JP4992669B2 - Cable connection device - Google Patents

Description

  The present invention relates to a cable connection device that transmits, for example, a video signal and an audio signal between a video camera device and a television receiver or between a television receiver and a VTR.

  In a cable connection device that transmits video signals and audio signals between a video camera device and a television receiver or between a television receiver and a VTR, the luminance signal and color signal that compose the television image are combined. In some cases, a composite video signal that can be handled at the same time is transmitted, and in other cases, a component video signal that allows a luminance signal, a synchronization signal, and a color signal constituting a television image to be separated and transmitted is transmitted. An audio signal may be transmitted in addition to either a composite video signal or a component video signal.

  For example, when transmitting a composite video signal, a cable for transmitting a composite video signal, a cable for transmitting an R channel audio signal, a cable for transmitting an L channel audio signal, and three cables A cable is required. When the S terminal is used, the luminance signal Y and the color signal C may be separated (Y / C separation), and the color signal may be transmitted after low-frequency conversion.

  For example, when transmitting a component signal, a cable for transmitting luminance (Y) and a synchronization signal, a cable for transmitting a color signal (Cr / Pr), and a color signal (Cb / Pb) are transmitted. Cable, a cable for transmitting an R channel audio signal, a cable for transmitting an L channel audio signal, and five cables are required.

  When transmitting any video signal, or any video signal and audio signal, it is necessary to unify the cable at the plug portion connected to the electronic device. The bushing portion of the plug portion has two upper and lower parts. Molded with a mold. At this time, it is necessary to make the upper and lower molds symmetrical so that a gap does not occur between the cable and the mold. For this reason, the cable is a composite round cable in which a plurality of cables are integrated and integrated, or a parallel cable in which a plurality of cables are arranged in a row and integrated.

  However, the composite round cable has a large crosstalk because the video signal core and the audio core are arranged close to each other. In order to prevent the composite round cable from becoming too thick, for example, the audio core may be made thinner than the video core. However, if the thickness of the core wire is changed, the structure of the composite round cable becomes complicated and expensive.

  Moreover, since a parallel cable arranges several cables in a line, it becomes wide and, as a result, a plug also enlarges. For this reason, in an electronic device such as a portable video camera device that has been reduced in size, the jack is also increased in size.

JP 60-226713 A

  An object of this invention is to provide the cable connection apparatus which can make crosstalk noise small, aiming at size reduction of a plug part.

  In order to solve the above-described problems, the cable connecting device according to the present invention includes a first cable complex in which odd-numbered cables are arranged in a row and integrally formed, and even-numbered cables are arranged in a row. A second cable composite that is integrally formed and a plug that holds the first cable composite and the second cable composite. In the state where the plug is combined so that the cable of the cable composite having the smaller number of cables is substantially positioned in the trough formed between the cables of the cable complex having the larger number of cables. And holding the end of the first cable complex and the end of the second cable complex.

  According to the present invention, the plugs are combined so that the cables of the cable composite having the smaller number of cables are substantially located in the valleys formed between the cables of the cable complex having the larger number of cables. In this state, since the end portion of the first cable complex and the end portion of the second cable complex are held, the crosstalk noise can be reduced while reducing the size of the plug portion.

  Hereinafter, the present invention will be described with reference to the drawings, taking as an example a case where a video camera device and a monitor are connected by a cable.

  In FIG. 1, an HD video camera device 10 capable of shooting a video with high image quality transmits an HD video signal to an HD monitor device 20 capable of displaying a high-quality video signal (HD video signal). The state where it is connected by the cable connection device 30 used for this purpose is shown. In addition, the SD video camera device 40 capable of capturing a video with standard image quality transmits the SD video signal to the SD monitor device 50 capable of displaying a standard image quality video signal (SD video signal). The state where it is connected by the cable connection device 60 used for this purpose is shown. The HD video camera device 10 capable of shooting a video with high image quality can also output an SD video signal. In this case, the HD video camera device 10 can also be connected to the SD monitor device 50 using the cable connection device 60.

  As described above, the HD video camera apparatus 10 can output the HD video signal and the SD video signal. For this reason, the HD video signal cable connection device 30 and the SD video signal cable connection device 60 are provided. The connection is selectively made in accordance with the type of video signal to be output.

  Further, in the HD video camera device 10, the jack 11 to which the HD video signal cable connection device 30 and the SD video signal cable connection device 60 are connected is the same in order to reduce the size and the like. It is one. Therefore, the plugs of the HD video signal cable connection device 30 and the SD video signal cable connection device 60 are the same. When the HD video signal is output from the HD video camera device 10 due to the fact that the plug shapes of the HD video signal cable connecting device 30 and the SD video signal cable connecting device 60 are the same, There is a possibility that the cable connection device 60 for signals may be connected by mistake, or when the SD video signal is output, the cable connection device 30 for HD video signals may be connected by mistake. Therefore, the HD video camera device 10 performs processing for determining the type of the connected cable connection device, and outputs an HD video signal or an SD video signal that matches the type of the connected cable connection device. Yes.

  Also for the SD video camera device 40, the HD video signal cable connection device 30 and the SD video signal cable connection device 60 have the same plug shape, so that the HD video signal cable connection is the same. The device 30 may be connected by mistake. Therefore, the SD video camera device 40 performs processing for determining the type of the connected cable connection device, and when the HD video signal cable connection device 30 is erroneously connected, the view finder of the SD video camera device 40. You can now warn the monitor that the cable is wrong. Further, even when the HD video signal cable connection device 30 is connected to the conventional SD video camera device in which the process of determining the type of the connected cable connection device is not performed, For example, a screen such as a red color that reminds a warning to the viewfinder or the monitor of the monitor device 20 or the SD video camera device 40 is displayed.

  Note that the type determination of the connected cable performed in the HD video camera device 10 and the SD video camera device 40 is performed based on the ID incorporated in the plug. Although the details will be described later, here, the plug of the HD video signal cable connection device 30 has a built-in resistance element for distinguishing it from the SD video signal cable connection device 60 and other types of cables. The HD video camera device 10 and the SD video camera device 40 detect the resistance value to determine the type of cable.

(1) Description of Cable Connection Device 30 for HD Video Signal As shown in FIGS. 1 to 3, the cable connection device 30 used for connection between the HD video camera device 10 and the HD monitor device 20 is an HD video signal. A three-core parallel first cable complex 301 in which three first to third cables 301a, 301b, 301c are integrally formed in a line, and two first cables 301a, 301b, 301c. 4 and the 5th cable 302a, 302b and the 2nd core parallel 2nd cable composite 302 which integrally molded in the line, and the 1st cable composite 301 transmits an HD video signal. The second cable complex 302 is adapted to transmit audio signals.

  The first cable complex 301 transmits an HD video signal. In view of the fact that the HD video signal has a wider bandwidth than the SD video signal, the first cable complex 301 uses a cable of the cable connection device 60 for transmitting the SD video signal. A broadband cable is used. Specifically, the HD video signal is a component video signal composed of a luminance signal (Y), a first color signal (Pb), and a second color signal (Pr). Therefore, the first cable 301a constituting the first cable complex 301 transmits, for example, a luminance signal (Y), and the second cable 301b transmits, for example, the first color signal (Pb). Thus, for example, the second color signal (Pr) is transmitted by the third cable 301c.

  Further, the fourth cable 302a of the second cable complex 302 transmits an L channel audio signal, and the fifth cable 302b transmits an R channel audio signal.

  The first cable complex 301 and the second cable complex 302 as described above are provided with a multi-plug 304 on the side to be connected to the jack 11 of the HD video camera device 10, and are integrated by the multi-plug 304. For example, an RCA plug 303 is provided on the side connected to the HD monitor device 20. That is, in the case of RCA, as shown in FIG. 1, each of the first to third cables 301a, 301b, 301c of the first cable complex 301 is separated, and a Y plug 303a is provided on the first cable 301a. The second cable 301b is provided with a Pb plug 303b, and the third cable 301c is provided with a Pr plug 303c. Further, the fourth and fifth cables 302a and 302b of the second cable complex 302 are separated, the Lch audio plug 303d is provided in the fourth cable 302a, and the Rch audio plug 303e is provided in the fourth cable 302b. I have to.

  As shown in FIG. 2B, a multi-plug 304 that integrates the first cable complex 301 and the second cable complex 302 on the side connected to the jack 11 of the HD video camera device 10 has three cores. The parallel first cable complex 301 and the two-core parallel second cable complex 302 are the first cable complex 301 on the second cable complex 302 side of the first cable complex 301. In the valley 305a between the first cable 301a and the second cable 301b and the valley 305b between the second cable 301b and the third cable 301c, the fourth and The fifth cables 302 a and 302 b are arranged so as to be positioned, and are integrated by the multi-plug 304. As shown in FIG. 2 (B), the first cable complex 301 and the second cable complex 302 are stacked, so that the cable connecting device 30 is more than when five cables are arranged in a row. However, the width of the multi-plug 304 can be reduced, and for example, the outer shape can be accommodated in a size of about 10 mm in length and 10 mm in width, so that downsizing can be achieved.

  Further, as shown in FIG. 2B, the back surface from which the first cable complex 301 and the second cable complex 302 of the multi-plug 304 are led is surrounded by the first cable complex 301 and the first cable complex 301. A support portion 307 that supports the periphery of the second cable complex 302 is provided.

  Further, when the first cable complex 301 and the second cable complex 302 are overlapped as described above, a plurality of outer trough portions 308 are formed on the outer side. Accordingly, a blocking portion 309 is formed on the support portion 307 formed around the back surface of the multi-plug 304 so as to block the substantially valley-shaped outer trough portion 308 continuously. The blocking portion 309 supports the first cable complex 301 and the second cable complex 302 and prevents foreign matters such as dust from entering the multi-plug 304. The first cable complex 301 and the second cable complex 302 are separated at a portion derived from the multi-plug 304, and each is flexibly displaced. The blocking portion 309 also prevents the first cable complex 301 and the second cable complex 302 from being excessively bent.

  As shown in FIGS. 2 to 4, the multi-plug 304 includes a terminal member 311 to which the first to fifth cables 301 a, 301 b, 301 c, 302 a, and 303 b are connected inside the case 306. A shell 312 provided so as to cover the terminal member 311 is provided.

  The case 306 constitutes the outer casing of the multi-plug 304, and is molded by PVC (polyvinyl chloride) resin or the like. The case 306 is provided with a main body 306a and a lead-out portion 306b from which the first cable complex 301 and the second cable complex 302 are led out on the back side of the main body 306a. As shown in FIG. 4, the main body 306a includes a terminal member 311 to which the first to third cables 301a, 301b, 301c and the fourth and fifth cables 302a, 302b are connected. A shell 312 or the like provided on the terminal member 311 is incorporated. The lead-out portion 306b is provided with a plurality of slits 306c and is formed to be more flexible than the main body portion 306a, and the first to third cables 301a, The cables 301b and 301c and the fourth and fifth cables 302a and 302b are protected from wear.

  As shown in FIGS. 4 to 7, the terminal member 311 is provided with a terminal portion 313 to be inserted into the jack 11 of the HD video camera device 10 on one end side, and the first to third cables on the other end side. A connection portion 314 for connecting 301a, 301b, 301c and the fourth and fifth cables 302a, 302b is provided.

  The terminal portion 313 has a plug portion formed in a substantially D shape, and is surrounded by a shell 312 having conductivity. The terminal portion 313 is a portion protruding from the front surface of the case 306 while being covered with the shell 312, and is a portion inserted into the jack 11 of the HD video camera device 10.

Here, the pin arrangement of the terminal portion 313 will be described with reference to FIGS. 5 (A) and 5 (B). In this example, as shown in FIG. 5A, the terminal portion 313 is provided with a total of ten pins in two rows of five pins.
(First row)
Pin 1 ... L channel audio signal terminal Pin 2 ... Blank here, but LANC (Local Application Control Control System) signal terminal, which is an interface used for consumer VCR control No. 3 Pin: GND terminal for video signal Pin 4: Blank here, but DC power supply terminal for LANC Pin 5: First color signal (Pb) terminal (second row)
Pin 6: R channel audio signal terminal Pin 7: Plug ID terminal, here, a resistance element (for example, 33 KΩ) indicating that it is a cable connection device 30 for HD video signals is connected. The other end of the resistance element is connected to GND.
Pin 8: GND terminal for audio signal Pin 9: Second color signal (Pr) terminal Pin 10: Luminance signal (Y) terminal As described above, the terminal unit 313 is an audio terminal. Terminals for signals (pins 1 and 6) are provided on one end in the longitudinal direction, and terminals for video signals (pins 10, 9 and 5) are provided on the other end in the longitudinal direction for output. The audio signals and video signals to be transmitted are prevented from interfering with each other by providing them on opposite sides of the terminal row and separating the distances.

  As shown in FIGS. 4 and 6 to 8, the connection portion 314 provided on the opposite side of the terminal portion 313 is provided with a first step portion 315 on the proximal end side, and then the first step A second step 316 thinner than the first step 315 is provided on the tip side of the step 315, and the first to third cables 301a and 301b are provided on the opposing surfaces of the step 315 and 316, respectively. , 301c and the fourth and fifth cables 302a, 302b are provided with connection terminals 317 to which the cables are connected by soldering or the like.

Specifically, on one surface of the first stepped portion 315, the first pin, the third pin, the connection terminals ₃₁₇ 1 corresponding to the fifth _pin, 317 3, 317 ₅ are provided, the second step portion Connection terminals 317 ₂ and 317 ₄ are provided on one surface of 316. In addition, connection terminals 317 ₆ , 317 ₈ , and 317 ₁₀ corresponding to the 6th pin, the 8th pin, and the 10th pin are provided on the other surface of the first stepped portion 315, and the second stepped portion 316 Connection terminals 317 ₇ and 317 ₉ are provided on the other surface. The first to third cables 301a, 301b, 301c and the fourth and fifth cables 302a, 302b are connected to the connection terminals 3171 to ₁₀ as follows.

Connection terminal 317 ₁ (corresponding to the first pin)... The fourth cable 302a (L channel audio signal) of the second cable complex 302 is connected.
Connection terminal 317 ₂ (corresponding to the second pin)... Blank here, but a LANC signal cable may be connected.
Connection terminal 317 ₃ (corresponding to the 3rd pin)... The GND line of the third cable 301c of the first cable complex 301 is connected.
Connection terminal 317 ₄ (corresponding to the 4th pin)... Blank here, but a LANC DC power supply cable may be connected.
Connection terminal 317 ₅ (corresponding to the fifth pin)... The second cable 301b (first color signal (Pb)) of the first cable complex 301 is connected.
Connection terminal 317 ₆ (corresponding to the 6th pin)... The fifth cable 302b (R channel audio signal) of the second cable complex 302 is connected.
Connection terminal 317 ₇ (corresponding to the 7th pin)... Is connected to one end of a resistance element (eg, 33 KΩ) 318 serving as a plug ID.
Connection terminal 317 ₈ (corresponding to the 8th pin)... The GND line of the fifth cable 302b of the second cable complex 302 is connected. Further, the other end of the resistance element 318 is connected.
Connection terminal 317 ₉ (corresponding to the 9th pin)... The third cable 301c (second color signal (Pr)) of the first cable complex 301 is connected.
Connection terminal 317 ₁₀ (corresponding to the 10th pin)... The first cable 301a (luminance signal (Y)) of the first cable complex 301 is connected.

  As shown in FIGS. 4 and 8, the GND line of each cable is connected to a shell 312 provided so as to cover the terminal portion 313 of the terminal member 311 by soldering or the like.

  The shell 312 has a surface plated with nickel or the like and has conductivity. The shell 312 includes a cylindrical portion 319 into which the terminal portion 313 of the terminal member 311 is inserted, and arm portions 320 and 320 formed on both sides of the cylindrical portion 319. Are connected to the GND line of each cable.

As described above, the multi-plug 304 is connected to the connection terminals 3171 to ₁₀ provided in the connection portion 317 of the terminal member 311 with the first to third cables 301a, 301b, and 301c and the fourth and fifth cables 302a. , 302b are connected by soldering or the like, and the GND line is connected to the shell 312 by soldering or the like. Then, the state shown in FIG. 8 is obtained, and thereafter, as shown in FIG. In order to protect the connection part of the member 311 or the shell 312 and the first to third cables 301a, 301b, 301c and the fourth and fifth cables 302a, 302b, that is, the connection part 314 of the terminal member 311, the inner mold 321 is protected. Is provided. Further, the portion where the inner mold 321 is provided is also a portion substantially corresponding to the main body portion 306a of the case 306 serving as the outer casing of the multi-plug 304 described above. The inner mold 321 is molded with PE (Polyethylene) resin or the like. Thereafter, the case 306 is molded on the inner mold 321.

  Here, FIG. 10 shows one first mold 330 when the case 306 is molded. The first mold 330 is a mold for molding the two-core parallel second cable complex 302 side, and includes a main body molding portion 331 for molding the main body portion 306a of the case 306, and a lead-out portion of the case 306. In a state where the lead-out part molding part 332 for molding 306b and the terminal arrangement part 333 formed continuously with the main body molding part 331 in which the terminal part 313 of the terminal member 311 covered with the shell 312 is arranged are overlapped. It has a cable arrangement part 334 formed continuously with a lead-out part molding part 332 where a certain first cable complex 301 and a second cable complex 302 are arranged.

  FIG. 11 is a cross-sectional view of the cable placement portion 334 in a state where the first mold 330 and the second mold 340 abutted against the first mold 330 are clamped.

  The cable placement portion 334 includes substantially semicircular continuous cable holding portions 335a and 335a for holding the second cable composite 302, and the first cable composite 301 is provided on both sides of the cable holding portions 335a and 335b. Cable support portions 336a and 336b that support both sides of the cable are formed so as to protrude in parallel with each other.

  By the way, when the case 306 is molded, the resin is injected and filled into the cavity 339 formed by clamping the first mold 330 and the second mold 340. At this time, the resin injected and filled in the cavity 339 may ooze out along the outer trough 308 of the first cable composite 301 or the second cable composite 302 arranged in the cable placement portion 334. . Further, there is a possibility that the valleys 305a and 305b provided between the first cable complex 301 and the second cable complex 302 may ooze out.

  Therefore, as shown in FIGS. 10 and 11, the cable holding portions 335 a and 335 b of the cable placement portion 334 have the second ends held by the cable holding portions 335 a and 335 a at the end portions 337 on the cable support portions 336 a and 336 b side. The fourth and fifth cables 302a and 302b of the cable complex 302 are formed so as to protrude slightly inward so as to be compressed in directions close to each other. Further, even in the cable support portions 336a and 336b that support both sides of the first cable complex 301, the first to third cables 301a, 301b, and 301c are slightly inside so as to be compressed in directions close to each other. It is formed to overhang. That is, in the first mold 330, the first cable complex 301 and the second cable complex 302 are slightly compressed in the width direction by the cable holding portions 335a and 335a and the cable support portions 336a and 336b. To keep in. Furthermore, the end portions 338 of the cable support portions 336a and 336b, that is, the portions that abut the second mold 340 are formed in a substantially arc shape toward the outside.

  As shown in FIG. 11, the second mold 340 that is paired with the first mold 330 is substantially half of which holds the first to third cables 301a, 301b, 301c of the first cable complex 301. Circular cable holding portions 341a, 341b, and 341c are formed, and the cable holding portions 341a and 341c on both sides are formed in an arc shape of the cable support portions 336a and 336b of the first mold 330. A receiving portion 342 for receiving the tip portion 338 is formed.

  Therefore, as shown in FIG. 11, the mold clamping is performed so that the tip end portions 338 of the cable support portions 336 a and 336 b of the first die 330 are engaged with the receiving portions 342 of the second die 340. Then, the first cable complex 301 and the second cable complex 302 held in a slightly compressed state in the width direction by the cable holding portions 335a and 335a and the cable support portions 336a and 336b are shown in FIG. As indicated by the arrows, the second mold 340 further compresses the first cable complex 301 and the second cable complex 302 in a direction close to each other. As a result, in the state where the first mold 330 and the second mold 340 are clamped, the outer trough 308, in particular, between the first cable complex 301 and the second cable complex 302. The portions of the outer troughs 308a and 308a provided in are reduced. Therefore, the resin injected and filled into the cavity 339 is prevented from oozing out along the outer trough 308 of the first cable complex 301 or the second cable complex 302 arranged in the cable arrangement part 334. be able to. Further, the first cable complex 301 and the second cable complex 302 are also present in the valleys 305a and 305b formed between the first cable complex 301 and the second cable complex 302. By being compressed, it is possible to prevent the resin injected and filled into the cavity 339 from leaking out.

  In the mold apparatus including the first mold 330 and the second mold 340 as described above, the gate for injecting and filling the resin into the cavity 339 is separated from the cable placement section 334, for example, the main body molding section 331. The pressure on the cable placement portion 334 side is lowered to prevent the resin from leaking out.

  When the first mold 330 and the second mold 340 are opened and the multi-plug 304, which is a molded product, is ejected, the first and second molds 330 and 340 are compressed. The cable complex 301 and the second cable complex 302 return to the original state. As a result, as shown in FIG. 2B, the outer peripheral portions of the first cable complex 301 and the second cable complex 302 are substantially in close contact with the blocking portion 309, The strength is reinforced, and dust or the like can be prevented from entering the multi plug 304.

  In the cable connection device 30 for an HD video signal configured as described above, as shown in FIGS. 2 to 4, the first cable complex 301 and the second cable complex 302 are connected to the first cable. Since the fourth and fifth cables 302a and 302b of the second cable complex 302 are positioned in the valleys 305a and 305b of the complex 301 and integrated with the multi-plug 304, the cable is 5 The width of the multi-plug 304 can be made narrower than in the case of the 5-core parallel cable arranged in a single line, and the outer shape can be accommodated in a size of about 10 mm in length and 10 mm in width, for example, and downsizing is achieved. be able to. Further, the cable connection device 30 for HD video signals is configured such that the first cable complex 301 for video and the second cable complex 302 for audio are separated at portions other than the multi-plug 304. Thus, the crosstalk between the video signal and the audio signal can be reduced. For example, with the configuration as described above, a cable with a performance of 80 db or more can be realized. In addition, for example, an attenuation of 0.1 db or less can be realized at a characteristic impedance of 75Ω and 30 MHz.

  As shown in FIG. 11, in the cable connection device 30, the multi-plug 304 is arranged by superimposing the first cable composite 301 parallel to the three cores and the second cable composite 302 parallel to the two cores. Even when the case 306 serving as the outer casing is molded, the resin can be injected and filled in a state in which the first cable composite 301 and the second cable composite 302 are compressed in the direction of approaching each other. As a result, the seepage of the resin can be prevented, the appearance can be improved, the removal work such as burrs can be omitted, and the production efficiency can be improved.

  Further, as shown in FIG. 2B, the outer peripheral portions of the first cable composite 301 and the second cable composite 302 are substantially in close contact with the closed portion 309, and the closed portion 309 provides strength. In addition, it is possible to prevent dust and the like from entering the multi-plug 304.

  In the above example, the cable connecting device 30 for HD video signals in which the first cable composite 301 parallel to the three cores and the second cable composite 302 parallel to the two cores are stacked and integrated by the multi-plug 304. However, if the cable is a cable in which an odd number of parallel cables and an even number of cables are stacked, the same effect as the cable connecting device 30 can be obtained. For example, the cable connection device 60 used for transmitting the SD video signal is a three-core parallel cable composed of a cable for transmitting two audio signals and a cable for transmitting one video signal as will be described later. However, for example, a two-core parallel cable for transmitting an audio signal and a single cable for transmitting a video signal may be arranged in a valley portion of the two-core parallel cable.

  Further, in the cable connection device 30 for HD video signals as described above, a resistance element is used as the plug ID, but other identification means such as an RFID tag may be provided.

  The HD video signal cable connection device 30 is not limited to the connection between the HD video camera device 10 and the HD monitor device 20, but is used to connect the VTR to the HD monitor device 20 or the like. May be. The cable connection device 30 for HD video signals transmits a component video signal composed of a luminance signal (Y), a first color signal (Cb), and a second color signal (Cr). Also good.

  Further, the cable connection device 30 for HD video signal has a countermeasure against radiation noise from the cable and static electricity in the vicinity of the multi plug 304, the Y plug 303a, the Pb plug 303b, the Pr plug 303c, the Lch audio plug 303d, and the Rch audio plug 303e. As a countermeasure, a substantially cylindrical ferrite core member that passes through the cable may be provided.

(2) Description of Cable Connection Device 60 for SD Video Signal As shown in FIG. 1, the cable connection device 60 that connects the HD video camera device 10 or the SD video camera device 40 and the SD monitor device 50 is, for example, The first cable 601 for SD video signals and the second and third cables 602 and 603 for audio signals are integrally formed in a line. The cable connecting device 60 is connected to the HD video camera device 10 or the SD video camera device 40 on the side connected to the HD video signal cable connecting device 30. 600 is provided. The SD video signal cable connecting device 60 connected to the SD monitor device 50 is provided with the SD cable plug 604 on the first cable 601 and the Lch on the second cable 602. An audio plug 605 is provided, and an Rch audio plug 606 is provided on the third cable 603. The SD video signal plug 604 is, for example, an RCA plug that outputs a composite signal (VIDEO) or an S terminal. When three cables are used for video, a plug for luminance signal (SY) and a plug for color signal (SC) are provided in addition to the plug for composite signal (VIDEO). Also good. The first to third cables 601, 602, and 603 are usually standard cables, but may be broadband cables as in the case of the cable connection device 30 for HD video signals. good.

  The multi-plug 600 connected to the HD video camera device 10 or the SD video camera device 40 is connected to jacks 11 and 41 provided on the HD video camera device 10 or the SD video camera device 40.

  Here, the pin arrangement of the multiplug 600 will be described with reference to FIGS.

1st pin: L channel audio signal terminal 2nd pin ... blank here, but LANC signal terminal 3rd pin ... GND terminal for video signal 4th pin ... blank here However, LANC DC power supply terminal Pin 5: Color signal (SC) terminal (second row)
Pin 6: R channel audio signal terminal Pin 7: Short. The resistance element 318 is not connected.
Pin 8: GND terminal for audio signals Pin 9: Composite signal (VIDEO) terminal Pin 10: Luminance signal (SY) terminal For SD video signals configured as described above The cable connection device 60 can connect the multi-plug 600 to the jack 41 of the HD video camera device 10 or the jack 41 of the SD video camera device 40. Then, the SD video signal cable connection device 60 can display the SD video signal on the SD monitor device 50.

  The SD video signal cable connection device 60 is not limited to the connection between the SD video camera device 40 and the SD monitor device 50, and is used to connect the VTR to the SD monitor device 50 and the like. May be. Also, the SD video signal cable connection device 60 has a substantially cylindrical ferrite core that passes through the cable as a countermeasure against radiation noise and static electricity from the cable, similarly to the HD video signal cable connection device 30. You may make it provide.

(3) Description of HD Video Camera Device 10 As described above, the HD video camera device 10 can selectively output an HD video signal and an SD video signal from the jack 11, The multi plug 304 of the HD video signal cable connection device 30 and the multi plug 600 of the SD video signal cable connection device 60 are selectively inserted and connected.

  The multi-plug 304 of the cable connection device 30 for HD video signals and the multi-plug 600 of the cable connection device 60 for SD video signals are physically the same, and the number of pins is ten. The jack 11 into which such multi-plugs 304 and 600 are inserted is configured to output a signal as shown in FIG.

  Here, the types of signals output from the 1st, 4th, 6th, and 8th pins do not differ depending on whether the HD video signal is output or the SD video signal is output.

  The 7th pin indicates a plug ID, which has a predetermined resistance value, for example, 33 kΩ when the cable connection device 30 is used for HD video signals, and when the cable connection device 60 is used for SD video signals, Since the resistance element is not connected, it is 0Ω.

  The 5th pin outputs the first color signal (Pb) when the HD video signal is output, and outputs the color signal (SC) when the SD video signal is output.

  The 9th pin outputs a second color signal (Pr) for HD video signals, and outputs a composite signal (VIDEO) for SD video signals.

  The 10th pin outputs a luminance signal (Y) in the case of an HD video signal, and outputs a luminance signal (S−Y) also in the case of an SD video signal.

  As shown in FIG. 14, the HD video camera apparatus 10 includes an HD digital signal processing circuit 101 that generates a digital HD video signal, an SD digital signal processing circuit 102 that generates a digital SD video signal, and an HD digital signal processing circuit. A first changeover switch 103 that switches between the digital signal 101 and the SD digital signal processing circuit 102; a D / A converter 104 that converts a digital HD video signal or digital SD video signal into an analog signal; and an analog HD video signal that can be output. The HD analog signal processing circuit 105 to be switched, the SD analog signal processing circuit 106 to be switched so that an analog SD video signal can be output, the microcomputer 107 that determines the type of the cable connection device connected to the jack 11, and the imaging unit HD video signal for video Comprises a recording unit 108 for recording and storing the SD video signal, an inverter 109 for switching and controlling the output of the HD analog signal processing circuit 105 and the SD analog signal processing circuit 106.

  The HD digital signal processing circuit 101 uses a luminance signal (Y), a first color signal (Pb), and a second color signal from a signal imaged by an image sensor such as a charge-coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS). The HD component video signal composed of the color signal (Pr) is generated and stored in the recording unit 108 as a digital signal. Also, the HD digital signal processing circuit 101 reads a digital HD video signal, that is, a component video signal from the recording unit 108 when outputting to the HD monitor device 20.

  The SD digital signal processing circuit 102 also outputs a luminance signal (S−Y) and a color difference signal (R−Y, B−Y) to a color signal (S−C) from a signal captured by an image sensor such as a CCD or CMOS sensor. Furthermore, the luminance signal (S−Y) and the color signal (S−C) are combined, and the composite signal (VIDEO) is stored in the recording unit 108 as a digital signal. Further, when outputting to the SD monitor device 50, the SD digital signal processing circuit 102 reads a digital SD video signal, that is, a composite signal (VIDEO) from the recording unit 108, and outputs a luminance signal (S) from the composite signal (VIDEO). -Y) and a color signal (SC) are generated.

  The first change-over switch 103 selects the HD digital signal processing circuit 101 when the HD video signal cable connection device 30 is connected, and selects the HD video signal, that is, the luminance signal (Y) and the first color signal ( Pb) and the second color signal (Pr) can be output to the D / A converter 104. The first changeover switch 103 selects the SD digital signal processing circuit 102 when the SD video signal cable connection device 60 is connected, and the luminance signal generated from the SD video signal, that is, the composite signal (VIDEO). (S−Y) and the color signal (S−C) can be output to the D / A converter 104.

  The D / A converter 104 has an input port 104a to which the HD video signal from the HD digital signal processing circuit 101 and the SD video signal from the SD digital signal processing circuit 102 are selectively input, and first to third outputs. Ports 104b, 104c, 104d.

  When a digital HD video signal is input from the HD digital signal processing circuit 101, the D / A converter 104 converts the digital luminance signal (Y) into an analog signal, and outputs the analog signal from the first output port 104b. The second color signal (Pr) is converted into an analog signal and output from the second output port 104c, and the digital first color signal (Pb) is converted into an analog signal and output from the third output port 104d. Output. The D / A converter 104 converts the digital luminance signal (S−Y) into an analog signal when the digital SD video signal is input from the SD digital signal processing circuit 102, and the first output port 104 b The digital color signal (S-C) is converted into an analog signal, output from the second output port 104c, and nothing is output from the third output port 104e.

  The HD analog signal processing circuit 105 turns on / off the output of the analog HD video signal. Specifically, the HD analog signal processing circuit 105 includes first to third switches 105a, 105b, and 105c serving as second switching means. The first switch 105a is provided between the first output port 104b of the D / A converter 104 and the 10th pin of the jack 11, and turns on / off the output of the analog luminance signal (Y) of the HD video signal. The second switch 105b is provided between the second output port 104c of the D / A converter 104 and the 9th pin of the jack 11, and turns on / off the output of the analog second color signal (Pr) of the HD video signal. To do. The third switch 105c is provided between the third output port 104d of the D / A converter 104 and the fifth pin of the jack 11 and turns on / off the output of the analog first color signal (Pb) of the HD video signal. To do.

  The SD analog signal processing circuit 106 turns on / off the output of an analog SD video signal. Specifically, the SD analog signal processing circuit 106 includes fourth to sixth switches 106a, 106b, and 106c serving as second switching means. The fourth switch 106a is provided between the first output port 104b of the D / A converter 104 and the 10th pin of the jack 11, and turns on / off the output of the analog luminance signal (S−Y) of the SD video signal. . The fifth switch 106b is provided between the second output port 104c of the D / A converter 104 and the fifth pin of the jack 11, and turns on / off the output of the analog color signal (SC) of the SD video signal. .

  In addition, the SD analog signal processing circuit 106 includes an adder 106 d that adds outputs from the first output port 104 b and the second output port 104 c of the D / A converter 104. The adder 106d adds the analog luminance signal (S−Y) and the color signal (S−C) of the SD video signal to generate a composite signal (VIDEO). The sixth switch 106c is provided between the adder 106d and the 9th pin, and turns on / off the output of the analog composite signal (VIDEO) of the SD video signal.

  The microcomputer 107 detects the resistance value of the 7th pin. Then, the microcomputer 107 determines that the HD video signal cable connection device 30 is connected to the jack 11 when the predetermined value, for example, 33 kΩ, and if it is 0Ω, the SD video signal cable is connected to the jack 11. It is determined that the connection device 60 is connected. When ∞Ω, it is determined that nothing is connected to the jack 11. Specifically, when the microcomputer 107 determines that the HD video signal cable connection device 30 is connected to the jack 11, the microcomputer 107 connects the first changeover switch 103 to the terminal 101 a, and the HD digital signal processing circuit 101. And D / A converter 104 are switched to be connected. When the microcomputer 107 determines that the SD video signal cable connection device 60 is connected to the jack 11, the microcomputer 107 connects the first changeover switch 103 to the terminal 102a, and the SD digital signal processing circuit 102 and the D / A converter 104 is switched to be connected. Further, the microcomputer 107 outputs a control signal for switching and controlling the first to third switches 105a, 105b, 105c and the fourth to sixth switches 106a, 106b, 106c to the inverter 109.

  The inverter 109 switches and controls the first to third switches 105a, 105b, and 105c and the fourth to sixth switches 106a, 106b, and 106c based on a control signal input from the microcomputer 107. Specifically, the inverter 109 turns on the first to third switches 105a, 105b, and 105c and turns off the fourth to sixth switches 106a, 106b, and 106c when outputting an analog HD video signal. . Accordingly, the analog luminance signal (Y) of the HD video signal is output from the 10th pin of the jack 11, and the analog second color signal (Pr) of the HD video signal is output from the 9th pin. ) And the first analog color signal (Pb) of the HD video signal is output from the fifth pin.

  In addition, when outputting an analog SD video signal, the inverter 109 turns off the first to third switches 105a, 105b, and 105c and turns on the fourth to sixth switches 106a, 106b, and 106c. Thus, the analog luminance signal (S-Y) of the SD video signal is output from the 10th pin of the jack 11, and the analog composite signal (VIDEO) of the SD video signal is output from the 9th pin. And the analog color signal (SC) of the SD video signal is output from the fifth pin.

  Next, a processing procedure until the type of the cable connection device connected to the jack 11 of the HD video camera device 10 is detected and the HD video signal or SD video signal is output will be described with reference to FIG.

  In step S1, the microcomputer 107 detects the resistance value of the 7th pin, determines whether the resistance value is changed from ∞Ω to 0Ω or 33kΩ, and when it becomes 33kΩ or 0Ω, the microcomputer 11 receives the HD video signal. It is determined that either the multi-plug 304 of the cable connection device 30 or the multi-plug 600 of the cable connection device 60 for SD video signals is connected. When the cable is connected to the jack 11, the microcomputer 107 determines in step S2 whether the resistance value is a predetermined value, for example, 33 kΩ, and when the resistance value is the predetermined value, the cable connecting device for HD video signals. 30 is determined to be connected, and the process proceeds to step S3. If the resistance value is not a predetermined value, the microcomputer 107 determines that the SD video signal cable connection device 60 is connected, and proceeds to step S4.

  When the HD video signal cable connection device 30 is connected, the microcomputer 107 connects the first changeover switch 103 to the terminal 101a in step S3 so that the HD video signal can be output to the D / A converter 104. To do. Further, the microcomputer 107 turns on the first to third switches 105a, 105b, and 105c and turns off the fourth to sixth switches 106a, 106b, and 106c via the inverter 109.

  As a result, the HD digital signal processing circuit 101 outputs a component video signal composed of the luminance signal (Y), the first color signal (Pb), and the second color signal (Pr) to the D / A converter 104, and D The / A converter 104 converts the digital signal into an analog signal and outputs an analog luminance signal (Y) from the first output port 104b. This analog luminance signal (Y) is output to the 10th pin via the first switch 105a. The D / A converter 104 outputs an analog second color signal (Pr) from the second output port 104c. The analog second color signal (Pr) is output to the 9th pin via the second switch 105b. The D / A converter 104 outputs an analog first color signal (Pb) from the third output port 104d. The analog first color signal (Pb) is output to the fifth pin through the third switch 105c. Audio signals are output from the 1st and 6th pins.

  As shown in FIG. 1, in the HD video signal cable connection device 30, the Y plug 303a is connected to the Y input terminal 21a of the HD monitor device 20, the Pb plug 303b is connected to the Pb input terminal 21b, and Pr A plug 303c is connected to the Pr input terminal 21c. Furthermore, the Lch audio plug 303d is connected to the Lch audio input terminal 21d, and the Rch audio plug 303e is connected to the Rch audio input terminal 21e. Accordingly, the HD monitor device 20 displays the HD video signal and outputs a stereo audio signal.

  When the SD video signal cable connection device 60 is connected, the microcomputer 107 can connect the first changeover switch 103 to the terminal 102a and output the SD video signal to the D / A converter 104 in step S4. Like that. Further, the microcomputer 107 turns off the first to third switches 105a, 105b, and 105c and turns on the fourth to sixth switches 106a, 106b, and 106c via the inverter 109.

  Thus, the SD digital signal processing circuit 102 outputs the luminance signal (SY) and the color signal (SC) to the D / A converter 104, and the D / A converter 104 converts the digital signal into an analog signal. After conversion, an analog luminance signal (SY) is output from the first output port 104b. The analog luminance signal (S−Y) is output to the 10th pin through the fourth switch 106a. The D / A converter 104 outputs an analog color signal (SC) from the second output port 104c. This analog color signal (SC) is output to the fifth pin through the fifth switch 106b. The adder 106d adds the analog luminance signal (SY) and the color signal (SC) to generate a composite signal (VIDEO) and outputs it to the 9th pin. Audio signals are output from the 1st and 6th pins.

  In the SD video signal cable connection device 60, as shown in FIG. 1, the SD video signal plug 604 is connected to the RCA composite input terminal or S terminal 61a of the SD monitor device 50. Further, the Lch audio plug 605 is connected to the Lch audio input terminal 61b, and the Rch audio plug 606 is connected to the Rch audio input terminal 61c. Therefore, the SD monitor device 50 displays the SD video signal and outputs a stereo audio signal.

  The HD video camera apparatus 10 configured as described above can output both an HD video signal and an SD video signal, but when adopting such a configuration, an HD video signal is output to one jack 11. Since both the multi-plug 304 of the signal cable connection device 30 and the multi-plug 600 of the cable connection device 60 for SD video signal are connected, the number of jacks can be reduced as compared with the prior art. Reduction can be achieved, and the overall size of the apparatus can be reduced. In the HD video camera device 10, both the multi plug 304 of the cable connection device 30 for HD video signal and the multi plug 600 of the cable connection device 60 for SD video signal are connected to the jack 11. At this time, the type of cable is determined, and the HD video signal and the SD video signal are output according to the determination result, so that an erroneous video signal is output to the HD monitor device 20 and the SD monitor device 50. Can be prevented.

  In the HD video camera device 10, the microcomputer 107 may discriminate more types of cables. For example, in the above example, the cable connection device 30 for HD video signals is defined as 33 kΩ and the cable connection device 60 for SD video signals is defined as 0 Ω. However, another resistance value is assigned to headphones and earphones. The resistance value may be assigned to the cable to be connected, and the microcomputer 107 may further determine the resistance value. In this case, only the Lch audio signal and the Rch audio signal are output. Furthermore, another resistance value may be assigned to a cable connected to an operation device such as a remote operation device, and the microcomputer 107 may determine this resistance value. In this case, control signals are exchanged using the 2nd and 4th pins used for the LANC, which is blank in the above example. Thus, the microcomputer 107 can discriminate more types of cables.

(4) Description of SD Video Camera Device 40 The SD video camera device 40 has a jack 41 that outputs an SD video signal. The jack 41 outputs SD video signals exclusively, and is connected to the cable connection device 60 for SD video signals. The multi-plug 304 of the cable connection device 30 for HD video signals and the SD video are connected. In view of the fact that the multi-plug 600 of the signal cable connection device 60 has the same physical shape, it is physically the same as the jack 11 of the HD video camera device 10.

  As shown in FIG. 16, the SD video camera device 40 includes an SD digital signal processing circuit 401 that generates a digital SD video signal, a D / A converter 402 that converts the digital SD video signal into an analog signal, and an analog SD video. SD analog signal processing circuit 403 for generating a signal, warning data memory 404 storing warning data to be displayed when an incorrect cable connection device is connected to jack 41, and cable connection connected to jack 41 A microcomputer 405 for discriminating the type of apparatus and a changeover switch 406 for switching the output of the SD digital signal processing circuit 401 are provided.

  The SD digital signal processing circuit 102 generates a color signal (S−C) from a luminance signal (S−Y) and a color difference signal (R−Y, B−Y) from a signal captured by an image sensor such as a CCD or a CMOS sensor. Further, the luminance signal (S−Y) and the color signal (S−C) are combined and the composite signal (VIDEO) is stored in the recording unit 407 as a digital signal. The SD digital signal processing circuit 102 reads a digital SD video signal, that is, a composite signal (VIDEO) from the recording unit 407 and outputs a luminance signal (S) from the composite signal (VIDEO) when output to the SD monitor device 50. -Y) and the color signal (SC) are separated.

  The changeover switch 406 is turned on when the SD video signal cable connection device 60 is connected, and the SD video signal, that is, the luminance signal (SY) and the color signal (SC) are D / A. The output to the converter 402 is made possible. Further, the changeover switch 406 is turned off when the wrong type of cable, for example, the cable connection device 30 for HD video signal is connected, and prohibits the output of the SD video signal.

  The D / A converter 402 has an input port 402a to which the SD video signal from the SD digital signal processing circuit 102 is input, and first and second output ports 402b and 402c. When the digital SD video signal is input from the SD digital signal processing circuit 401, the D / A converter 402 converts the digital luminance signal (SY) into an analog signal and outputs the analog signal from the first output port 402b. The digital color signal (S-C) is converted into an analog signal and output from the second output port 402c.

  The SD analog signal processing circuit 403 generates an analog SD video signal to be output. Specifically, the SD analog signal processing circuit 403 includes an adder 403 a that adds the outputs of the first output port 402 b and the second output port 402 c of the D / A converter 402. The adder 403a adds the analog luminance signal (S−Y) and the color signal (S−C) of the SD video signal to generate a composite signal (VIDEO).

  Accordingly, the analog luminance signal (S−Y) output from the first output port 402 b of the D / A converter 402 is input to the 10th pin of the jack 41 and the second output port of the D / A converter 402. The analog color signal (SC) output from 402c is input to the fifth pin of the jack 41, and the composite signal (VIDEO) generated by the adder 403a is input to the ninth pin. .

  The warning data memory 404 displays a warning on a display unit 408 such as a monitor or a viewfinder of the SD video camera device 40 when an incorrect cable is connected to the jack 41 instead of the cable connection device 60 for SD video signals. The data for is stored. For example, when the cable connection device 30 for HD video signals is connected to the jack 41 of the SD video camera device 40, there is a high possibility that it will be connected to the HD monitor device 20. That is, as shown in FIG. 1, the HD monitor device 20 is provided with component signal input terminals, that is, a Y input terminal 21a, a Pb input terminal 21b, and a Pr input terminal 21c. Therefore, the HD monitor device 20 is connected to the SD video camera device 40, and the SD video signal is input to the HD monitor device 20. Specifically, the Y plug 303a of the HD video signal cable connection device 30 is connected to the Y input terminal 21a, the Pb plug 303b is connected to the Pb input terminal 21b, and the Pr plug 303c is connected to the Pr input terminal 21c. Is done. For this reason, the SD video signal is input to the HD monitor device 20, and display is not performed correctly. For this reason, the warning data memory 404 stores warning data such as text data such as characters, image data, moving image data, audio data, and the like. For example, warning data such as “This cable is not compatible with this monitor” is stored in the warning data memory 404.

  The microcomputer 405 detects the resistance value of the 7th pin. The microcomputer 405 determines that the HD video signal cable connection device 30 is mistakenly connected to the jack 41 when the predetermined value, for example, 33 kΩ, and if it is 0Ω, the microcomputer 405 determines that the SD video signal is connected to the jack 41. The cable connection device 60 is determined to be connected, and when it is ∞Ω, it is determined that nothing is connected to the jack 41. Specifically, when the microcomputer 405 determines that the HD video signal cable connection device 30 is erroneously connected to the jack 41, the microcomputer 405 turns off the selector switch 406. When the microcomputer 405 determines that the SD video signal cable connection device 60 is correctly connected to the jack 41, the microcomputer 405 turns on the switch 406 and connects it to the terminal 401a. Switching is made so that the D / A converter 402 is connected.

  Next, a processing procedure from detection of the type of the cable connection device connected to the jack 41 of the SD video camera device 40 to output of the SD video signal will be described with reference to FIG.

  In step S11, the microcomputer 405 detects the resistance value of the 7th pin, determines whether the resistance value is changed from ∞Ω to 0Ω or 33kΩ, and when the resistance value becomes 0Ω or 33kΩ, the cable for the HD video signal is connected to the jack 41. It is determined that either the multi plug 304 of the connection device 30 or the multi plug 600 of the cable connection device 60 for the SD video signal is connected. When the cable is connected to the jack 41, the microcomputer 405 determines in step S12 whether the resistance value is a predetermined value, for example, 33 kΩ, and when the resistance value is the predetermined value, the cable connecting device for HD video signals. 30 is determined to be connected by mistake, and the process proceeds to step S13. If the resistance value is not the predetermined value, the microcomputer 405 determines that the SD video signal cable connection device 60 is correctly connected, and proceeds to step S14.

  When the HD video signal cable connection device 30 is mistakenly connected to the jack 41, the microcomputer 405 disconnects the changeover switch 406 from the terminal 401a in step S13, turns off the SD video signal, and prohibits the output of the HD video signal. The SD video signal is prevented from being output to the monitor device 20. At the same time, the microcomputer 405 reads the warning data from the warning data memory 404 and displays it on the display unit 408 such as a monitor or a viewfinder.

  When determining that the SD video signal cable connection device 60 is correctly connected, the microcomputer 405 turns on the changeover switch 406 to connect the terminal 401a and the D / A converter 402 in step S14. Accordingly, the SD digital signal processing circuit 401 outputs the luminance signal (SY) and the color signal (SC) to the D / A converter 402, and the D / A converter 402 converts the digital signal into an analog signal. After conversion, an analog luminance signal (S−Y) is output from the first output port 402b. This analog luminance signal (SY) is output to the 10th pin. The D / A converter 402 outputs an analog color signal (SC) from the second output port 402c. The analog color signal (SC) is output to the fifth pin. The adder 403a generates a composite signal (VIDEO) by combining the analog luminance signal (SY) and the color signal (SC), and outputs the composite signal (VIDEO) to the ninth pin. Audio signals are output from the 1st and 6th pins.

  In the SD video signal cable connection device 60, as shown in FIG. 1, the SD video signal plug 604 is connected to the RCA composite input terminal or S terminal 61a of the SD monitor device 50. Further, the Lch audio plug 605 is connected to the Lch audio input terminal 61b, and the Rch audio plug 606 is connected to the Rch audio input terminal 61c. Therefore, the SD monitor device 50 displays the SD video signal and outputs a stereo audio signal.

  In the SD video camera device 40 configured as described above, the microcomputer 405 determines whether the SD video signal cable connection device 60 is correctly connected, so that the HD video signal cable connection device 30 or the like is erroneous. Since the output of the SD video signal is prohibited when the cable is connected, it is possible to prevent an erroneous video from being displayed on the HD monitor device 20. At the same time, since the SD video camera device 40 is displayed on the display unit 408 such as a monitor or a viewfinder, the user mistakenly connects the cable connection device 30 for HD video signals to the SD video camera device 40. You can know what happened.

  In the example of FIG. 17, when the multi-plug 304 of the HD video signal cable connection device 30 is mistakenly connected to the jack 41, the SD video camera device 40 turns off the changeover switch 406, and the SD video signal. However, the output of the SD video signal may not be prohibited. In this case, as described below, a red image is displayed on the HD monitor device 20. In general, since red is a color used when warning is performed, the user erroneously connects the cable connection device 30 for HD video signals by displaying a red image on the HD monitor device 20. You can know what happened.

(5) Description of Existing SD Video Camera Device The existing SD video camera device is obtained by removing the configuration of the microcomputer 405 and the warning data memory 404 from the SD video camera device 40 shown in FIG. Has a similar configuration. That is, the jack of the output terminal that outputs the SD video signal is the same as the jack 41 of the SD video camera device 40 described above. Therefore, in addition to the multi plug 600 of the cable connection device 60 for SD video signals, the jack of the existing SD video camera device is connected to the multi of the cable connection device 30 for HD video signals connected to the HD monitor device 20. The plug 304 may be connected by mistake.

  When the multi-plug 304 of the HD video signal cable connection device 30 is mistakenly connected to the jack of the existing SD video camera device, the SD video signal is input to the HD monitor device 20 as shown in FIG. Will be.

  At this time, the HD video signal cable connection device 30 and the HD monitor device 20 are correctly connected. As a result, the SD video signal is connected to the input terminal of the HD monitor device 20 next. The SD signal as shown in FIG.

Luminance signal (SY): Luminance signal Y input terminal 21a of the HD monitor device 20
Color signal (SC) ... 1st color signal Pb input terminal 21b of the monitor device 20 for HD
Composite signal (VIDEO)
... Second color signal Pr input terminal 21c of HD monitor device 20
Then, as shown in FIG. 18, each of the luminance signal Y input terminal 21a, the first color signal Pb input terminal 21b, and the second color signal Pr input terminal 21b of the HD monitor device 20 detects the synchronization signal sync. It is supposed to be.

  For this reason, the luminance signal Y input terminal 21a of the HD monitor device 20 includes the synchronization signal sync in the luminance signal (SY) of the SD video signal. ) As the luminance signal (Y) of the HD video signal.

  Further, since the first color signal Pb input terminal 21b of the HD monitor device 20 does not include the synchronization signal sync even if the color signal (SC) of the SD video signal is input, the color signal (S- C) is not recognized as the first color signal (Pb) which is a blue component.

  Further, since the second color signal Pr input terminal 21c of the HD monitor device 20 includes the synchronization signal sync in the composite signal (VIDEO) of the SD video signal, the composite signal (VIDEO) of the SD video signal. Are recognized as the second color signal (Pr) of the HD video signal which is a red component.

  As a result, the HD monitor device 20 recognizes the luminance signal (Y) and the second color signal (Pr) of the SD video signal, and displays a red image. In general, since red is a color often used for warning, the user can know that an incorrect cable has been connected by looking at the HD monitor device 20.

  In the HD monitor device 20, as shown in FIG. 19, when a synchronization signal having an amplitude of a certain width or more is input, the luminance signal (Y), the first color signal (Pb), and the second color are displayed. Recognize the signal (Pr). Therefore, even when the plug connection between the HD video signal cable connection device 30 and the HD monitor device 20 is wrong, the HD monitor device 20 uses a color other than red in the following cases. Will be displayed.

Luminance signal (SY): Luminance signal Y input terminal 21a of the HD monitor device 20
Color signal (SC): Second color signal Pr input terminal 21c of the HD monitor device 20
Composite signal (VIDEO)
... First color signal Pb input terminal 21b of HD monitor device 20
In this case, since the composite signal (VIDEO) having a synchronization signal is input to the first color signal Pb input terminal 21b, a blue screen is displayed on the HD monitor device 20. Even in such a case, since the abnormal image is displayed on the HD monitor device 20, the user can know that the wrong cable is connected by looking at the HD monitor device 20. it can.

  As shown in FIG. 19, the HD monitor device 20 displays a brighter image as the amplitude of the luminance signal (SY) in the region X of the video signal is larger, and the amplitude of the composite signal (VIDEO) is larger. A red or blue screen will be displayed.

  The composite signal (VIDEO) is input to the luminance signal Y input terminal 21a of the HD monitor device 20, and the luminance signal (SY) is input to the first color signal Pb input terminal 21b or the second color signal Pr input terminal. 21c is input. In this case, since the luminance signal Y input terminal 21a recognizes the chroma component as a luminance signal, a glaring image is displayed as a whole. Even in such a case, since the abnormal image is displayed on the HD monitor device 20, the user can know that the wrong cable is connected by looking at the HD monitor device 20. it can.

(6) Modification of Cable Connection Device 30 for HD Video Signal In the above example, the case of using an RCA plug for connection with the HD monitor device 20 is described for the cable connection device 30 for HD video signal. For connection to the HD monitor device 20, a D terminal plug 22 may be used as shown in FIG. The D terminal plug 22 is connected to the D terminal 23 of the HD monitor device 20. In this method, HD component video signals (Y, Pb, Pr), R channel and L channel audio signals, and one connector can be connected, and the number of plugs can be reduced as compared with RCA.

It is a figure which shows the display system of HD video signal and SD video signal to which this invention is applied. (A) is the perspective view which looked at the multi-plug of the cable connecting device for HD video signals from the back side, and (B) is a back view. It is the perspective view which looked at the multiplug of the cable connection apparatus for HD image signals from the front side. It is a disassembled perspective view of the multi plug of the cable connection device for HD video signals. (A) And (B) is a figure which shows pin arrangement | positioning of the multi plug of the cable connection apparatus for HD video signals. It is a side view of a terminal member. It is a rear view of a terminal member. It is a perspective view which shows the state by which the cable was connected to the terminal member. It is a perspective view which shows the state by which the inner mold was provided in the state of FIG. It is a perspective view which shows the 1st metal mold | die for mold-molding the case used as the outer casing of a multiplug. It is sectional drawing of the cable arrangement | positioning part of the state by which the 1st metal mold | die and the 2nd metal mold were clamped. (A) And (B) is a figure which shows pin arrangement | positioning of the multi plug of the cable connection apparatus for SD video signals. It is a figure which shows pin arrangement | positioning of the jack of an HD video camera apparatus. It is a block diagram of a HD video camera device. It is a flowchart which shows the process sequence until it detects the kind of cable connection apparatus connected to the jack of HD video camera apparatus, and outputs an HD video signal or an SD video signal. It is a block diagram of an SD video camera device. It is a flowchart which shows the process sequence until it detects the kind of cable connection apparatus connected to the jack of SD video camera apparatus, and outputs an SD video signal. It is a figure which shows the relationship between SD video signal and HD component video signal. It is a figure which shows the amplitude of a video signal. It is a figure which shows the modification of the cable connection apparatus for HD video signals.

Explanation of symbols

10 HD video camera device, 11 jack, 20 HD monitor device, 30 HD video signal cable connection device, 40 SD video camera device, 50 SD monitor device, 60 SD video signal cable connection device, 301 1st Cable composite, 301a to 301c first to third cable, 302 second cable composite, 302a fourth cable, 302b fifth cable, 303 RCA plug, 303a Y plug, 303b Pb plug, 303c Pr Plug, 303d Lch audio plug, 303e Rch audio plug, 304 multi plug, 305a, 305b trough, 306 case, 306a main body, 306b lead-out part, 306c slit, 307 support part, 308 outer trough part, 309 closing part, 31 Terminal members, 312 shell 313 terminal portion 314 connection portion, the first stepped portion 315, 316 the first step portion 317 connecting terminal 318 resistor, 319 cylindrical portion, 320 arm, 321 inner mold

Claims (4)

A first cable complex in which an odd number of cables are lined up in one row and formed integrally;
A second cable complex in which an even number of cables are lined up in one row and formed integrally;
A plug for holding the first cable complex and the second cable complex;
In the state where the plug is combined so that the cable of the cable composite having the smaller number of cables is substantially positioned in the trough formed between the cables of the cable complex having the larger number of cables. A cable connecting device holding the end of the first cable complex and the end of the second cable complex. In the plug, an end of the first cable complex and an end of the second cable complex are formed between the cables of the cable complex having the larger number of cables by an inner mold. In the valley part, the combined state is maintained so that the cable of the cable composite with the smaller number of the cables is almost located,
2. The cable connection device according to claim 1, wherein a case is formed outside the inner mold. The first cable complex consists of three cables and transmits a video signal,
3. The cable connection device according to claim 2, wherein the second cable complex includes two cables and transmits an audio signal.   4. The cable connection device according to claim 3, wherein the video signal output terminal and the audio signal output terminal are provided on opposite sides of the output terminal row.

Images