of the flange 17.
[0020]
The operation when the plug 11 is inserted into the jack 10 is as follows. The insulating cylinder portion 11 b of the plug 11 is fitted in the jack 10, and the flange 12 of the plug 11 is fitted on the jack 10. The male contact 11a in the plug 11 comes into contact with a female contact (not shown) in the jack 10 to be in an electrically conductive state. The female contact is structurally electrically connected to the jack 10. Both the jack 10 and the flange 17 are electrically connected. The front end face of the flange 12 of the plug 11 comes into contact with the bent end face of the probe portion 13 and comes into electrical conduction.
[0021]
As a result of the above, when the plug 11 is correctly inserted into the jack 10, the electric wire 14 → the tab 13a → the probe 13 → the flange 12 → the plug 11 → the male contact 11a → the female contact → the jack 10 → the flange 17 → The electric wire 14 and the electric wire 15 are in an electrically conductive state through a path such as the tab 17a → the electric wire 15.
[0022]
Conversely, if the plug 11 is not properly inserted into the jack 10, the front end surface of the flange 12 in the plug 11 and the bent end surface of the probe portion 13 in the jack 10 do not come into contact with each other, and the electric wire 14 and the electric wire 15 is electrically separated. By detecting the incomplete coupling, the incomplete coupling is prevented. Note that the power supply control is not mentioned in this publication.
[0023]
There is another problem in an apparatus that automatically detects whether or not it is connected to another device as in the above example. Even if the cable is connected correctly, the user cannot easily know whether it is operating correctly. Moreover, it is very inconvenient when trying to transmit a long distance.
[0024]
As a prior art (third prior art) for solving the second problem, there is one disclosed in Japanese Patent Laid-Open No. 6-52938. The structure of the connector for a coaxial cable in this publication will be described below with reference to FIG.
[0025]
In FIG. 9, reference numeral 20 denotes a cable on the network side, 21 denotes a connector, 22 denotes a signal line in the connector, 23 denotes a ground line in the connector, and 24 emits light in a state where a signal is transmitted and is not transmitted. Light-emitting elements that are turned off in the state, 25 is a resistor having the same value as the termination resistor provided at the termination position of the network cable, 26 is a node-side cable that is a computer or terminal device, and 21 a is a connection to the network-side cable 20. , 21b is a connection portion with the cable 26 on the node side, 22a and 22b are signal line terminals, and 23a and 23b are ground line terminals.
[0026]
The network side cable 20 and the node side cable 26 are connected via a connector 21. That is, the cable 20 on the network side is connected to the connection part 21a of the connector 21, and the signal line terminal 22a and the ground line terminal 23a are connected to the signal line terminal at the node side connection part 21b via the signal line 22 and the ground line 23, respectively. 22b is connected to a ground line terminal 23b and is connected to a node device (not shown) through a cable 26 on the node side.
[0027]
A high frequency digital signal is transmitted bidirectionally through the signal line 22. When the cables 20 and 26 are in a normal state where no disconnection has occurred, and in a normal state where there is no contact failure in the connection portions 21a and 21b of the connector 21, the light emitting element 24 emits light by transmitting a digital signal. However, if there is a disconnection or poor contact, the light emitting element 24 does not emit light. In this manner, the presence or absence of disconnection or poor contact is checked by detecting whether or not the light emitting element 24 emits light.
[0028]
[Problems to be solved by the invention]
In a signal transmission device, it is required to reduce power consumption by supplying power to a signal transmission unit or signal reception unit only when it is necessary to transmit a signal and shutting off the power supply when unnecessary. In addition, it is required to ensure high reliability by allowing the user to check whether the plug of the cable is correctly attached and whether the internal circuit is operating correctly.
[0029]
In the case of the connector with a connection confirmation function disclosed in Japanese Patent Application Laid-Open No. 7-57819 as the first prior art (see FIG. 7), the light emitting element 3, the light receiving element 4 and the like are detected in detecting whether or not the plug 2 is inserted. Expensive parts such as the optical sensor driving circuit 5 are required, the number of parts is large, the structure is complicated overall, and the cost is increased.
[0030]
In the case of the coaxial cable connector (see FIG. 8) disclosed in Japanese Patent Application Laid-Open No. 5-62739 as the second prior art, the probe 13 having a special shape, the probe 13 and the jack In addition to newly adding a spacer 18 interposed between one flange 2 and the probe portion 13, the spacer 18 and the flange 2 must be commonly attached to the insulator block 19. The overall shape and structure are extremely complex. Furthermore, since the presence / absence of insertion is detected by contacting the abutting surface between the bent end surface of the probe portion 13 and the front end surface of the flange 12 on the plug 11 side, the processing accuracy of the jack and plug is required to be extremely severe. This increases the cost. Nevertheless, the accuracy with respect to play when joined is difficult to obtain, and the jack and plug cannot be detected unless the fitting length is the same. In other words, there are restrictions on using jacks and plugs made by different manufacturers.
[0031]
Furthermore, the coaxial cable connector disclosed in Japanese Patent Laid-Open No. 6-52938 as the third prior art (see FIG. 9) may be effective for bidirectional transmission or the transmission side of unidirectional transmission. Although it is not known, it is difficult to detect at the receiving side of unidirectional transmission. Further, in this means, since the light emitting element 24 as a load is connected to the signal line 22 itself, the transmission distance is shortened when the frequency is increased.
[0032]
The present invention was created in order to solve the above-described problems, and presupposes a configuration that reduces unnecessary power consumption in a circuit unrelated to signal transmission via a jack when no plug is inserted. Its purpose is to simplify the structure and realize it at a relatively low price, and to improve reliability by increasing the accuracy of detecting whether or not there is a plug. It is another object of the present invention to make it easy for the user to confirm the operation status as to whether automatic control of power supply / stop based on the presence / absence of plug insertion is appropriate.
[0033]
[Means for Solving the Problems]
A signal transmission apparatus according to the present invention which attempts to solve the above-described problem is a division in which a ground terminal (corresponding to a general ground terminal) in a jack is divided into a plurality of parts in an electrically separated state and one is grounded. The other is used as a divided connection detection terminal.
[0034]
When a plug is inserted into such a jack, the divided connection detection terminal is electrically connected to the divided ground terminal. On the other hand, in a state where the plug is not inserted, or in a state where the insertion failure occurs even if the plug is inserted, the divided connection detection terminal and the divided ground terminal remain electrically separated. Become. By identifying these two states, the presence / absence of plug insertion can be detected. When the plug is present, power can be supplied to the circuit to perform the necessary operation. It is possible to cut power supply and reduce wasteful power consumption.
[0035]
And in order to exhibit such a function, what is equivalent to a general ground terminal is divided into a plurality of parts in an electrically separated state, and one is divided into grounded ground terminals, and the other is divided into connection detection terminals. It can be of a simple structure as much as it can, and the number of parts can be reduced, thereby suppressing an increase in cost burden.
[0036]
In particular, the combination of the split connection detection terminal and the split ground terminal originally corresponds to a general ground terminal. When a plug is inserted, the plug is connected to the general ground terminal. Since the electrical connection state appears, the divided connection detection terminal corresponding to the general ground terminal and the divided ground terminal have good electrical connection via the plugs inserted. The state will be revealed. This is usually a mating surface contact, not a butt surface contact, and a reliable contact is obtained. Therefore, it is possible to clearly identify the presence or absence of insertion, and the detection accuracy is excellent. Nevertheless, it is not required that the processing accuracy is so severe. That is, the structure can be made very simple, and the reliability can be improved while suppressing an increase in cost.
[0037]
In addition, the jack structure as described above can be dealt with only by changing the jack side, and no modification is required on the plug side. Things can be used as they are, or new but general types developed in the future can be applied as they are.
[0038]
In addition to the above-described requirements, the signal transmission device of the present invention is configured to detect an inconsistency state by detecting an inconsistency in power supply / cutoff control. In this way, whether or not the corresponding circuit is activated as expected by automatic power supply when plugging is present, and whether or not the corresponding circuit is automatically shut off when plugging is not present Therefore, it is possible to make the user confirm the control inconsistency state (in other words, the realization of proper control) as to whether or not the operation state has become inoperable as expected, and the operation reliability can be improved.
[0039]
  MaJackAs described above, the ground terminal (corresponding to a general ground terminal) is divided into a plurality of divided ground terminals on one side to be grounded, and the remaining divided ground terminals of the division Is a structure having the other divided connection detection terminal in an electrically separated state. Such a jack is mainly used in the signal transmission apparatus as described above, and thereby, it is possible to easily construct a signal transmission apparatus that exhibits the above-described excellent actions and effects.
[0040]
In the above description, the relationship between the jack and the plug has been described. However, this expression does not necessarily have to be taken into consideration, and the relationship between the male connector and the female connector may be taken. You can think of it as a concept of sockets or receptacles. That is, typical examples include a coaxial cable jack and an IEEE 1394 cable jack, but connectors of any other aspect may be applied.
[0041]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be generally described below.
[0042]
  The signal transmission device of the first invention of the present application is:Depending on whether a signal transmission means, a power supply means for supplying power to the signal transmission means, a switch means interposed between the signal transmission means and the power supply means, and whether or not a plug is inserted into the jack Detects whether or not there is a mismatch in the control state based on comparing the power supply control means for controlling on / off of the switch means and the output state of the signal transmission means and the output state of the power supply control means. An inconsistency state detecting means, and an inconsistency state informing means for informing the inconsistency state by the inconsistency state detecting means,The ground terminal (corresponding to a general ground terminal) in the jack is divided into a plurality of parts in an electrically separated state to make one divided ground terminal to be grounded, and the other is made a divided connection detection terminal. Against the jackSaidIt is configured to control power supply / cutoff based on switching between electrical connection / separation of the divided ground terminal and the divided connection detection terminal according to the presence / absence of plug insertion.The signal transmission means is connected to the jack.
[0043]
  The operation of the first invention is as follows. Power can be supplied to the circuit when the plug is inserted to perform necessary operations, and when no plug is inserted, the power supply can be cut off to reduce wasteful power consumption. As described above, the structure of the jack for demonstrating the power supply is simple as long as one is a divided ground terminal to be grounded and the other is a divided connection detection terminal. In addition, since the mating surface is contacted by inserting a plug, the electrical connection between the divided connection detection terminal and the divided ground terminal can be ensured, and it is clearly indicated whether there is an insertion or not. And the detection accuracy is excellent. Nevertheless, it is not required that the processing accuracy is so severe. That is, the structure is extremely simple, the number of parts can be reduced, and the reliability can be enhanced while suppressing an increase in cost burden. Furthermore, the plug side does not require modification, and the same plug as that of a general conventional one can be used as it is.Also, when the plug is inserted, the switch means is turned on to supply power to the signal transmission means, and the signal transmission means is activated to perform the signal transmission function. Conversely, when the plug is not inserted, the switch is turned on. By turning off the means, the power supply to the signal transmission means is stopped and the signal transmission means is deactivated, so that wasteful power consumption can be reduced. In order to exert such a function, the above-described jack is used, so that the structure can be simplified and the reliability can be enhanced while being relatively inexpensive. Further, when the mismatch state detection means detects a mismatch between the output state of the signal transmission means and the output state of the power supply control means, the mismatch state is notified by sending the detection signal to the mismatch state notification means. Can inform the user.
[0044]
  The signal transmission device of the second invention of the present application is:Signal receiving means, power supply means for supplying power to the signal receiving means, switch means interposed between the signal receiving means and the power supply means, and depending on whether a plug is inserted into the jack Detects whether or not there is a mismatch in the control state based on comparing the power supply control means for controlling on / off of the switch means and the output state of the signal receiving means and the output state of the power supply control means. A mismatching state detection unit for detecting the mismatching state by the mismatching state detection unit, and the ground terminal of the jack is divided into a plurality of parts in an electrically separated state and one of them is grounded. The divided ground terminal and the other are divided connection detection terminals, and the divided ground terminal according to whether the plug is inserted into the jack or not Based on the switching of the electrical connection and separation of devoted connection detection terminal configured to perform control of the supply and interruption of power supply, the signal receiving means is connected to said jack.
[0045]
  The operation of the second invention is as follows. Power can be supplied to the circuit when the plug is inserted to perform necessary operations, and when no plug is inserted, the power supply can be cut off to reduce wasteful power consumption. As described above, the structure of the jack for demonstrating the power supply is simple as long as one is a divided ground terminal to be grounded and the other is a divided connection detection terminal. In addition, since the mating surface is contacted by inserting a plug, the electrical connection between the divided connection detection terminal and the divided ground terminal can be ensured, and it is clearly indicated whether there is an insertion or not. And the detection accuracy is excellent. Nevertheless, it is not required that the processing accuracy is so severe. That is, the structure is extremely simple, the number of parts can be reduced, and reliability can be improved while suppressing an increase in cost burden. Furthermore, the plug side does not require modification, and the same plug as that of a general conventional one can be used as it is. Also, when the plug is inserted, the switch means is turned on to supply power to the signal receiving means, the signal receiving means is activated, and the signal receiving function is exhibited. Conversely, when the plug is not inserted, the switch is turned on. The power supply to the signal receiving means is stopped by turning off the means and the signal receiving means is deactivated, so that useless power consumption can be reduced. In order to exert such a function, the above-described jack is used, so that the structure can be simplified and the reliability can be enhanced while being relatively inexpensive. Further, when the mismatch state detection means detects a mismatch between the output state of the signal receiving means and the output state of the power supply control means, the mismatch state is notified by sending the detection signal to the mismatch state notification means. Can inform the user.
[0046]
  A signal transmission device according to a third aspect of the present invention is the signal transmission device according to the first or second aspect, wherein the inconsistency state notifying means is a display means. As a form of notification, a sound such as an alarm buzzer may be used, but more specific and detailed notification is possible by displaying. In other words, whether the circuit is in an active state despite the absence of plugging, or whether the circuit is inoperative despite being plugged in, etc. Can be informed specifically and in detail.
[0066]
Hereinafter, specific embodiments of a signal transmission device and a jack according to the present invention will be described in detail with reference to the drawings.
[0067]
(Embodiment 1)
FIG. 1 is a block diagram showing an electrical configuration of a transmission-side signal transmission device according to Embodiment 1 of the present invention, and FIG. 2 is a perspective view showing a structure of a coaxial cable jack in the signal transmission device. The first embodiment relates to a signal transmission device on the transmission side.
[0068]
First, a schematic configuration of the signal transmission device will be described with reference to FIG. Reference numeral 100 is a jack for electrical connection / separation by inserting / removing an external coaxial cable plug (not shown), 101 is a signal processing means, 102 is a signal form suitable for transmission upon receiving an output signal of the signal processing means 101 Signal transmitting means for converting to signal transmission, 103 is a power supply means for supplying power to the signal transmitting means 102, 104 is inserted between the power supply means 103 and the signal transmitting means 102, and signal is transmitted from the power supply means 103 A switch means 105 for turning on / off the power supply to the means 102 and a power supply control means 105 for turning on / off the switch means 104 based on detection of a connection state of a coaxial cable plug (not shown) to the jack 100. Note that reference numerals 100a, 100b, and 100c as components of the coaxial cable jack 100 will be described later.
[0069]
The mode of control of the switch means 104 by the power supply control means 105 is as follows.
[0070]
The power supply control unit 105 monitors whether or not a coaxial cable plug (not shown) is inserted into the jack 100. The jack 100 outputs a detection signal indicating whether or not the plug is inserted to the power control means 105. The power supply control means 105 sends an on control signal to the switch means 104 when detecting the presence of insertion. The switch means 104 that has received the ON control signal performs a closing operation, connects the power supply means 103 to the signal transmission means 102, and supplies power from the power supply means 103 to the signal transmission means 102. As a result, the signal transmission unit 102 becomes active, and the signal generated by the signal processing unit 101 is sent to the jack 100 via the signal transmission unit 102, and further from the jack 100 to the external device via the coaxial cable plug and the coaxial cable. To send.
[0071]
The power supply control means 105 also sends an off control signal to the switch means 104 when it is detected that the coaxial cable plug is not inserted into the jack 100 (including insertion failure). The switch means 104 that has received the OFF control signal performs an opening operation, disconnects the signal transmission means 102 from the power supply means 103, and stops power supply to the signal transmission means 102.
[0072]
The meaning of this power supply stop is as follows. Even if the signal transmission means 102 is in an active state, the coaxial cable plug is not connected to the jack 100 and there is no medium for signal transmission to an external device. It is useless to leave it in a state. Therefore, wasteful power consumption can be reduced by putting the signal transmission unit 102 into an inoperative state.
[0073]
Next, a specific structure of the jack 100 will be described with reference to FIG.
[0074]
The grounding portion of a conventional coaxial cable jack is cylindrical, and all the portions are configured to have the same electrical potential. In the coaxial cable jack 100 according to the first embodiment, the grounding portion of the conventional coaxial cable jack is divided into a plurality of parts in an electrically separated state to form one divided ground terminal 100c that is grounded and the other is divided. The connection detection terminal 100b is provided, and the power supply / supply is switched based on switching between electrical connection / separation between the divided ground terminal 100c and the divided connection detection terminal 100b according to the presence / absence of plug insertion into the jack. It is configured to control the shutoff.
[0075]
In the coaxial cable jack 100 shown in FIG. 2, the inner conductor portion 50 and the outer conductor portion 60 are arranged concentrically, and an insulator (not shown) is interposed between the inner conductor portion 50 and the outer conductor portion 60. And are integrated. The outer conductor portion 60 is integrally provided with a concentric flange 61, guide pins 62 and 62 are integrally planted, and a ground connection portion 63 is integrally provided. . The inner conductor portion 50 is configured in an elongated cylindrical shape, and the center hole of the cylindrical portion is configured in the female contact 100a.
[0076]
Further, in the present embodiment, the outer conductor portion 60 is divided into two. One of them is large in size and serves as a ground terminal 100c like a general one. In the present specification, this ground terminal 100c is called a divided ground terminal 100c. The other divided part of the outer conductor part 60 is a divided connection detection terminal 100b having a small size. The flange portion 61, the guide pins 62 and 62, and the ground connection portion 63 exist toward the divided ground terminal 100c. The shape of the divided connection detection terminal 100b is a strip having a long and narrow partial arc along the axial direction. An insulating connector 100d is interposed between the divided connection detection terminal 100b and the divided ground terminal 100c, and the divided ground terminal 100c, the insulating connector 100d, and the divided ground terminal 100c are commonly used. An integral cylindrical body similar to the above is constructed. An output terminal 64 for detecting the presence / absence of plug insertion is provided in the divided connection detection terminal 100b at a position corresponding to the back side of the flange 61.
[0077]
It should be noted that the shape and size of the divided connection detection terminal 100b shown in the figure are merely examples that are considered preferable, and the presence or absence and mode of the flange 61, the guide pins 62, 62, the ground connection 63, and the output terminal 64 Are only examples that are considered preferable, and can be arbitrarily determined. Further, the division number of the original outer conductor portion 60 can be arbitrarily determined. The same applies to the material and size of the insulating connector 100d. In short, an appropriate value is set in consideration of the number of divisions of the ground terminal of the existing coaxial cable plug and the width of the gap between the ground terminals.
[0078]
Although not described above with reference to FIG. 1, the coaxial cable jack 100 described with reference to FIG. 2 is divided into three electrically separated elements, that is, a female contact 100a as shown in FIG. It consists of a connection detection terminal 100b and a divided ground terminal 100c, and an output terminal 64 in the divided connection detection terminal 100b is connected to a DC power source Vcc via a pull-up resistor 106 and connected to the power control means 105. Has been.
[0079]
In the state where the coaxial cable plug (not shown) is not inserted and the plug is not inserted, as described above, the divided connection detection terminal 100b is electrically separated from the divided ground terminal 100c. Becomes “H” level obtained by subtracting the voltage drop of the pull-up resistor 106 from the DC power source Vcc. The power supply control means 105 outputs an off control signal to the switch means 104 when receiving a detection signal indicating that the plug connection detection terminal 100b does not have an “H” level plug. In this case, the switch means 104 is opened, the power supply from the power supply means 103 to the signal transmission means 102 is stopped, and the signal transmission means 102 becomes inoperative.
[0080]
When the coaxial cable plug (not shown) is inserted, the coaxial cable plug contacts both the divided connection detection terminal 100b and the divided ground terminal 100c. Therefore, the divided connection detection terminal 100b is used for the coaxial cable. Since the divided ground terminal 100c is connected to the ground GND via the plug and the divided ground terminal 100c is connected to the ground GND, the divided connection detection terminal 100b is substantially connected to the ground GND. The voltage drop in the pull-up resistor 106 becomes the same as Vcc, and the potential of the divided connection detection terminal 100b becomes “L” level. The power supply control means 105 outputs an ON control signal to the switch means 104 when an “L” level plug insertion detection signal is input from the divided connection detection terminal 100b. In this case, the switch means 104 is closed, and power is supplied from the power supply means 103 to the signal transmission means 102, and the signal transmission means 102 becomes active.
[0081]
In a state where the coaxial cable plug is inserted into the coaxial cable jack 100, a male contact (not shown) in the coaxial cable plug is brought into conductive contact with the female contact 100a, and the signal transmission is in an active state by receiving power. The means 102 sends out a signal obtained by performing predetermined conversion on the signal from the signal processing means 101. The sent signal is sent from the female contact 100a in the coaxial cable jack 100 to the male contact in the coaxial cable plug. Then, it is sent to an external device via a coaxial cable.
[0082]
In the first embodiment, the divided connection detection terminal 100b and the divided ground terminal 100c are integrated through the insulating connector 100d, so that the strength is not inferior to that of a general one. Yes. However, depending on the material and the thickness, it is conceivable to implement in a form in which the insulating connector 100d is omitted.
[0083]
The coaxial cable jack 100 according to the first embodiment achieves the function of detecting the presence or absence of insertion of a coaxial cable plug by the presence or absence of electrical contact due to insertion of the coaxial cable plug. The structure is much simpler than that using the light emitting element, the light receiving element, and the optical sensor driving circuit in the first prior art.
[0084]
Further, the coaxial cable jack 100 according to the first embodiment has a much simpler structure than the jack 10 of the second prior art shown in FIG. 8, and its manufacturing cost is low. It is possible to suppress.
[0085]
The coaxial cable plug to be inserted into the coaxial cable jack 100 is not a specific coaxial cable plug whose fitting length is severely standardized as in the second prior art (FIG. 8). The same as a general conventional one may be used as it is. Alternatively, it is possible to apply a new but general type that will be developed in the future.
[0086]
(Embodiment 2)
FIG. 3 is a block diagram showing an electrical configuration of the signal transmission apparatus according to the second embodiment of the present invention. The second embodiment relates to a signal transmission device on the receiving side.
[0087]
In FIG. 3, reference numeral 100 indicates the same coaxial cable jack shown in FIG. 2 as described with reference to FIG. 1 in the first embodiment, 201 is signal processing means, and 202 is input from the coaxial cable jack 100. Signal receiving means for converting the signal into a signal form suitable for later signal processing and delivering it to the signal processing means 201, 203 power supply means for supplying power to the signal receiving means 202, 204 for receiving power with the power supply means 203 Switch means inserted between the power supply means 202 to turn on / off the power supply from the power supply means 203 to the signal receiving means 202, and 205 is a switch based on detection of a connection state of a coaxial cable plug (not shown) to the jack 100 Power supply control means for controlling on / off of the means 204; 206, a split connection detection end in the coaxial cable jack 100; 100b is a pull-up resistor to pull up.
[0088]
The mode of control of the switch means 204 by the power supply control means 205 is as follows.
[0089]
The power control means 205 monitors whether or not a coaxial cable plug (not shown) is inserted into the jack 100. When the coaxial cable plug is inserted, the coaxial cable plug contacts both the divided connection detection terminal 100b and the divided ground terminal 100c of the coaxial cable jack 100, so the divided connection detection terminal 100b. Is connected to the divided ground terminal 100c via the coaxial cable plug, and the divided ground terminal 100c is connected to the ground GND. Consequently, the divided connection detection terminal 100b is substantially connected to the ground GND. As a result, the voltage drop in the pull-up resistor 206 is the same as Vcc, and the potential of the divided connection detection terminal 100b becomes the “L” level. The power supply control means 205 outputs an ON control signal to the switch means 204 when an “L” level plug insertion detection signal is input from the divided connection detection terminal 100b. In this case, the switch means 204 is closed, and power is supplied from the power supply means 203 to the signal receiving means 202, and the signal receiving means 202 becomes active. A signal input from the coaxial cable jack 100 via a coaxial cable and a coaxial cable plug (not shown) is sent to the signal processing means 201 via the signal receiving means 202.
[0090]
When the coaxial cable plug (not shown) is not inserted, the split connection detection terminal 100b in the coaxial cable jack 100 is electrically separated from the split ground terminal 100c, so the split connection detection terminal 100b. The potential at is “H” level obtained by subtracting the voltage drop of the pull-up resistor 206 from the DC power supply Vcc. The power supply control means 205 outputs an OFF control signal to the switch means 204 when it receives a "H" level plug insertion absence detection signal from the divided connection detection terminal 100b and determines that no plug is inserted. become. In this case, the switch means 204 is opened, the power supply from the power supply means 203 to the signal receiving means 202 is stopped, and the signal receiving means 202 becomes inoperative.
[0091]
The meaning of this power supply stop is as follows. Even if the signal receiving means 202 is in an active state, the coaxial cable plug is not connected to the jack 100 and there is no medium for receiving a signal from an external device. It is useless to leave it in a state. Therefore, wasteful power consumption can be reduced by putting the signal receiving unit 202 into an inoperative state.
[0092]
Also in the second embodiment, the other configurations, operations, operations, and effects are the same as those in the first embodiment, and thus description thereof is omitted.
[0093]
(Embodiment 3)
FIG. 4 is a block diagram showing an electrical configuration of the signal transmission apparatus on the transmission side according to the third embodiment of the present invention.
[0094]
The same reference numerals as those in FIG. 1 for the first embodiment also indicate the same components in FIG. 4 for the third embodiment, so that only the names of the reference numerals are described here. Matters described in the first embodiment and not described again in the third embodiment are also applicable to the third embodiment as they are, and detailed description thereof is omitted. Reference numeral 100 denotes a coaxial cable jack, 100a a female contact, 100b a divided connection detection terminal, 100c a divided ground terminal, 101 a signal processing means, 102 a signal transmission means, 103 a power supply means, and 104 a switch means , 105 are power control means, and 106 is a pull-up resistor. The configuration of the third embodiment is different from that of the first embodiment as follows.
[0095]
As new components, an inconsistency state detection unit 107 and an inconsistency state notification unit 108 are provided. The inconsistency state notifying unit 108 may be a display unit such as a liquid crystal display (LCD) or an electronic buzzer.
[0096]
The inconsistency state detection means 107 receives the output signal from the power supply control means 105 and the output signal from the signal transmission means 102, and detects whether the apparatus is operating normally based on both signals. It has become. Specifically, when the signal output from the power supply control unit 105 is an ON control signal and a valid output signal is not output from the signal transmission unit 102, it is assumed that a mismatch has occurred. The mismatch detection signal is output to the mismatch status notification means 108.
[0097]
The inconsistency state detection unit 107 generates an inconsistency when a valid output signal is output from the signal transmission unit 102 when the signal output from the power control unit 105 is an off control signal. As a result, the mismatch detection signal is output to the mismatch status notification means 108.
[0098]
The inconsistency state notifying unit 108 that has received the inconsistency detection signal displays a message informing the user that the inconsistency state has been detected. For example, “normal sleep status” is displayed.
[0099]
In other cases, that is, when a valid output signal is output from the signal transmission unit 102 when the signal output from the power control unit 105 is an ON control signal, or output from the power control unit 105. If a valid output signal is not output from the signal transmission unit 102 when the received signal is an off control signal, it is assumed that the signal is in a matching state, and a mismatch detection signal is sent to the mismatch state notification unit 108. Do not output. At this time, the inconsistency state notifying unit 108 does not perform special display. Alternatively, when it is determined that the inconsistency state detection unit 107 is in a matching state, the inconsistency state notification unit 108 outputs a matching state detection signal to the inconsistency state notification unit 108, and the inconsistency state notification unit 108 is in a matching state. You may comprise so that the display which notifies a user may be performed. For example, “normal operation status” is displayed.
[0100]
As described above, in the signal transmission device according to the third embodiment, even if the user thinks that the coaxial cable plug is correctly inserted into the coaxial cable jack 100, there is a defect such as insufficient insertion amount. If it occurs, “Normal Sleep Status” is displayed, and when it is correctly inserted, “Normal Operation Status” is displayed, so it is possible to avoid malfunction of the device due to user's assumption in advance. Or notify the user of a circuit failure.
[0101]
In the above description, the output of the signal transmission unit 102 is simply described as being sent to both the coaxial cable jack 100 and the mismatch state detection unit 107. However, as an actual circuit configuration, It is preferable to provide a distributor on the output side so as to keep the load of the signal line for transmission to the jack 100 in the same state as usual, thereby preventing the transmission distance from decreasing.
[0102]
(Embodiment 4)
FIG. 5 is a block diagram showing an electrical configuration of the signal transmission apparatus on the receiving side according to the fourth embodiment of the present invention.
[0103]
The same reference numerals as those in FIG. 3 for the second embodiment indicate the same components in FIG. 5 for the fourth embodiment, so that only the names of the reference numerals are described here. The items described in the second embodiment and not described again in the fourth embodiment also correspond to the fourth embodiment as they are, and detailed description thereof is omitted. Reference numeral 100 denotes a coaxial cable jack, 100a a female contact, 100b a divided connection detection terminal, 100c a divided ground terminal, 201 a signal processing means, 202 a signal receiving means, 203 a power supply means, and 204 a switch means 205 are power control means, and 206 is a pull-up resistor. The configuration of the fourth embodiment is different from that of the second embodiment as follows.
[0104]
As new components, an inconsistency state detection unit 207 and an inconsistency state notification unit 208 are provided. The inconsistency state notifying unit 208 may be a display unit such as a liquid crystal display (LCD) or an electronic buzzer.
[0105]
The mismatch state detection means 207 receives the output signal from the power supply control means 205 and the output signal from the signal reception means 202, and detects whether or not the apparatus is operating normally based on both signals. It has become. Specifically, when the signal output from the power supply control unit 205 is an ON control signal and a valid output signal is not output from the signal reception unit 202, it is assumed that a mismatch has occurred. The mismatch detection signal is output to the mismatch status notifying unit 208.
[0106]
The inconsistency state detection unit 207 generates an inconsistency when a valid output signal is output from the signal reception unit 202 when the signal output from the power control unit 205 is an off control signal. As a result, the mismatch detection signal is output to the mismatch status notification unit 208.
[0107]
The inconsistency state notifying unit 208 that has received the inconsistency detection signal performs a display notifying the user that the inconsistency state has been detected. For example, “normal sleep status” is displayed.
[0108]
In cases other than the above, that is, when a valid output signal is output from the signal receiving unit 202 when the signal output from the power control unit 205 is an ON control signal, or output from the power control unit 205. When a valid output signal is not output from the signal receiving unit 202 when the received signal is an off control signal, it is assumed that the signal is in a matched state, and a mismatch detection signal is sent to the mismatch state notifying unit 208. Do not output. At this time, the inconsistency state notifying unit 208 does not display specially. Alternatively, when it is determined that the inconsistency state detection unit 207 is in the alignment state, the inconsistency state notification unit 208 outputs a matching state detection signal, and the inconsistency state notification unit 208 is in the alignment state. You may comprise so that the display which notifies a user may be performed. For example, “normal operation status” is displayed.
[0109]
As described above, in the signal transmission device according to the fourth embodiment, even if the user thinks that the coaxial cable plug is correctly inserted into the coaxial cable jack 100, there is a defect such as insufficient insertion amount. If it occurs, “Normal Sleep Status” is displayed, and when it is correctly inserted, “Normal Operation Status” is displayed, so it is possible to avoid malfunction of the device due to user's assumption in advance. Or notify the user of a circuit failure.
[0110]
(Embodiment 5)
The fifth embodiment relates to another form of the jack. FIG. 6 is a perspective view showing the structure of the IEEE1394 cable jack according to the fifth embodiment of the present invention.
[0111]
The reference numeral 300a as a component of the IEEE 1394 cable jack 300 is four or six contacts for transmitting a signal, and 300b is one of the case ground terminals of the IEEE 1394 cable jack 300 which is divided into two parts. A divided connection detection terminal 300c used for detecting the presence / absence of insertion is a divided ground terminal 300c which is a remaining part of the housing ground terminal divided into two and is used for grounding as usual. In addition, in order to ensure strength, an insulating coupling body may be interposed between the divided connection detection terminal 300b and the divided ground terminal 300c for integration.
[0112]
The IEEE 1394 cable jack 300 configured as described above can be used in place of the coaxial cable jack 100 in the signal transmission device shown in FIGS. 1, 3, 4, and 5. Specifically, this corresponds to a case where the female contact 100a is replaced with the contact 300a, the divided connection detection terminal 100b is replaced with the divided connection detection terminal 300b, and the divided ground terminal 100c is replaced with the divided ground terminal 300c.
[0113]
In the signal transmission device using the IEEE 1394 cable jack 300, the other configurations, operations, operations, and effects are the same as those of the first to fourth embodiments, and thus the description thereof is omitted.
[0114]
As mentioned above, although embodiment of this invention was explained in full detail, this invention does not need to be limited to said embodiment, The following embodiment can also be included.
(1) In the above embodiment, in the jack, the divided connection detection terminal and the divided ground terminal are integrated via an insulating connecting body, but the insulating connecting body is not always necessary, and the material and the meat Depending on the contrivance of thickness, the insulating coupling body may be omitted.
(2) In the above embodiment, the signal transmission device on the transmission side and the signal transmission device on the reception side are separately discussed. However, it is not always necessary to be bound by them, and both the transmission function and the reception function are provided. You may comprise as a signal transmission apparatus.
(3) In the case of (2) above, the jack may be configured as a single unit for transmission and a unit for reception, or may be configured as a single unit that integrates both. Also good. In the case of the integral type, the number of divisions of the original outer conductor portion 60 is an even division such as four divisions or six divisions.
(4) In the above description, the relationship between the jack and the plug has been described. However, this expression is not necessarily limited to this, and may be understood as the relationship between the male connector and the female connector. Furthermore, the female side may be considered as a concept such as a socket or a receptacle. That is, in the above description, the coaxial cable jack and the IEEE 1394 cable jack are given as typical examples, but in addition to this, a D-sub connector, an amphenol connector, a DIN connector, a mini-DIN, which are mainly used for RS-232C cables. It can be considered to be applied to connectors, HDI connectors, S video terminal connectors, BNC connectors, various bus connectors, and the like.
[0115]
The above (1) to (4) are items independent of each other, and any number of these items may be appropriately combined.
[0116]
Note that any matter described in the specification or the drawings of the present application may be omitted, added to the scope of claims, or modified in the detailed description of the invention.
[0117]
【The invention's effect】
As described above, according to the present invention, in the signal transmission device that reduces the wasteful power consumption by stopping the power supply to the corresponding circuit when the plug is not inserted, the divided ground terminal and the divided connection detection are performed. Even though it has a very simple structure with the terminal, it can detect the presence or absence of the plug in the form of contact with the mating surface of the plug with high accuracy, and yet the processing accuracy is not so severe. Things are not required, and reliability can be improved while suppressing an increase in cost.
[0118]
Furthermore, it is possible to cope with the change only on the jack side, and it is not necessary to change the plug side, so it is possible to use the same plug as a general conventional one as it is. Yes, or it will be possible to apply new but general types that will be developed in the future.
[0119]
Also, whether or not the corresponding circuit is activated as expected by automatic power supply when plugged in, and the circuit as expected by automatic power shutoff when no plug is inserted It is possible to allow the user to check the control inconsistency state (in other words, to realize proper control) as to whether or not the inoperable state has been reached, thereby improving the operation reliability.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an electrical configuration of a transmission-side signal transmission device according to a first embodiment of the present invention.
FIG. 2 is a perspective view showing a structure of a coaxial cable jack in the signal transmission device according to the first embodiment.
FIG. 3 is a block diagram showing an electrical configuration of a signal transmission apparatus on the reception side according to the second embodiment of the present invention.
FIG. 4 is a block diagram showing an electrical configuration of a transmission-side signal transmission device according to a third embodiment of the present invention.
FIG. 5 is a block diagram showing an electrical configuration of a signal transmission apparatus on the reception side according to Embodiment 4 of the present invention.
6 is a perspective view showing a structure of an IEEE 1394 cable jack in the signal transmission device according to the fifth embodiment of the present invention. FIG.
FIG. 7 is a block diagram showing a schematic configuration of a connector with a connection confirmation function according to the first prior art.
FIG. 8 is a perspective view showing a schematic structure of a second conventional coaxial cable connector.
FIG. 9 is a circuit diagram showing a schematic configuration of a third conventional coaxial cable connector.
[Explanation of symbols]
50 Inner conductor
60 Outer conductor
63 Ground connection
64 Output terminal of ground connection
100 Jack for coaxial cable
100a Female contact
100b Split connection detection terminal
100c Divided ground terminal
100d Insulated connector
101 Signal processing means
102 Signal transmission means
103 Power supply means
104 switch means
105 Power control means
106 Pull-up resistor
107 Inconsistency state detection means
108 Inconsistency state notification means
201 Signal processing means
202 Signal receiving means
203 Power supply means
204 Switch means
205 Power control means
206 Pull-up resistor
207 Inconsistency state detection means
208 Inconsistency state notification means
300 Jack for IEEE 1394 cable
300a contact
300b Split connection detection terminal
300c Split ground terminal

Claims (3)

Depending on whether a signal transmission means, a power supply means for supplying power to the signal transmission means, a switch means interposed between the signal transmission means and the power supply means, and whether or not a plug is inserted into the jack Detects whether or not there is a mismatch in the control state based on comparing the power supply control means for controlling on / off of the switch means and the output state of the signal transmission means and the output state of the power supply control means. An inconsistency state detecting means, and an inconsistency state informing means for informing the inconsistency state by the inconsistency state detecting means
Leave without a partitioning connection detecting terminal and the other with forming a partitioning ground terminal is grounded one divided into a plurality of electrically separated state ground terminals in the jack, organic-merge of the plug relative to the jack It is configured to control power supply / cutoff based on switching between electrical connection / separation of the divided ground terminal and the divided connection detection terminal according to the need, and the signal transmission means is connected to the jack signal transmission apparatus characterized by being. Signal receiving means, power supply means for supplying power to the signal receiving means, switch means interposed between the signal receiving means and the power supply means, and depending on whether a plug is inserted into the jack Detects whether or not there is a mismatch in the control state based on comparing the power supply control means for controlling on / off of the switch means and the output state of the signal receiving means and the output state of the power supply control means. An inconsistency state detecting means, and an inconsistency state informing means for informing the inconsistency state by the inconsistency state detecting means
A ground terminal in the jack is divided into a plurality of parts in an electrically separated state, and one of the ground terminals is a grounded ground terminal that is grounded, and the other is a split connection detection terminal. Based on switching between electrical connection / separation of the divided ground terminal and the divided connection detection terminal according to the absence, it is configured to control power supply / cutoff, and the signal receiving means is connected to the jack A signal transmission device. 3. The signal transmission apparatus according to claim 1, wherein the inconsistency state notifying unit is a display unit .

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