JP3960344B2 - Imaging device - Google Patents

Description

  The present invention relates to an imaging apparatus that can be used in an information system that enables transmission and reception with a plurality of receiving devices using a liquid crystal monitor. Specifically, the liquid crystal monitor has a remote control function (hereinafter simply referred to as a remote control), This remote control is operated to transmit / receive wirelessly to / from TV (TV), VTR (video tape recorder) and its tuner, and display TV video on the LCD monitor, record TV video on the VTR, and display playback images. The imaging apparatus can be used in an information system that can be used.

Conventionally, many video camera apparatuses having a liquid crystal monitor have been proposed. The LCD monitor is electrically connected to the video camera body and can be opened and closed. In general, the LCD monitor is supported so that the angle can be changed in the open state. The remote control provided on the monitor transmits and receives wirelessly using infrared rays, etc., and the LCD monitor is operated to drive the video camera and the video camera is monitored while monitoring the video, or the video recorded on the video camera is played back as a playback image There is something that can be monitored with a monitor.
JP-A-8-205016 Japanese Patent Laid-Open No. 4-104580

  However, in both Patent Document 1 and Patent Document 2 described above, the liquid crystal monitor can be attached to and detached from the video camera main body, and the liquid crystal monitor is separated from the video camera main body. The camera can be used to send and receive wirelessly, operate the LCD monitor to drive the video camera by remote control and shoot while monitoring the video, or monitor the video recorded on the video camera as a playback image on the LCD monitor For example, a liquid crystal monitor having a remote control function is used to transmit and receive wirelessly to / from a TV or VTR and its tuner, display a TV image on the liquid crystal monitor, record a TV image on the VTR, and display a playback image on a liquid crystal display. There is no technology that can be seen on a monitor.

  The present invention uses a liquid crystal monitor having a remote control function and transmits / receives to / from a receiving device such as a TV or a receiving device such as a VTR, displays a TV image on the liquid crystal monitor, records a TV image on a VTR, It is an object of the present invention to obtain a suitable image pickup apparatus for use in an information system that can display an image on a liquid crystal monitor.

In order to achieve the above-described object, an imaging apparatus according to the present invention displays an imaging unit provided in an imaging apparatus main body and that captures an image of a subject, an audio input unit to which sound is input, and a captured image captured by the imaging unit. A display unit that is provided in the imaging apparatus main body and outputs a voice input from the audio input unit, a recording unit that records a captured image, and provided in the imaging apparatus main body and also for the captured image A first recording operation unit that controls the start of recording in the recording unit, and the display unit includes a second recording operation unit that controls the recording start of the captured image in the recording unit, and an audio input unit. The most important feature is that a second sound output unit for outputting the input sound is provided .

  In the imaging apparatus of the present invention configured as described above, an infrared device or the like is used for a first receiving device such as a television or a second receiving device such as a tuner of a VTR using an operation device such as a remote controller and a wireless transmission / reception device. Can be selectively transmitted / received by a radio signal using the video signal, so that the video signal from the first receiving device can be displayed on a display means such as a liquid crystal monitor or the video from the second receiving device. The signal can be displayed on the display means.

  In the image pickup apparatus of the present invention, a wireless transmission / reception device is used using an operation device such as a remote control, and a first reception device such as a television or a second reception device such as a VTR is used by a wireless signal using infrared rays or the like. The video signal from the first receiver can be displayed on the display means such as a liquid crystal monitor, or the video signal can be recorded on the second receiver and recorded. The reproduced video signal can be reproduced and displayed by the display means.

  Furthermore, in the imaging apparatus of the present invention, the operating device uses infrared rays or the like for the first receiving device that receives a video signal from a television or the like and the second receiving device that receives a video signal from a tuner such as a VTR. The first or second video signal from the first or second receiving device is transmitted as a radio signal using infrared rays or the like, and the first or second video signal is transmitted. A wireless transmission / reception device that receives a video signal as a wireless signal is provided, and the first or second video signal received by the wireless transmission / reception device can be displayed by display means such as a liquid crystal monitor.

  In the imaging device of the present invention, the operation device uses infrared rays or the like for the first receiving device that receives a video signal from a television or the like and the second receiving device that receives a video signal from a tuner such as a VTR. The first video signal selected by the first receiving device or the second video signal reproduced by the second receiving device is transmitted wirelessly, and the first or A wireless transmission / reception device that wirelessly receives the second video signal is provided, and the first video signal received by the wireless transmission / reception device or the reproduced second video signal can be displayed by display means such as a liquid crystal monitor.

An imaging unit, an audio input unit, a display unit, a first audio output unit, a recording unit, and a first recording operation unit are provided, and the display unit includes a second recording operation unit and a second audio output unit. A wireless transmission / reception device is used by using an operation device such as a remote controller, and is selectively transmitted / received to / from a first reception device such as a television or a second reception device such as a VTR tuner by a wireless signal using infrared rays or the like. Thus, an image pickup apparatus capable of displaying a video signal from the first receiving apparatus on a display means such as a liquid crystal monitor or displaying a video signal from the second receiving apparatus on the display means can be easily provided. Realized by simple configuration.

Embodiments of an information system using an imaging apparatus of the present invention will be described below with reference to the drawings.
This embodiment is an example of an information system in which the liquid crystal monitor 1 as an operation device can be used alone, FIG. 1 is an example of use, FIG. 2 is a block diagram of the information system, and FIG. An external view of the liquid crystal monitor 1 is shown.

  Reference numeral 2 denotes an infrared transmitter / receiver having a TV tuner 38 disposed on a wall of the room, etc., and this infrared transmitter / receiver 2 constitutes a second transmitter / receiver. The infrared transmitter / receiver 2 transmits the image signal and the audio signal from the TV tuner 38 as an infrared signal. Reference numeral 3 denotes an infrared transmitter / receiver indicating the first transmitter / receiver. The infrared transmitter / receiver 3 transmits a video signal and an audio signal from the TV 4 and a VTR 5 as an example of a video recording / reproducing device as infrared signals.

  As shown in FIG. 3, the liquid crystal monitor 1 includes a monitor main body 6 in which a circuit board is formed and a liquid crystal panel having a liquid crystal screen 7 as display means on the back side of the monitor main body 6. An infrared light receiving unit 9 is provided on the upper part of the unit 8 and the monitor body 6. The infrared light receiver 9 is rotatable in a free angle direction by a universal joint supported on the monitor body 6 via a bracket (not shown).

Speaker 10 showing a first specific example of the second audio output portion to the monitor main body portion 6, volume control 11 of the speaker 10, a second specific example of the second audio output portion headphone 12 is connected A headphone terminal 13 and a microphone 14 are shown. The infrared light receiving portion 9 provided in the monitor main body portion 6 in this example is provided across the width of the upper portion of the main body portion 6. Of course, an infrared light emitting element (not shown) is provided on the back surface of the monitor body 6.

  The liquid crystal panel unit 8 has a remote control unit 15, and a remote control button 17 and a narration button 18 are provided on the remote control unit 15. The remote control unit 15 is separated from the connection unit 19 with respect to the liquid crystal panel unit 7 and can be used alone. Reference numeral 20 denotes a liquid crystal monitor display on / off switch.

Next, an example of the circuit configuration of the liquid crystal monitor 1 is shown in FIG.
The liquid crystal monitor 1 is supplied with power to a control circuit 23, a backlight power supply unit 24, and a liquid crystal drive circuit 25 through a power supply circuit 22 connected to a battery 21. A backlight 26 is turned on by the backlight power supply unit 24 to illuminate the liquid crystal screen 7.

  The battery 21 is built in the monitor body 1. The infrared light receiving unit 9 of the liquid crystal monitor 1 includes a video signal light receiving element 9a and an audio signal light receiving element 9b. The video signal light receiving element 9a is connected to the liquid crystal drive circuit 25 through a decoder 27, and the audio signal light receiving element 9b is a decoder. 28 and the amplifier 29 are connected to the speaker 10 and the headphone terminal 13.

  Reference numeral 30 denotes an infrared light emitting element connected from the control circuit 23 of the liquid crystal monitor 1 via the encoder 31. Also connected to the control circuit 23 are a channel switching button 32 and a switch 36 that is selectively switched to a TV side terminal 33, a VTR side terminal 34, and a TV tuner side terminal 35.

  The infrared transmitter / receiver 2 of the TV tuner is configured as shown in FIG. That is, the TV tuner 38 connected to the antenna 37 has an infrared light emitting element 40 that emits a video signal as an infrared signal via an encoder 39, and an infrared light emitting element that emits an audio signal as an infrared signal via an encoder 41. 42 and an infrared receiving element 44 for receiving an infrared signal channel signal via a decoder 43. As the power source of the infrared transmitter / receiver 2, a household AC power source is used.

  On the other hand, the infrared transmitter / receiver 3 has a video signal output terminal 4a and an audio signal output terminal 4b from the TV 4, and also has a video signal output terminal 5a and an audio signal output terminal 5b from the VTR 5. The video signal output terminals 4a and 5a of the TV 4 and VTR 5 can be switched by a video signal switching switch 45, and the audio signal output terminals 4b and 5b of the TV 4 and VTR 5 can be switched by an audio signal switching switch 46.

  The video signal changeover switch 45 and the audio signal changeover switch 46 are switched by the selector 47 in conjunction with the TV 4 side and the VTR 5 side, and the selector 47 is connected to the infrared light receiving unit 49 via the decoder 48.

  The video signal changeover switch 45 described above includes an infrared light emitting unit 51 that emits a video signal as an infrared signal via an encoder 50, and the audio signal changeover switch 46 emits an audio signal as an infrared signal via the encoder 51. An infrared light emitting unit 52 is provided. Reference numeral 53 denotes a light receiving window for the power switch / channel of the TV 4, and 54 denotes a light receiving window of the power switch of the VTR 5.

  In the information system configured as described above, the procedure for monitoring the TV program on the liquid crystal monitor 1 using the TV tuner is as follows. First, the switch 36 of the liquid crystal monitor 1 is connected to the TV tuner side terminal 35 and the channel switching button 32 is connected. Is selected as a predetermined channel, an electric signal from the control circuit 23 is encoded into an infrared signal, emitted from the infrared light emitting element 30, and received by the infrared light receiving element 44 of the infrared transmitter / receiver 2. Then, this infrared signal is decoded and converted into an electric signal and input to the TV tuner 38. The video signal and audio signal of the channel thus selected are encoded here as infrared signals, emitted from the infrared light emitting elements 40 and 42, and received by the video signal receiving element 9a and the audio signal receiving element 9b of the liquid crystal monitor 1. Thereafter, the video signal is decoded and the TV broadcast can be monitored on the liquid crystal screen 7 via the liquid crystal drive circuit 25, and the audio signal can be decoded and listened to through the amplifier 29 via the headphones 12.

  On the other hand, the procedure for monitoring a TV program, VTR tuner or VTR playback video on the liquid crystal monitor 1 using the TV 4 and VTR 5 is as follows. Is encoded into an infrared signal, emitted from the infrared light emitting element 30, and received by the infrared light receiving unit 49 of the infrared transmitter / receiver 3. The infrared signal is decoded and converted into an electrical signal, and the video signal changeover switch 45 and the audio signal changeover switch 46 are connected to the VTR 5 side via the selector 47. Thus, the video signal and the audio signal from the VTR 5 are encoded and emitted from the infrared light emitting units 51 and 52, respectively, and received by the video signal receiving element 9a and the audio signal receiving element 9b of the liquid crystal monitor 1, and then the video signal is The decoded image can be monitored on the monitor screen 7 via the liquid crystal drive circuit 25 after decoding, and the audio signal can be decoded and listened to through the amplifier 29 with the headphones 12 or the like.

  Therefore, since it can be used as described above, another TV broadcast program can be viewed on the LCD monitor 1 or recorded on the VTR by using the VTR tuner only when watching TV with a family. It is convenient to monitor information on the liquid crystal monitor 1 as a reproduced image.

  Here, a reference example when applied to a video camera device using a liquid crystal monitor used in the information system of the present invention will be described.

[Reference Example 1]
4 is an overall perspective view of the video camera device as seen from the front side, and FIG. 5 is an overall perspective view of the video camera device as seen from the back side.

  The video camera apparatus includes a video camera main body 101 in which a video camera mechanism unit (imaging unit) and a VTR mechanism unit (recording unit) are accommodated, and a liquid crystal monitor 102 that is detachably supported on the back side of the video camera main body 101. It consists of and.

First, the configuration of the video camera body 101 will be described.
On the upper front of the video camera body 101 are a photographing lens 103 , a microphone 104 as an audio input unit, a zoom switching button 105 as a first zoom operation unit, and a start / stop button 106 as a first recording operation unit. There is a power switch 107 for switching between video camera operation and VTR operation at the upper part, and a viewfinder 108 and a speaker 109 as a first audio output part at the upper part on the rear surface.

  A part of the video camera body 101 has a battery lid 111 that can be opened and closed with a hinge 110 as a fulcrum, and a battery (not shown) serving as a power source of the video camera device is accommodated therein. Further, the back of the video camera body 101 is a back cover 112, and the back cover 112 is opened by operating the knob 113, and a tape cassette is inserted into and removed from a VTR mechanism (not shown) built in the video camera body 101. Can do.

  Further, an infrared transmission / reception mechanism 114 for transmitting and receiving signals between the video camera main body 101 and the liquid crystal monitor 102 using infrared rays is disposed on an upper side of the video camera main body 101. The infrared transmission / reception mechanism 114 will be described in detail later.

  Now, the liquid crystal monitor 102 supported on the back surface of the video camera main body 101 has a monitor main body portion 115 in which a circuit board is built, and a liquid crystal screen 116 on the back side of the monitor main body portion 115. A liquid crystal panel unit 117 as a display unit, a power source unit 118 of the monitor main body unit 115, and a battery 119 as a power source connected to the power source unit 118 are configured.

  FIG. 6 shows a perspective view of the above-described liquid crystal monitor 102 separated from the video camera main body 101, and FIG. 7 shows a mechanism for attaching and detaching the liquid crystal monitor 102 and the video camera main body 101.

  The monitor main body 115 and the liquid crystal panel 117 are coupled to each other by a hinge 120 at the upper end thereof, and the monitor main body 115 and the liquid crystal panel 117 are pivoted at a predetermined rotation angle with the hinge 120 as a rotation fulcrum. Can be stopped. The monitor body 115 and the liquid crystal panel 117 are electrically connected by a flexible substrate (not shown).

  The monitor main body 115 has a pair of hooks 121 and 121 at the upper front portion of the monitor main body 115 and a lock pin 122 at the lower front of the monitor main body 115. The lock pin 122 has a reduced diameter in which only the lower portion becomes a flat surface in the middle. It is formed in the portion 122a. In addition, a connector plug 123 composed of multiple terminals is provided on the front surface of the monitor main body 115, and an infrared light emitting element 124 as a transmission means is provided at another position.

  On the other hand, the monitor main body 115 is provided with an infrared light receiving element 125 as a receiver. The infrared light receiving element 125 is rotatable in a free angle direction by a universal joint 127 supported on the monitor body 115 via a bracket 126. A cord 128 electrically connects the monitor main body 115 and the infrared light receiving element 125.

  Further, a power supply unit 118 is integrally fixed to the monitor main body 115, and a lock knob 129 for attaching and detaching the battery 119 described above to a housing part on the back side of the power supply unit 118, as shown in FIG. An indicator lamp 130 that lights up when the battery 119 is sufficiently usable and blinks when the battery level is low, and a brightness adjustment dial 131 that is a brightness adjustment unit of the liquid crystal screen 116 are provided.

  In addition, a liquid crystal monitor display on / off switch 132 that is a switching operation unit, a start / stop button 133 that is a second recording operation unit for video shooting by the video camera body 101, 2 is a zoom button 134 which is a zoom operation unit.

  In the liquid crystal monitor 102 configured as described above, the connection of the monitor main body 115 to the video camera main body 101 is related to the hook portion 121 at the top of the monitor main body 115 with the recess 135 formed on the back surface of the video camera main body 101. By inserting the lock pin 122 into the lock hole 136 provided on the back surface of the video camera body 101 while being inserted, the lock pin 122 is locked to the snap spring 137 as shown in FIG. The reduced diameter portion 122a of the pin 122 can be engaged and mechanically coupled.

  At this time, the connector plug 123 is inserted into the connector jack 138 provided on the video camera main body 101 side, so that the monitor main body 115 and the video camera main body 101 can be electrically connected. When the monitor main body 115 is connected to the video camera main body 101, the lower flat portion of the lock pin 122 is brought into contact with the bottom of the lock hole 136, so that the monitor main body 115 is prevented from rattling up and down. Damage to the connector plug 123 and the connector jack 138 and poor electrical contact can be avoided.

Next, the detailed configuration of the infrared transmission / reception mechanism 114 will be described with reference to FIG.
A cylindrical outer cylinder 140 is fixed in a container 139 constituting the housing, and an elevating cylinder 141 that can move up and down is accommodated in the outer cylinder 140. An arm piece 142 protrudes from the lifting cylinder 141 through a guide hole 140 a formed in a part of the outer cylinder 140.

  The elevating cylinder 141 is provided with a light guide member 143 made of acrylic resin or the like, and two parallel infrared light emitting LED elements 144 and 144 on the light guide member 143. The light guide member 143 has an infrared incident window 143a facing the same direction as the LED element 144 below the infrared light emitting LED element 144 on the upper front side, and a reflecting surface 143b on which the incident infrared light from the incident window 143a is reflected at right angles. The bottom surface has an emission window 143c through which infrared rays reflected by the reflection surface 143b are emitted.

  The light guide member 143 and the infrared light emitting LED element 144 are covered with a light-shielding cover so as to expose the entrance window 143a and the exit window 143c of the light guide member 143 and the tip of the infrared light emitting LED element 144, thereby forming a transmission / reception unit 145. ing. The transmitter / receiver 145 is fitted to the elevating cylinder 141 in the circumferential direction by a fitting portion 146, whereby the infrared light emitting LED element 144 and the light guide member 143 described above together with the transmitter / receiver 145 are circular with the fitting portion 146 as a rotating portion. It can rotate in the circumferential direction.

  Further, a coil spring 147 is stretched between the bottom of the lifting cylinder 141 and the bottom of the outer cylinder 140, and the infrared light emitting LED covered with the transmission / reception section 145 together with the lifting cylinder 141 by the spring force of the coil spring 147. The element 144 and the light guide member 143 are pushed up, and the infrared light emitting LED element 144 and the incident window 143 a of the light guide member 143 protrude from the opening window 139 a on the upper surface of the container 139. That is, when the head of the transmitting / receiving unit 145 protruding from the opening window 139a of the container 139 is pushed down against the spring force of the coil spring 147, the lifting cylinder 141 is locked in a state of being pushed down by a lock mechanism (not shown), and the infrared ray The incident window 143a of the light emitting LED element 144 and the light guide member 143 is concealed in the opening window 139a of the container 139. When the head of the transmission / reception unit 145 is pushed again from this state, the lock mechanism of the elevating cylinder 141 is released and infrared light is emitted The incident window 143a of the LED element 144 and the light guide member 143 is a so-called push-push type locking mechanism that protrudes again from the opening window 139a of the container 139.

  On the other hand, there is a wiring board 148 at the bottom of the container 139. The wiring board 148 is provided with a remote control light receiving unit 149, and the remote control light receiving unit 149 has the infrared light receiving element 150 at a position facing the incident window 143a of the light guide member 143 described above. Further, the cord 144 a drawn out from the infrared light emitting LED elements 144 and 144 described above is wired to a predetermined circuit of the wiring board 148. Furthermore, a micro switch 151 is disposed on the wiring board 148 at a position corresponding to the arm piece 142 of the outer cylinder 140 described above.

  The infrared transmission / reception unit 114 configured as described above is attached to the video camera body 101 via a rotation unit 152. The rotation unit 152 moves the infrared transmission / reception mechanism 114 up and down with respect to the video camera body 101, although not shown in detail. It is good also as a structure rotated freely to the left-right direction with the up-down direction as needed, when rotating only to a direction. Of course, the infrared transmission / reception mechanism 114 and the video camera body 101 are electrically connected through the rotation means 152.

An example of the circuit configuration of the video camera main body 101 and the liquid crystal monitor 102 described above is shown in FIG.
The video camera body 101 is supplied with power to the control circuit 155, mechanical deck 156, backlight power supply unit 157, connector plug 138, and video / audio signal recording / playback circuit 158 via a power supply circuit 154 connected with a battery indicated by reference numeral 153. Supplied. The backlight 159 is turned on by the backlight power supply unit 157 to illuminate the liquid crystal display device 160 of the viewfinder 108.

  The control circuit 155 includes a mechanical deck 156, a video / audio signal recording / playback circuit 158, a group of buttons such as a start / stop button 106 of the video camera body 101, an infrared light receiving unit 150 via a decoder 161, a micro switch 151, and an encoder 162. Are respectively connected to the infrared light emitting LED elements 144.

  The video / audio signal recording / reproducing circuit 158 is connected to the infrared light emitting LED element 144 via the mechanical deck 156, the liquid crystal drive circuit 163, the liquid crystal display device 160 of the viewfinder 108, and the encoder 162, respectively. The audio signal from the recording / reproducing circuit 158 is output to the speaker 109 via the amplifier 164, and the video signal is output to the connector plug 138.

  The subject image from the photographic lens 103 is converted into a video signal by the CCD 165 and input to the video / audio signal recording / reproducing circuit 158 via the amplifier 166 and the video signal processing circuit 167. Further, the audio input to the microphone 104 is input to the video / audio signal recording / reproducing circuit 158 via the amplifier 168 and the audio signal processing circuit 169.

  On the other hand, the liquid crystal monitor 102 is supplied with power to the control circuit 171, the backlight power supply unit 172, the liquid crystal drive circuit 173, the connector jack 123, and the indicator lamp 130 via the power supply circuit 170 of the power supply unit 118 connected with the battery 119. . The backlight power source unit 172 turns on the backlight 174 to illuminate the liquid crystal screen 116.

  The control circuit 171 is connected to the liquid crystal drive circuit 173 and the monitor display on / off switch 132. The liquid crystal drive circuit 173 is connected to the infrared light receiving element 125, the connector jack 123, and the brightness adjustment knob 131 of the liquid crystal screen via the decoder 175.

  Reference numeral 176 denotes a remote control circuit built in the monitor main body 115 of the liquid crystal monitor 102. As a power source, a button battery 177 is used separately from the battery 119 described above. Then, it is connected to the infrared light emitting element 124 via an operation button such as a video shooting start / stop button 133 and an encoder 178.

Next, the operation will be described.
When the liquid crystal monitor 102 is connected to the video camera body 101, the connector plug 123 of the liquid crystal monitor 102 and the connector jack 138 of the video camera body 101 are electrically connected. Can be directly monitored on the liquid crystal screen 116 of the liquid crystal monitor 102 from the video camera main body 101 side, and can be used as a normal usage form of the video camera apparatus.

  Further, in the normal use state described above, the power supply circuit 154 on the video camera main body 101 side and the power supply circuit 170 on the liquid crystal monitor 102 side are connected. Therefore, the batteries 153 and 119 are common. This is supplied to the video camera body 101 and the liquid crystal monitor 102. However, when the voltage values of the batteries 153 and 119 are extremely different, a so-called known shutdown circuit may be provided that drops the battery voltage having a high voltage value.

  Further, the power supply circuit 170 of the liquid crystal monitor 102 is always checked by the control circuit 155 of the video camera body 101. Therefore, when the power supply of the video camera body 101 is turned off, the control circuit 155 senses this. Thus, the power supply circuit 170 of the liquid crystal monitor 102 is automatically turned off.

  Next, in a state where the liquid crystal monitor 102 is mechanically separated from the video camera main body 101, the video image by the video camera main body 101 is monitored by the liquid crystal monitor 102, or the video camera main body 101 is controlled by the liquid crystal monitor 102. The operation will be described with reference to FIGS.

  In FIG. 9, in use, first, the power switch 107 on the video camera body 101 side is turned on, and the head of the transmission / reception unit 145 of the infrared transmission / reception mechanism 114 is pushed to enter the infrared light emitting LED element 144 and the incident window 143a of the light guide member 143. Is projected from the opening window 139a of the container 139, so that the infrared light signal from the infrared light emitting LED element 144 can be emitted and the infrared signal from the liquid crystal monitor 102 can enter the incident window 143. Here, in the infrared transmission / reception mechanism 114, the arm piece 142 operates the microswitch 151 in a state where the transmission / reception unit 145 is pushed into the container 139 and is locked, and controls the control circuit 155 to control infrared rays from the infrared light emitting LED element 144. The generation of the signal is stopped, and the infrared light receiving element 150 is prevented from receiving the infrared signal from the incident window 143.

  In the example of FIG. 9, the transmission / reception unit 145 is directed to the opposite side of the video camera body 101 from the video shooting direction, and the infrared light receiving element 125 of the liquid crystal monitor 102 is opposed to the transmission / reception unit 145.

  Thus, when the start / stop button 133 of the liquid crystal monitor 102 is operated to operate the liquid crystal monitor display on / off switch 132, the electric signal from the remote control circuit 176 is encoded into an infrared signal and emitted from the infrared light emitting element 124. This infrared signal enters the light guide member 143 from the entrance window 143a of the infrared transmission / reception mechanism 114 shown in FIG. 8 of the video camera main body 101, is reflected from the reflection surface 143b of the light guide member 143 at a right angle, and exits from the exit window 143c. The light enters the infrared light receiving element 150. Then, the infrared signal is decoded again into an electric signal and controlled by the control circuit 155, and through the video / audio signal recording / reproducing circuit 158, in the case of video shooting, the video signal is encoded into the infrared signal and is transmitted from the infrared light emitting LED element 144. Light is emitted as an infrared signal, and is received by the infrared light receiving element 125 of the liquid crystal monitor 102. The infrared signal is decoded into a video signal, and the video signal can be monitored on the liquid crystal screen 116 via the liquid crystal drive circuit 173. At the same time, the video deck can be recorded by driving the mechanical deck 156.

  Further, by operating the zoom button 134 of the liquid crystal monitor 102 during video shooting, the infrared signal can be received by the video camera body 101 and zoom shooting can be performed in the same manner as described above.

  The infrared light emitting element 124 of the liquid crystal monitor 102 needs to be positioned sufficiently behind the infrared light receiving element 125 so that the signal from the infrared light emitting element 124 does not jump into the infrared light receiving element 125. That is, if the signal from the infrared light emitting element 124 jumps into the infrared light receiving element 125, it becomes noise and disturbs the image on the monitor screen, making it difficult to see.

  Further, by separating the battery of the remote control circuit 176 of the liquid crystal monitor 102 from the battery 119 as an original power source, there is an advantage that the video camera body 101 can be controlled by the battery of the remote control circuit even when the battery 119 becomes empty. . In addition, by using a rectangular wave for driving the remote control circuit 176, it is possible to avoid the problem that the signal is likely to be disturbed by noise when a common power source is used.

FIG. 11 shows one use example of the video camera device.
In this example, a video is taken at a wedding reception. In general, in such cases, the photographer is often busy taking video while looking through the viewfinder of the video camera or watching the LCD screen, but the video camera device of this example is not available. If used, the video camera body 1 is supported on a tripod 180 and placed on a table. The photographing lens can be directed to the groom and the bride, and the photographer 181 can perform operations such as zoom photographing while looking at the monitor screen of the LCD monitor 102. You can eat at the same time.

  As another usage, the video camera body 101 can be supported on a large tripod and placed in the corner of the room, and a photographer sitting on the table can operate the liquid crystal monitor 102 to take a video. Even if such a usage is wireless even if the waiter crosses in front of the video camera, it has no effect. In addition, the monitor screen disappears for a moment, but since the video camera is recording, the recording can be continued.

[Reference Example 2]
12 and 13 are perspective views showing another reference example of the video camera device, FIG. 12 is a perspective view of the video camera device viewed from the viewfinder side, and FIG. 13 shows the video camera body 101 and the liquid crystal monitor 102 separated from each other. It is a perspective view, and in the following description, only the parts different from the reference example 1 described above will be described, and the same parts will be denoted by the same reference numerals and redundant description will be omitted.

  In this example, the upper portion of the video camera main body 101 is formed in the concave portion 201, the video camera mechanism portion 202 is disposed in the concave portion 201, and the VTR mechanism portion is in the video camera main body 101. The video camera mechanism 202 has a photographing lens 203 and a microphone 204 on the front side and a viewfinder 205 on the back side, and the video camera mechanism 202 is configured to be capable of panning and tilting operations by a pan / tilt mechanism. Yes. Note that the upper surface of the video camera mechanism 202 is slightly lower than the left and right video camera main body 101 portions of the recess 201. For this reason, even if the video camera body 101 is accidentally dropped from the upper side, the video camera mechanism 202 can be protected from impact.

FIG. 14 shows details of the pan / tilt mechanism.
A U-shaped frame 206 is disposed in the recess 201 of the video camera body, and the frame 206 is supported at the center of the bottom on the bottom surface of the recess 201 so as to be rotatable in the horizontal direction by a support shaft 207. Then, both side surfaces of the video camera mechanism 202 described above are supported on the upper ends of the leg pieces 208 and 208 erected from both sides of the frame 206 through the support shafts 209 and 209 so as to be swingable in the vertical direction.

  A fan-shaped gear 210 is attached to the support shaft 209, a small-diameter gear 211 as a reduction gear meshes with the sector-shaped gear 210, and an output gear 214 of the motor 213 meshes with a large-diameter gear 212 as a sector gear. That is, the rotational drive of the motor 213 causes the sector gear 210 to rotate in the vertical direction together with the support shaft 209 from the output gear 214 via the large-diameter gear 212 and the small-diameter gear 211 as a reduction gear, As a result, the video camera mechanism 202 supported on the support shaft 209 can be swung in a so-called tilt direction (vertical direction). Note that the sector gear 210, the large and small diameter gears 211 and 212, and the motor 213 constituting the tilt mechanism are built in the video camera mechanism 202.

  On the other hand, a gear portion 215 with the support shaft 207 as a rotation center is formed on one side of the bottom portion of the frame 206 described above, and a small-diameter gear 217 of a reduction gear meshes with the gear portion 215 via a transmission gear 216, and the reduction gear. The large-diameter gear 218 is engaged with the output gear 220 of the motor 219. That is, by rotating the motor 219, the output gear 220 rotates around the support shaft 207 together with the gear 206 and the frame 206 via the large-diameter gear 218, the small-diameter gear 217, and the transmission gear 216 as a reduction gear. The video camera mechanism 202 can be swung in the panning direction (left-right direction). Of the pan mechanism, the transmission gear 216, the large and small diameter gears 217 and 218, and the motor 219 are built in the video camera body 101.

  Also, part of the left and right main body parts constituting the concave portion 201 of the video camera main body 101 is made up of window portions 221 and 222 made of red plastic or the like that transmit infrared rays. 224 is built-in. One infrared transmission / reception unit 223 has a pair of a light-emitting LED element 225 for image transmission and a light-emitting LED element 226 for audio transmission, and faces the three directions of the front side, the outer side, and the rear side of the video camera body 101. Is arranged. Below these, a sound signal receiving LED element 228 is arranged with a light shielding plate 227 so as to face the three directions of the front side, the outer side and the rear side of the video camera body 101 in the same manner as described above. . Further, a remote control signal light receiving element 229 is similarly arranged in three directions of the front side, the outer side, and the rear side of the video camera main body 101 in the main body portion below it.

  The other infrared transmission / reception unit 224 has a pair of image transmission light emitting LED elements 225 and sound transmission light emitting LED elements 226, an audio signal receiving LED element 228, and a remote control signal so as to face one of the remaining three directions. Each of the light receiving elements 229 is arranged.

Next, the configuration of the liquid crystal monitor 102 will be described.
The liquid crystal monitor 102 can also be separated from the video camera main body 101 by the attaching / detaching mechanism in the same manner as the reference example 1 described above, and the liquid crystal panel 117 can be rotated with respect to the monitor main body 115.

  The monitor main body 115 has a speaker 230, a volume knob 231 for the speaker 230, a headphone terminal 233 to which the headphones 232 are connected, and a microphone 234. In addition, the infrared light receiver 125 provided in the monitor main body 115 is provided over the width of the upper portion of the main body 115 in this example. Of course, an infrared light emitting element (not shown) is provided on the back surface of the monitor main body 115.

  In addition, the liquid crystal panel unit 117 includes a remote control unit 235, and the remote control unit 235 is provided with a joystick 236 for controlling the pan / tilt mechanism described above, a remote control button 237, and a narration button 238. The remote control unit 235 is separated from the connection unit 239 with respect to the liquid crystal panel unit 117 and can be used alone.

  An example of the circuit configuration of the video camera body 101 and the liquid crystal monitor 102 described above is shown in FIG. The same parts as those in the circuit configuration described in FIG. 10 of the reference example 1 described above are denoted by the same reference numerals, and redundant description will be omitted, and different parts will be described.

  The image transmission light emitting LED element 225 and the sound transmission light emitting LED element 226 of the video camera body 101 are connected to the video / audio signal recording / reproducing circuit 158 via encoders 240 and 241, respectively. The audio mix circuit 243 is connected via the decoder 242, and this audio mix circuit 243 is connected between the video / audio signal recording / reproducing circuit 158 and the audio signal processing circuit 169. The remote control signal receiving element 229 is connected to the control circuit 155 via the decoder 244. Further, an initialization button 245 is connected to the control circuit 155, and the initialization button 245 is provided in the vicinity of the start / stop button 106 of the video camera body 101.

  The motors 213 and 219 of the pan / tilt mechanism are driven by a motor drive circuit 246. The motor drive circuit 246 is connected to a power supply circuit 154 and controlled by a signal from the control circuit 155.

  On the other hand, reference numeral 247 denotes a battery for power supply of the liquid crystal monitor 102 and is built in the monitor main body 115. The infrared light receiving element 125 of the liquid crystal monitor 102 includes a video signal light receiving element 125a and an audio signal light receiving element 125b. The video signal light receiving element 125a is connected to the liquid crystal drive circuit 173 via the decoder 248 to receive the audio signal. The element 125 b is connected to the speaker 230 and the headphone terminal 233 via the decoder 249 and the amplifier 250.

  The infrared light emitting element includes an audio signal light emitting element 124a and a remote control signal light emitting element 124b. The audio signal light emitting element 124a is connected to the microphone 234 via the encoder 251 and the amplifier 252, and the remote control signal light emitting element 124b. Is connected to the remote control circuit 253. The remote control circuit 253 uses a button battery 254 separately from the battery 247 described above, and the remote control unit 235 is connected to the remote control signal light emitting element 124b via the encoder 255.

Next, the operation will be described.
When the liquid crystal monitor 102 is connected to the video camera body 101, the connector plug 123 of the liquid crystal monitor 102 and the connector jack 138 of the video camera body 101 are electrically connected. Can be directly monitored on the liquid crystal screen 116 of the liquid crystal monitor 102 from the video camera main body 101 side, and can be used as a normal usage form of the video camera apparatus. In this embodiment, the audio signal as well as the video signal monitor can be heard through the speaker 230 or the headphones 232 of the liquid crystal monitor 102.

  In the normal use state described above, the power supply circuit 154 on the video camera body 101 side and the power supply circuit 170 on the liquid crystal monitor 102 side are connected, and the battery 247 of the liquid crystal monitor 102 is charged by the battery 153 of the video camera body 101. When the liquid crystal monitor 102 is separated from the video camera body 101, the liquid crystal monitor 102 is driven by a built-in battery 247.

  Next, in a state where the liquid crystal monitor 102 is mechanically separated from the video camera body 101, the video image from the video camera body 101 is monitored by the liquid crystal monitor 102, and the video camera body 101 is controlled by the liquid crystal monitor 102. 13 to 15 will be described.

  In FIG. 13, first, when a power switch (not shown) on the video camera body 101 side is turned on and the liquid crystal monitor display on / off switch 132 of the liquid crystal monitor 102 is operated, a remote control signal is converted from the remote control circuit 253 to an infrared signal. The encoded light is emitted from the remote control signal light emitting element 124b. After the infrared signal is received by the remote control signal receiving element 229 shown in FIG. 14 of the video camera body 101, the infrared signal is decoded into an electric signal and controlled by the control circuit 155, and the video / audio signal recording / reproducing circuit 158 In the case of video shooting, the video signal is encoded into an infrared signal and emitted from the image transmission light emitting LED element 225. After the infrared signal is received by the image signal receiving element 125 of the liquid crystal monitor 102, the infrared signal is decoded into an electric signal, and the image signal can be monitored on the liquid crystal screen 116 via the liquid crystal drive circuit 173. A video image can be recorded by simultaneously driving the mechanical deck 156 by a signal from the video / audio signal recording / reproducing circuit 158.

  The audio signal from the video / audio signal recording / reproducing circuit 158 is encoded as an infrared signal and emitted from the audio transmission light emitting LED element 226. The infrared signal is received by the audio signal receiving element 125 b and then decoded into an electric signal so that the audio signal can be heard through the speaker 230 or the headphones 232.

  Further, when a voice is input from the microphone 234 while pressing the narration button 238 of the liquid crystal monitor 102 during video shooting, the voice is encoded into an infrared signal and emitted from the voice signal light emitting element 124a. The infrared signal is received by the audio signal receiving LED element 228, decoded into an electric signal, mixed through the audio mixing circuit 243, mixed in the video / audio signal recording / reproducing circuit 158, and recorded on the tape of the mechanical deck 156 as it is. That is, the narrated mixed audio signal can be mixed with the above-described audio signal and monitored by the headphones 232 of the liquid crystal monitor 102.

  Further, by operating the joystick 236 of the remote control unit 235 during video shooting, the signal is encoded into an infrared signal and received from the remote control signal light emitting element 124b to the remote control signal light receiving element 229, where the infrared signal is decoded and controlled. The motor drive circuit 246 is driven and controlled via the circuit 155, and the video camera mechanism 202 can be panned or tilted.

Here, one use example of the reference example 2 will be described with reference to FIG.
For example, the car 256 is stopped in the middle of driving, the video camera body 101 is placed on a flat surface such as a hood, the whole family faces the shooting lens of the video camera mechanism unit 202 with the scenery as a background, and the photographer holds the liquid crystal monitor 102. It is possible to take a video while checking the angle of view and zooming by operating the remote control unit 235.

  With such a method of use, with a conventional video camera, the photographer cannot appear on the shooting screen, and therefore the photographer does not appear when the video is played back later. Can be resolved.

  By the way, in the conventional case, as a method that the whole family can appear on the shooting screen, the video camera is supported on a tripod, the angle of view is confirmed, recording is started with the remote control, and the operator adds to the shooting screen. However, there is an advantage that these problems can be solved at once by using the video camera device.

  In the case of the reference example 2, the image transmission light emitting LED element 225, the sound transmission light emitting LED element 226, the sound signal receiving LED element 228, and the remote control signal light receiving element 229 of the video camera main body 101 are the video camera main body 101 in the reference example. The video camera body 1 can be operated from the liquid crystal monitor 102 from any direction. Depending on the performance of each element and the purpose of use of the video camera, the direction of the element may be 8 directions, 12 directions, or 3 directions or 2 directions.

  In addition, the video camera mechanism 202 is controlled by operating the initialize button 245 in a state where the pan / tilt operation is performed, that is, in a state where the video camera mechanism 202 is oriented in a predetermined angle direction with respect to the video camera body 101. The video camera mechanism 202 can be returned to the original front position with respect to the video camera body 101 by the control by the circuit 155. This allows you to use it as if you were using a regular video camera.

  In the video camera device of Reference Example 2, the video camera main body 101 does not move and only the video camera mechanism unit 202 performs pan / tilt operation. However, as another mechanism, a pan / tilt mechanism is provided below the video camera main body 1. May be arranged so that the entire video camera is panned and tilted.

  The monitor image of the liquid crystal panel 117 can be turned on / off by the liquid crystal monitor display on / off switch 132. The liquid crystal display on / off switch 132 is a push button type, and only while the button is pressed. Check what is being captured by the video camera so that it can be monitored on the monitor screen. When the button is released, the monitor is turned off and the transmission of the infrared signal is stopped. Battery consumption can be saved.

  Further, the remote control unit 235 can be removed from the connection unit 239 of the liquid crystal panel unit 117 and used alone as a small remote control, which facilitates carrying.

  The present invention is not limited to the embodiments described above and shown in the drawings, and various modifications can be made without departing from the scope of the invention.

  In the embodiment of the present invention, the remote control signal for transmission / reception between the liquid crystal monitor 1 and the TV tuner 2 or VTR 5 has been described using infrared rays. May be.

  As described above, in the imaging device of the present invention, an infrared ray or the like is used for the first receiving device such as a television or the second receiving device such as a VTR tuner using an operation device such as a remote controller and a wireless transmission / reception device. Can be selectively transmitted / received by a wireless signal using the video signal, and the video signal from the first receiver can be displayed on a display means such as a liquid crystal monitor, or the video signal from the second receiver can be displayed. Since it can be displayed on the means, when watching TV with the family, there is an effect that it is possible to view another TV broadcast program from the tuner such as the VTR using the display means.

  In the image pickup apparatus of the present invention, a wireless transmission / reception device is used using an operation device such as a remote control, and a first reception device such as a television or a second reception device such as a VTR is used by a wireless signal using infrared rays or the like. The video signal from the first receiving device can be selectively transmitted and received, and the video signal from the first receiving device can be displayed on a display means such as a liquid crystal monitor, or the video signal is recorded on the second receiving device. Can be reproduced and displayed by the display means, so that the information recorded in the VTR or the like can be monitored as a reproduced image using the display means.

  Furthermore, in the imaging apparatus of the present invention, the controller device receives a video signal from a first receiver that receives a video signal such as a television, and a VTR tuner that receives the second video signal. It is possible to selectively switch to a receiving device by a wireless signal using infrared rays or the like, and to transmit the first or second video signal from the first or second receiving device by a wireless signal using infrared rays or the like. And a wireless transmission / reception device that receives the first or second video signal as a wireless signal, and the first or second video signal received by the wireless transmission / reception device can be displayed by a display means such as a liquid crystal monitor. When the family is watching TV, it is a convenient remote controller that allows only oneself to watch another TV broadcast program using a display means from a tuner such as a VTR.

  In the imaging device of the present invention, the controller device receives a video signal from a first receiver that receives a video signal such as a television and a tuner of a VTR that receives the second video signal. The first video signal selected by the first receiver or the second video signal reproduced by the second receiver can be selectively switched to the receiver by a radio signal using infrared rays or the like. A wireless transmission / reception device that wirelessly transmits and receives the first or second video signal wirelessly, and displays the first video signal received by the wireless transmission / reception device or the reproduced second video signal on a liquid crystal monitor or the like. The information can be displayed by the means, and the information recorded on the VTR can be monitored as a reproduced image using the display means.

It is explanatory drawing of the usage example of the information system by the imaging device of this invention. It is a block circuit diagram of a liquid crystal monitor, a TV tuner, and a TV / VTR in the same information system. It is the external appearance perspective view of the liquid crystal monitor of an information system similarly. It is the external appearance perspective view which looked at the video camera device of the reference example 1 from the front. It is the external appearance perspective view which looked at the video camera device of the reference example 1 from the back. 10 is a perspective view of a liquid crystal monitor of Reference Example 1. FIG. It is a detachable block diagram of the video camera body and the liquid crystal monitor of Reference Example 1. It is sectional drawing of the infrared transmission / reception mechanism of the reference example 1. It is a perspective view of the remote control operation state of the video camera body of Reference Example 1 and the liquid crystal monitor. It is a block circuit diagram of the video camera main body and the liquid crystal monitor of Reference Example 1. 10 is an explanatory diagram of a usage example of Reference Example 1. FIG. It is an external appearance perspective view of the video camera apparatus of the reference example 2. It is a perspective view of the remote control operation state of the video camera body and the liquid crystal monitor of Reference Example 2. 10 is a perspective view of a pan / tilt mechanism of Reference Example 2. FIG. It is a block circuit diagram of the video camera main body and the liquid crystal monitor of Reference Example 2. 10 is an explanatory diagram of a usage example of Reference Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,102 ... Liquid crystal monitor (operation apparatus), 2 ... Infrared transmitter / receiver (TV tuner), 3 ... Infrared transmitter / receiver, 4 ... TV, 5 ... VTR, 6 ... Monitor main-body part, 7 ... Liquid crystal screen (display means), DESCRIPTION OF SYMBOLS 8,117 ... Liquid crystal panel part (display part), 9 ... Infrared light-receiving part, 15 ... Remote control part, 21 ... Battery, 30 ... Infrared light emitting element, 36 ... Switch, 40, 42 ... Infrared light emitting element, 44 ... Infrared light receiving element 45, 46 ... switch, 51 ... infrared light emitting unit, 101 ... video camera body (imaging device body), 105 ... zoom button (first zoom operation unit), 106 ... start / stop button (first recording operation unit) , 124... Infrared light emitting element (transmitting means), 125... Infrared light receiving element (receiving section), 131... Brightness adjustment dial (brightness adjusting section), 132. / Off switch (switching operation portion) 133 ... start / stop button (the second recording operation section), 134 ... zoom button (second zoom operation unit)

Claims (8)

An imaging unit provided in the imaging apparatus main body and imaging a subject;
An audio input unit for inputting audio;
A display unit for displaying a captured image captured by the imaging unit;
A first audio output unit that is provided in the imaging apparatus main body and outputs audio input from the audio input unit;
A recording unit for recording the captured image;
A first recording operation unit that is provided in the imaging device main body and controls recording start of the captured image in the recording unit ;
The display unit includes a second recording operation unit that controls recording start of the captured image in the recording unit, and a second audio output unit that outputs audio input from the audio input unit. An imaging apparatus characterized by that.   The imaging apparatus according to claim 1, wherein a viewfinder is provided in the imaging apparatus main body.   The imaging apparatus according to claim 1, wherein the first recording operation unit and the second recording operation unit control recording start and recording stop of the captured image in the recording unit. The imaging unit has an optical system having a zoom function,
A first zoom operation unit that is provided in the imaging apparatus body and controls a zoom state of the optical system;
The imaging apparatus according to claim 1, further comprising a second zoom operation unit that is provided in the display unit and controls a zoom state of the optical system . Wherein the display unit, the image pickup apparatus according to claim 1, characterized in that brightness adjustment unit that adjusts the brightness of the screen is provided. Wherein the display unit, the image pickup apparatus according to claim 1, characterized in that the switching operation unit for switching on / off the display portion.   The imaging apparatus according to claim 1, wherein the display unit is configured to be detachable from the imaging apparatus main body in which the imaging unit and the recording unit are stored. The imaging apparatus body is provided with a receiving unit for receiving a control signal,
The display unit includes transmission means for transmitting a control signal to the reception unit,
In a state where the display unit is separated from the imaging device main body, a recording operation unit disposed in the vicinity of the display unit is operated, whereby the display unit starts recording or recording with respect to the imaging device main body. 8. The imaging apparatus according to claim 7, wherein a control signal for controlling stop is transmitted.

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