JP3673774B2 - OPTICAL DEVICE, OPTICAL DEVICE DRIVE UNIT, AND CAMERA SYSTEM - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical device and an optical device driving unit used in a television camera, a video camera system, and the like, for example, a zoom lens device and a driving unit used in an ENG camera system and the like.
[0002]
[Prior art]
Zoom speed control using a zoom control switch, zoom demand, or the like in a conventional optical device such as a television lens or a video lens is proposed in, for example, Japanese Patent Laid-Open No. 51-40924.
[0003]
This zoom drive control is performed by servo means comprising a drive system such as a motor and a control system for controlling the operation of this drive system. In order to give a command signal to the control system in this servo means A zoom control switch or zoom demand is used. In an actual zoom operation, the zoom speed can be adjusted to a zoom speed desired by the photographer from a low speed to a high speed in accordance with an operation amount of a thumb ring provided on a zoom control switch or zoom demand.
[0004]
By the way, various shooting methods are used for shooting using a TV camera, a video camera, and the like. One of them is a shooting method in which shooting is performed while performing zoom driving at a constant low speed. And this imaging method may be used repeatedly during imaging.
[0005]
Conventionally, such zoom driving is realized by the photographer maintaining a constant amount of operation of a thumb ring provided on a zoom control switch or zoom demand.
[0006]
[Problems to be solved by the invention]
However, it is not easy for the photographer to keep the operation amount of the zoom control switch or the like constant during zoom driving. In particular, as the zoom drive speed is lowered, the time for keeping the operation amount of the zoom control switch or the like becomes longer, and it becomes very difficult to keep the operation amount constant. Furthermore, it is difficult to reproduce the same zoom drive speed over and over again.
[0007]
[Means for Solving the Problems]
In order to solve the above-described problems, in the present invention, preset drive control is started in an optical device or an optical device drive unit that performs preset drive control using preset information stored in advance for a lens or other optical adjustment means. When the optical adjustment means is driven and the storage instruction operation means is operated in advance, the actual drive speed and the actual drive direction of the optical adjustment means at the time of operation of the storage instruction operation means are preset speed information and preset. When the storage means for storing the direction information and the drive command operation means operated to generate the drive speed command and the drive direction command of the optical adjustment means according to the operation amount and the operation direction are not operated, the storage instruction The optical adjustment means is stored in the storage means in response to the operation of the control start operation means different from the operation means. At a speed corresponding to the preset speed information, it is provided with an arithmetic processing circuit for performing speed and direction preset drive control for driving in a direction corresponding to the preset direction information stored in the storage means.
[0008]
In the present invention, in the optical device or the optical device drive unit that performs preset drive control using preset information stored in advance with respect to the lens or other optical adjustment means, before the preset drive control is started, the operation amount and When the drive command operation means operated to generate the drive speed command and the drive direction command of the optical adjusting means according to the operation direction is operated and the storage instruction operation means is operated, the storage instruction operation means Control different from the storage instruction operation means when the drive instruction operation means is not operated, and storage means for storing the drive speed command and drive direction command of the optical adjustment means at the time of operation as preset speed information and preset direction information In response to the start operation means being operated, the optical adjustment means is set to the preset speed stored in the storage means. At a speed corresponding to the information, it is provided an arithmetic processing circuit for performing speed and direction preset drive control for driving in a direction corresponding to the preset direction information stored in the storage means.
[0009]
As described above, before starting the speed / direction preset drive control, the photographer or the like stores in advance an arbitrary actual drive speed and actual drive direction of the optical adjustment means, or a drive speed command and a drive direction command. By enabling speed / direction preset drive control to drive in the memorized direction at the memorized speed, it is possible to drive the optical adjusting means at a constant speed in the memorized direction by a very simple operation. It becomes. In addition, the constant speed driving at the same speed in the same direction can be accurately reproduced any number of times.
[0010]
In particular, when performing speed / direction preset drive control of the optical adjustment means at low speed, it may be difficult for the photographer to determine whether speed / direction preset drive control is being performed. It is preferable to provide a display means that can visually determine that the preset drive control is being performed.
[0011]
Further, in the above invention, provided is a speed selection operation means operated to select whether the driving speed of the optical adjustment means is a driving speed corresponding to the preset speed information or a maximum driving speed that can be driven, The optical adjusting means may be driven at a driving speed selected by operating the speed selecting operation means.
[0012]
As a result, the range of imaging methods using speed / direction preset drive control can be expanded, and a more meaningful preset drive control function can be realized.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 shows the configuration of a lens apparatus (optical apparatus) according to the first embodiment of the present invention.
[0014]
In this figure, 1 is a zoom control switch (drive command operation means) operated by a photographer, and 2 is a zoom lens for electrically driving a zoom lens optical system (optical adjustment means) 9 that performs zooming adjustment of the lens device. This is a command signal generation circuit that generates a command signal that indicates a driving direction and a driving speed (which may be a driving amount or a driving position) proportional to the operation amount of the control switch 1.
[0015]
3 is a zoom speed variable volume that varies the driving speed of the zoom lens optical system 9 with respect to the operation amount of the zoom control switch 1, and 4 is a command signal that performs signal level and shift conversion in order to capture the command signal into the A / D conversion circuit 5. It is an arithmetic circuit. The A / D conversion circuit 5 converts the analog signal output from the command signal calculation circuit 4 into a digital signal.
[0016]
Reference numeral 6 denotes a CPU that controls the operation of the lens apparatus. The CPU 6 includes a memory (storage means) 6a capable of storing a preset speed (preset speed information) and a preset direction (preset direction information). . The CPU 6 also controls “speed preset zoom control” (speed / direction preset drive control) for driving in the preset direction stored at the preset speed stored in the memory 6a.
[0017]
Reference numeral 8 denotes a memory switch (storage instruction operation means) that is shared to give the CPU 6 a storage instruction of a preset speed and a preset position used for “speed preset zoom control”.
[0018]
Reference numeral 7 denotes a memory execution function for storing the preset speed and the preset direction in the memory 6a by being turned on when the zoom lens optical system 9 is driven, and the preset speed and preset speed, as will be described later. This is a speed preset zoom switch (control start operation means) having a function of instructing start (and stop) of this control operation by being turned on after storage.
[0019]
A D / A conversion circuit 10 converts a command signal output from the CPU 6 to drive the zoom lens optical system 9 from a digital signal to an analog signal, and 11 indicates a signal level of the command signal output from the D / A conversion circuit 10. A CPU command signal calculation circuit 12 for performing shift conversion is a command signal switch for switching whether the zoom lens optical system 9 is driven from the zoom control switch 1 or the CPU 6.
[0020]
13 is a power amplifying circuit for operating a motor 14 that drives the zoom lens optical system 9, 15 is a speed detector that outputs a speed signal corresponding to the driving speed of the zoom lens optical system 9, and 16 is an A / A speed signal. This is a speed signal calculation circuit that performs signal level and shift conversion for incorporation into the D conversion circuit 17. The A / D conversion circuit 17 converts the analog signal output from the speed signal calculation circuit 16 into a digital signal.
[0021]
Reference numeral 18 denotes a position signal detector (position detecting means) for outputting a position signal corresponding to the position of the zoom lens optical system 9, and 19 denotes a position for performing signal level and shift conversion in order to take the position signal into the A / D conversion circuit 20. It is a signal arithmetic circuit. The A / D conversion circuit 20 converts the analog signal output from the set signal calculation circuit 19 into a digital signal.
[0022]
Reference numeral 21 denotes a preset operation indicator that performs display for visually determining whether or not “speed preset zoom control” is being performed.
[0023]
The speed preset zoom switch 7 and the memory switch 8 may be provided integrally with a lens apparatus body having a zoom lens optical system 9 or a focus lens optical system (not shown), or connected to the lens apparatus body via a cable or the like. You may provide in the zoom demand (external control unit) which is connected and has a thumb ring etc. instead of the zoom control switch 1.
[0024]
Of the above configuration, the components other than the zoom lens optical system 9, that is, each circuit such as the zoom control switch 1 and the CPU 6, the motor 14, the speed detector 15, the position detector 18, the speed preset zoom switch 7 and the memory switch 8. May be provided in a lens drive unit (optical device drive unit) used by being attached to or connected to a handy type lens device body.
[0025]
In the lens device or the lens driving unit having such a configuration, the zoom lens optical system 9 needs to be motor-driven in advance in order to store the preset speed and the preset speed.
[0026]
Here, drive control of the zoom lens optical system 9 from the zoom control switch 1 will be described first. When the zoom control switch 1 is operated, a command signal instructing a driving direction and a driving speed (which may be a driving amount or a driving position) proportional to the operation amount is output from the command signal generating circuit 2. This command signal is input to the power amplification circuit 13 via the zoom speed variable volume 3 that varies the drive speed of the zoom lens optical system 9 with respect to the operation amount of the zoom control switch 1 and the A side of the command signal changeover switch 12. The signal is amplified to a predetermined level by the amplifier circuit 13 and then input to the motor 14. As a result, the motor 14 operates and the zoom lens optical system 9 is driven.
[0027]
The actual driving speed and actual driving direction of the zoom lens optical system 9 necessary for storing the preset speed and the preset direction are the output from the speed detector 13, the speed signal calculation circuit 16 and the A / D conversion circuit 17. It can be detected by being input to the CPU 6 via.
[0028]
Further, as will be described later, a command signal proportional to the amount of operation of the zoom control switch 1 is determined by determining whether or not the zoom control switch 1 necessary for storing the preset speed and the preset direction has been operated. 2 and is input to the CPU 6 via the zoom speed variable volume 3, the command signal calculation circuit 4, and the A / D conversion circuit 5.
[0029]
The actual drive position of the zoom lens optical system 9 can be detected by inputting the output from the position detector 18 to the CPU 6 via the position signal calculation circuit 19 and the A / D conversion circuit 20.
[0030]
Next, description will be given of a preset speed and preset direction storage setting procedure necessary for executing the “speed preset zoom control”.
[0031]
In this memory setting procedure, the zoom lens when the photographer operates the zoom control switch 1 and drives the zoom lens optical system 9 in the direction to be preset at a speed to be preset in advance, and the memory switch 8 is turned on from off. The CPU 6 stores the driving speed and direction of the optical system 9 (the actual driving speed and the actual driving direction of the zoom lens optical system 9 detected through the speed detector 15) as a preset speed and a preset direction, respectively.
[0032]
The processing of the CPU 6 at this time will be described with reference to FIG. First, a predetermined zoom drive speed such as the maximum speed is stored as a preset speed in a preset speed memory area configured in the memory 6a as an initial setting (step 101). The preset speed at the time of initial setting may be a zoom drive speed desired by the photographer or a zoom drive speed set during the previous power-on of the lens apparatus.
[0033]
In addition, a predetermined zoom drive direction such as a telephoto side or a wide-angle side is stored as a preset direction in a preset direction memory area configured in the memory 6a as an initial setting (step 102). The preset direction at the time of initial setting may be the zoom drive direction desired by the photographer or the zoom drive direction set during the previous power-on of the lens apparatus.
[0034]
Next, the drive speed and drive direction of the zoom lens optical system 9 are acquired from the A / D conversion circuit 17 (step 103). Thereafter, the data of the A / D conversion circuit 5 is obtained, and it is determined whether or not the zoom control switch 1 is operated (step 104). The zoom speed and zoom direction are acquired from the D conversion circuit 17 (step 103).
[0035]
If the zoom control switch 1 has been operated, it is determined whether or not the memory switch 84 has changed from OFF to ON (step 105), and if the memory switch 8 has not changed from OFF to ON. Returns to step 103.
[0036]
If the memory switch 8 has changed from OFF to ON, the drive speed acquired in step 103 is stored in the preset speed memory area as a new preset speed (step 106). Further, the drive direction acquired in step 103 is stored in the preset direction memory area as a new preset direction (step 107).
[0037]
Next, the operation of “speed preset zoom control” (hereinafter simply referred to as “preset operation”) will be described. The control of the zoom lens optical system 9 during the preset operation is performed when the command signal output from the CPU 6 includes a D / A conversion circuit 10, a CPU command signal calculation circuit 11, a B side of the command signal changeover switch 12, and a power amplification circuit 13. Is input to the motor 14 via the zoom lens optical system 9 at a preset speed at a preset speed in a preset direction in the movable range end of the zoom lens optical system 9 (speed preset zoom control in the middle). When is stopped, it is done by driving to that position).
[0038]
The processing of the CPU 6 at this time will be described with reference to FIGS. First, it is determined whether or not the zoom control switch 1 is operated (step 201). If the zoom control switch 1 is operated, the zoom lens optical system 9 is controlled from the zoom control switch 1, The command signal selector switch 12 is switched to the A side (step 202).
[0039]
Next, it is determined whether or not the preset operation is performed (step 203). If the preset operation is not performed, it is determined whether or not the zoom control switch 1 is operated again (step 201). Return.
[0040]
If the preset operation is being performed in step 203, the preset operation indicator 21 is turned off (step 204), and then the preset operation is terminated (stopped) (step 205). Then, the process returns to the determination (step 201) of whether or not the zoom control switch 1 has been operated.
[0041]
On the other hand, if the zoom control switch 1 is not operated in step 201, it is determined whether or not the preset operation is performed (step 206). If the preset operation is not performed, the process proceeds to step 219. move on.
[0042]
If the preset operation is performed in step 206, the speed and direction of the zoom lens optical system 9 are acquired from the A / D conversion circuit 17 (step 207), and the zoom lens optical is further transmitted from the A / D conversion circuit 20. The position of the system 9 is acquired (step 408).
[0043]
Next, it is determined whether or not the zoom position acquired in step 208 has reached the movable range end position in this lens apparatus (step 209). If the zoom position has reached the movable range end, the command signal is switched. The switch 12 is switched to the A side (step 210), the preset operation indicator 21 is turned off (step 211), and the preset operation is terminated (step 212).
[0044]
If the zoom position does not reach the movable range end in step 209, whether or not the zoom speed acquired in step 207 is equal to the preset speed stored in the memory 6a in advance by the flow shown in FIG. (For example, whether or not the zoom speed is within a predetermined allowable range with respect to the preset speed) (step 213).
[0045]
If the zoom speed and the preset speed are not equal, it is determined whether or not the preset speed is faster than the zoom speed (step 214). If the preset speed is faster than the zoom speed, D / The command signal output to the A conversion circuit 10 is increased (step 216). If the preset speed is slower than the zoom speed, the command signal output to the D / A conversion circuit 10 is decreased (step 215).
[0046]
Thereafter, it is determined whether or not the zoom direction acquired in step 207 is equal to the preset direction stored in advance (step 217). If the zoom direction and the preset direction are not equal, the current zoom direction is determined. The zoom lens optical system 9 is driven in the opposite direction (step 218).
[0047]
After the above processes are completed, it is determined whether or not the speed preset zoom switch 7 (referred to as “preset zoom switch 7” in FIGS. 3 and 4) has changed from off to on (step 219). If the zoom switch 7 has not changed from OFF to ON, the process returns to the determination (step 201) as to whether or not the zoom control switch 1 has been operated.
[0048]
On the other hand, if the speed preset zoom switch 7 is changed from OFF to ON, it is determined whether or not the preset operation is performed (step 220). If the preset operation is not performed, the command signal The changeover switch 12 is switched to the B side (step 221), and the preset operation indicator 21 is turned on (step 223). Further, the preset operation in the preset direction at the preset speed stored in the memory 6a is started by the flow shown in FIG. 2 (step 223).
[0049]
Thereafter, when the zoom lens optical system 9 reaches the end of the movable range (step 209), the command signal changeover switch 12 is switched to the A side (step 210), and the preset operation indicator 21 is turned off (step 211). The operation is terminated (step 212).
[0050]
On the other hand, if the preset operation is being performed in step 220, the command signal changeover switch 12 is switched to the A side (step 224), the preset operation indicator 21 is turned off (step 225), and then the preset operation is terminated. (Stop) (Step 226).
[0051]
As described above, according to the present embodiment, the zoom lens optical system is selected in the direction stored in the memory 6a at a speed that is previously selected by the photographer or the like by operating the memory switch 8 and stored in the memory 6a. By enabling the preset operation for driving the system 9, the zoom lens optical system 9 can be driven at a constant speed by an extremely simple operation. In addition, by simply turning on the speed preset zoom switch 7, the constant speed drive at the same speed of the zoom lens optical system 9 can be accurately reproduced any number of times.
[0052]
Further, according to the present embodiment, since the preset operation indicator 21 is turned on when performing the preset operation, for example, even when the preset operation is performed at a low speed, the photographer can perform the preset operation. Can be clearly recognized.
[0053]
(Second Embodiment)
In the first embodiment, only “speed preset zoom control”, that is, a case where the preset operation is performed in a preset direction at a preset speed at a preset speed has been described. However, the zoom lens optical system 9 is driven during the preset operation. By adding a function to change the speed at the preset speed or at the highest speed that the lens device or drive unit can drive, the range of shooting techniques for TV and video shooting is further expanded. A more meaningful preset function can be realized.
[0054]
FIG. 5 shows the configuration of the lens apparatus of the present embodiment. In the present embodiment, components common to the first embodiment are denoted by the same reference numerals as in the first embodiment.
[0055]
In this embodiment, a preset mode changeover switch (speed selection operation means) 22 is added to the configuration of the first embodiment to determine whether the zoom lens optical system 9 during the preset operation is driven at the preset speed or at the highest speed. doing.
[0056]
The speed preset zoom switch 7, the memory switch 8, and the preset mode changeover switch 22 may be provided integrally with a lens apparatus body having the zoom lens optical system 9 or a focus lens optical system (not shown), or the lens apparatus body. The zoom demand (external control unit) may be provided with a thumb ring or the like connected to the zoom control switch 1 instead of the zoom control switch 1.
[0057]
Of the above configuration, the components other than the zoom lens optical system 9, that is, each circuit such as the zoom control switch 1 and the CPU 6, the motor 14, the speed detector 15, the position detector 18, the speed preset zoom switch 7, and the memory switch 8. The preset mode changeover switch 22 may be provided in a lens driving unit (optical device driving unit) used by being attached to or connected to a handy type lens device body.
[0058]
In the lens device or the lens driving unit having such a configuration, the zoom lens optical system 9 needs to be motor-driven in advance in order to store the preset speed and the preset direction. This is the same as in the first embodiment.
[0059]
Also, a drive control method of the zoom lens optical system 9 from the zoom control switch 1, a method of detecting the drive speed and drive speed of the zoom lens optical system 9 necessary for storing the preset speed and the preset direction, and the preset speed and The method for determining whether or not the zoom control switch 1 necessary for storing the preset direction is operated is the same as in the first embodiment.
[0060]
Next, the preset operation in this embodiment will be described. In the control of the zoom lens optical system 9 during the preset operation of the present embodiment, the command signal output from the CPU 6 includes the D / A conversion circuit 10, the CPU command signal calculation circuit 11, the B side of the command signal changeover switch 12, and the power. Although it is the same as in the first embodiment in that it is performed by being input to the motor 14 via the amplifier circuit 13, the preset zoom mode optical switch 9 is preset by the CPU 6 according to the state of the preset mode switch 22. The second embodiment is different from the first embodiment in that a preset mode in which a command signal for driving at a speed is output and a maximum speed mode in which a command signal for driving at the highest speed is output are selectively set. Regardless of which mode is set, the zoom lens optical system 9 is driven in the preset direction to the end of the movable range of the zoom lens optical system 9 (the position when the speed preset zoom control is stopped halfway). is there.
[0061]
Processing of the CPU 6 at this time will be described with reference to FIGS. First, it is determined whether or not the zoom control switch 1 is operated (step 401). When the zoom control switch 1 is operated, the zoom lens optical system 9 is controlled from the zoom control switch 1, The command signal selector switch 12 is switched to the A side (step 402).
[0062]
Next, it is determined whether or not the preset operation is performed (step 403). If the preset operation is not performed, it is determined whether or not the zoom control switch 1 is operated again (step 401). Return.
[0063]
If the preset operation is being performed in step 403, the preset operation indicator 21 is turned off (step 404), and then the preset operation is terminated (stopped) (step 405). Then, the process returns to the determination (step 401) of whether or not the zoom control switch 1 is operated.
[0064]
On the other hand, if the zoom control switch 1 is not operated in step 401, it is determined whether or not the preset operation is performed (step 406). If the preset operation is not performed, the process proceeds to step 420. move on.
[0065]
When the preset operation is performed in step 406, the speed and direction of the zoom lens optical system 9 are acquired from the A / D conversion circuit 17 (step 407), and the zoom lens optical is further transmitted from the A / D conversion circuit 20. The position of the system 9 is acquired (step 408).
[0066]
Next, it is determined whether or not the zoom position acquired in step 408 has reached the movable range end position in the lens apparatus (step 409). If the zoom position has reached the movable range end, the command signal is switched. The switch 12 is switched to the A side (step 410), the preset operation indicator 21 is turned off (step 411), and the preset operation is terminated (step 412).
[0067]
If the zoom position has not reached the end of the movable range in step 409, it is determined whether or not the preset mode is selected by the preset mode changeover switch 22 (step 413).
[0068]
Here, when the preset mode is selected, the zoom speed acquired in step 407 and the preset speed stored in the memory 6a in advance by the flow shown in FIG. 2 described in the first embodiment. (For example, whether or not the zoom speed is within a predetermined allowable range with respect to the preset speed) is determined (step 414).
[0069]
If the zoom speed and the preset speed are not equal, it is determined whether the preset speed is faster than the zoom speed (step 415). If the preset speed is faster than the zoom speed, D / The command signal output to the A conversion circuit 10 is increased (step 417). If the preset speed is slower than the zoom speed, the command signal output to the D / A conversion circuit 10 is decreased (step 416).
[0070]
Thereafter, it is determined whether or not the zoom direction acquired in step 407 is equal to the preset direction stored in advance (step 418). If the zoom direction and the preset direction are not equal, the current zoom direction is determined. The zoom lens optical system 9 is driven in the opposite direction (step 419).
[0071]
If the preset mode is not selected and the zoom speed is equal to the preset speed, the process proceeds to step 418 as it is.
[0072]
After the above processes are completed, it is determined whether or not the speed preset zoom switch 7 (referred to as the preset zoom switch 7 in FIGS. 6 and 7) has changed from OFF to ON (step 420). If the zoom switch 7 has not changed from OFF to ON, the process returns to the determination (step 401) as to whether or not the zoom control switch 1 has been operated.
[0073]
On the other hand, if the speed preset zoom switch 7 is changed from OFF to ON, it is determined whether or not the preset operation is performed (step 421). If the preset operation is not performed, the command signal The changeover switch 12 is switched to the B side (step 425), and the preset operation indicator 21 is turned on (step 426). Then, it is determined whether or not the preset mode is selected by the preset mode changeover switch 22 (step 427). If the preset mode is not selected, the preset operation is started at the highest drive speed (step 428). If the preset mode is selected, the preset operation is started at the preset speed (step 429).
[0074]
Thereafter, when the zoom lens optical system 9 reaches the end of the movable range (step 409), the command signal changeover switch 12 is switched to the A side (step 410), the preset operation indicator 21 is turned off (step 411), and the preset is performed. The operation is terminated (step 412).
[0075]
On the other hand, if the preset operation is being performed in step 421, the command signal changeover switch 12 is switched to the A side (step 422), the preset operation indicator 21 is turned off (step 423), and then the preset operation is terminated. (Cancel) (step 424).
[0076]
As described above, according to the present embodiment, in addition to the operational effects obtained by the first embodiment, whether the preset operation is performed at the preset speed or the maximum speed at which the lens apparatus can be driven is taken. Can be arbitrarily selected, so that the range of photographing techniques when photographing using a television camera or a video camera can be further expanded, and a more meaningful preset function can be realized.
[0077]
In the first and second embodiments, the case where the preset speed used for the preset operation is obtained from the actual driving speed of the zoom lens optical system 9 has been described. However, the preset speed is used for the operation of the zoom control switch 1. It may be obtained from a proportional speed command signal.
[0078]
In the first and second embodiments, the case where the driving speed and the driving direction of the zoom lens optical system 9 are detected using the speed signal output from the speed detector 15 has been described. The driving speed and the driving direction may be detected by acquiring output position signals at regular intervals.
[0079]
(Third embodiment)
In the first embodiment described above, the “speed preset zoom control”, that is, the preset speed and preset speed used for the preset operation are obtained from the actual driving speed and the actual driving direction of the zoom lens optical system 9 and the zoom lens optical system 9 Although the case where the acceleration / deceleration control of the zoom lens optical system 9 is performed so that the actual driving speed becomes equal to the preset speed has been described, the preset speed (command) and the preset direction (command) are proportional to the operation of the zoom control switch 1. By obtaining the speed command signal and the command signal corresponding to the operation direction of the zoom control switch 1 and not performing the acceleration / deceleration control as described above, simple control with a simple circuit configuration may be performed. Thereby, the speed detector 15, the speed signal calculation circuit 16, and the A / D conversion circuit 17 which are required in the first embodiment are not necessary.
[0080]
FIG. 8 shows the configuration of the lens apparatus of this embodiment. In the present embodiment, components common to the first embodiment are denoted by the same reference numerals as in the first embodiment.
[0081]
The present embodiment has a configuration in which the speed detector 15, the speed signal calculation circuit 16, and the A / D conversion circuit 17 are removed from the configuration of the first embodiment.
[0082]
The speed preset zoom switch 7 and the memory switch 8 may be provided integrally with a lens apparatus body having a zoom lens optical system 9 or a focus lens optical system (not shown), or connected to the lens apparatus body via a cable or the like. You may provide in the zoom demand (external control unit) which is connected and has a thumb ring etc. instead of the zoom control switch 1.
[0083]
In the above configuration, the components other than the zoom lens optical system 9, that is, each circuit such as the zoom control switch 1 and the CPU 6, the motor 14, the position detector 18, the speed preset zoom switch 7 and the memory switch 8 are handy type. You may provide in the lens drive unit (optical apparatus drive unit) with which it is mounted | worn with or connected to the lens apparatus main body.
[0084]
In the lens apparatus or lens driving unit having such a configuration, it is necessary to operate the zoom control switch 1 in advance in order to store the preset speed and the preset direction. It is necessary to drive the zoom lens optical system 9 in advance by a motor. This is the same as in the first embodiment.
[0085]
The drive control method of the zoom lens optical system 9 from the zoom control switch 1 is the same as that in the first embodiment.
[0086]
Further, the speed command signal output from the command signal generation circuit 2 in proportion to the operation amount of the zoom control switch 1 necessary for storing the preset speed is detected by the speed command signal being the zoom speed variable volume 3 and the command. This is possible by inputting to the CPU 6 via the signal arithmetic circuit 4 and the A / D conversion circuit 5. In the present embodiment, the speed command signal includes a direction command signal corresponding to the operation direction of the zoom control switch 1. Similarly, it is possible to determine whether or not the zoom control switch 1 is operated.
[0087]
Here, a preset setting speed (and preset direction) storage setting procedure (processing of the CPU 6) in the present embodiment will be described with reference to FIG.
[0088]
First, a predetermined zoom driving speed such as the maximum tele-direction speed is stored as a preset speed command including a direction command in a preset speed command memory area configured in the memory 6a as an initial setting (step 501).
[0089]
Next, a speed command signal is acquired from the A / D conversion circuit 5 (step 502), and then it is determined whether or not the zoom control switch 1 is operated (step 503). If the zoom control switch 1 is not operated, a speed command signal is acquired again from the A / D conversion circuit 5 (step 502).
[0090]
If the zoom control switch 1 has been operated, it is determined whether or not the state of the memory switch 8 has changed from off to on (step 504), and the state of the memory switch 8 has not changed from off to on. If so, the process returns to step 502 again.
[0091]
When the state of the memory switch 8 is changed from OFF to ON, the speed command signal including the direction command acquired in Step 502 is stored in the preset speed command memory area as a new preset speed command (Step 505). ).
[0092]
Next, the preset operation in this embodiment will be described. In the control of the zoom lens optical system 9 during the preset operation of the present embodiment, the command signal output from the CPU 6 includes the D / A conversion circuit 10, the CPU command signal calculation circuit 11, the B side of the command signal changeover switch 12, and the power. The zoom lens optical system 9 is input to the motor 14 via the amplifier circuit 13 and driven at a speed and direction corresponding to the preset speed command.
[0093]
The processing of the CPU 6 during this preset operation will be described with reference to FIGS. First, it is determined whether or not the zoom control switch 1 is operated (step 601). If the zoom control switch 1 is operated, the zoom lens optical system 9 is controlled from the zoom control switch 1, The command signal selector switch 12 is switched to the A side (step 602). Then, it is determined whether or not the preset operation is being performed (step 603). If the preset operation is not being performed, the process returns to the determination whether or not the zoom control switch 1 is being operated again (step 601). .
[0094]
On the other hand, if the preset operation is being performed in step 603, the preset operation indicator 21 is turned off (step 604), and then the preset operation is terminated (stopped) (step 605). Then, the process returns to the determination (step 601) of whether or not the zoom control switch 1 is being operated.
[0095]
If the zoom control switch 1 is not operated in step 601, it is determined whether or not a preset operation is performed (step 606). If the preset operation is not performed, the process proceeds to step 612.
[0096]
If the preset operation is performed in step 606, the zoom position is acquired from the A / D conversion circuit 20 (step 607).
[0097]
Next, it is determined whether or not the zoom position acquired in step 607 has reached the movable range end position in this lens apparatus (step 608). If the zoom position has reached the movable range end, the command signal is switched. The switch 12 is switched to the A side (step 609), the preset operation indicator 21 is turned off (step 610), and the preset operation is terminated (step 611).
[0098]
If it is determined in step 609 that the zoom position has not reached the movable range end, the process proceeds directly to step 612.
[0099]
After the above processes are completed, it is determined whether or not the speed preset zoom switch 7 has changed from OFF to ON (step 612). If the speed preset zoom switch 7 has not changed from OFF to ON, The process returns to the determination (step 601) of whether or not the zoom control switch 1 has been operated.
[0100]
When the speed preset zoom switch 7 is changed from OFF to ON, it is determined whether or not the preset operation is performed (step 613). When the preset operation is not performed, the command signal changeover switch is determined. 12 is switched to the B side (step 614), and the preset operation indicator 21 is turned on (step 615). Thereafter, a preset speed command stored and set in advance according to the flow shown in FIG. 9 is output to the D / A conversion circuit 10, and a preset operation is started at a speed and direction corresponding to the preset speed command (step 616). .
[0101]
Thereafter, when the zoom lens optical system 9 reaches the end of the movable range (step 608), the command signal changeover switch 12 is switched to the A side (step 609), the preset operation indicator 21 is turned off (step 610), and the preset is performed. The operation is terminated (step 611).
[0102]
If the preset operation is being performed in step 613, the command signal changeover switch 12 is switched to the A side (step 617), the preset operation indicator 21 is turned off (step 618), and then the preset operation is terminated (stopped). (Step 619).
[0103]
As described above, according to the present embodiment, the zoom lens optical system is selected in the direction stored in the memory 6a at a speed that is previously selected by the photographer or the like by operating the memory switch 8 and stored in the memory 6a. By enabling the preset operation for driving the system 9, the zoom lens optical system 9 can be driven at a constant speed by an extremely simple operation. In addition, by simply turning on the speed preset zoom switch 7, the constant speed drive at the same speed of the zoom lens optical system 9 can be accurately reproduced any number of times.
[0104]
Further, according to the present embodiment, since the preset operation indicator 21 is turned on when performing the preset operation, for example, even when the preset operation is performed at a low speed, the photographer can perform the preset operation. Can be clearly recognized.
[0105]
In each of the above embodiments, the case where both the preset speed and the preset direction are obtained from the actual driving state of the zoom lens optical system 9 or the driving command generated in accordance with the operation of the zoom control switch 1 has been described. One of the preset speed and the preset direction may be obtained from the actual drive state, and the other may be obtained from the drive command.
[0106]
In each of the above embodiments, the case where the preset speed is stored after determining that the zoom control switch 1 is operated has been described. The preset speed may be stored after determining that the system 9 is driven.
[0107]
In the above embodiment, the case where the memory switch 8 is constituted by a single switch has been described. However, in order to prevent erroneous operation, a memory switch including two sets as one set is provided so that both memory switches are operated. The preset information may be stored in response to this.
[0108]
In each of the above embodiments, the case where preset drive control related to the zoom lens optical system is performed has been described. However, the present invention performs preset drive control related to optical adjustment means other than the zoom lens optical system, such as a focus lens optical system and an iris. It can also be applied in the case of performing.
[0109]
【The invention's effect】
As described above, according to the present invention, before the speed / direction preset drive control is started, the photographer or the like can perform any actual drive speed and actual drive direction, or drive speed command and drive direction of the optical adjustment unit in advance. Since commands are stored and speed / direction preset drive control to drive in the stored direction at this stored speed is possible, the stored direction of the optical adjustment means can be performed by a very simple operation. Can be driven at a constant speed. Moreover, constant speed driving at the same speed in the same direction can be accurately reproduced any number of times.
[0110]
In addition, if a display means that can visually determine that the speed / direction preset drive control is being performed is provided, the speed / direction preset drive control of the optical adjustment means at a low speed is provided to the photographer. -It is possible to clearly recognize whether or not direction preset drive control is being performed.
[0111]
Further, in the above invention, provided is a speed selection operation means operated to select whether the driving speed of the optical adjustment means is a driving speed corresponding to the preset speed information or a maximum driving speed that can be driven, Since the optical adjustment means is driven at the drive speed selected by the operation of the speed selection operation means, the range of the photographing technique using the speed / direction preset drive control can be expanded, and a more meaningful preset. A drive control function can be realized.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a lens apparatus according to a first embodiment of the present invention.
FIG. 2 is a flowchart for storing preset speed and preset direction used for speed preset zoom control in the lens apparatus.
FIG. 3 is a processing flowchart of speed preset zoom control in the lens apparatus.
FIG. 4 is a process flowchart of speed preset zoom control in the lens apparatus.
FIG. 5 is a configuration diagram of a lens apparatus according to a second embodiment of the present invention.
FIG. 6 is a processing flowchart of speed preset zoom control in the lens apparatus of the second embodiment.
FIG. 7 is a processing flowchart of speed preset zoom control in the lens apparatus of the second embodiment.
FIG. 8 is a configuration diagram of a lens apparatus according to a third embodiment of the present invention.
FIG. 9 is a flowchart for storing preset speed (direction) used for speed preset zoom control in the lens apparatus of the third embodiment.
FIG. 10 is a processing flowchart of speed preset zoom control in the lens apparatus of the third embodiment.
FIG. 11 is a processing flowchart of speed preset zoom control in the lens apparatus of the third embodiment.
[Explanation of symbols]
1 ... Zoom control switch
2 ... Command signal generation circuit
3 ... Zoom speed variable volume
4 ... Command signal calculation circuit
5, 17, 20 ... A / D conversion circuit
6 ... CPU
6a ... Memory
7. Speed preset zoom switch
8 ... Memory switch
9. Zoom lens optical system
10. D / A conversion circuit
11 ... CPU command signal calculation circuit
12 ... Command signal switch
13 ... Power amplifier circuit
14 ... Motor
15. Speed detector
16 ... Speed signal calculation circuit
18 ... Position detector
19: Position signal calculation circuit
21 ... Preset operation indicator
22 ... Preset mode switch

Claims (14)

In an optical device that performs preset drive control using preset information stored in advance for a lens or other optical adjustment means,
Before starting the preset drive control, when the optical adjustment unit is driven and the storage instruction operation unit is operated in advance, the actual drive speed of the optical adjustment unit at the time of operation of the storage instruction operation unit and Storage means for storing the actual driving direction as preset speed information and preset direction information;
Control start different from the storage instruction operation means when the drive command operation means operated to generate the drive speed command and drive direction command of the optical adjustment means according to the operation amount and the operation direction is not operated In response to operation of the operation means, the optical adjustment means is driven in a direction corresponding to the preset direction information stored in the storage means at a speed corresponding to the preset speed information stored in the storage means. An optical apparatus comprising: an arithmetic processing circuit that performs speed / direction preset drive control. In an optical device that performs preset drive control using preset information stored in advance for a lens or other optical adjustment means,
Prior to starting the preset drive control, a drive command operating means operated to generate a drive speed command and a drive direction command of the optical adjusting means according to an operation amount and an operation direction is operated in advance and a storage instruction is issued Storage means for storing the drive speed command and the drive direction command of the optical adjusting means at the time of operation of the storage instruction operation means as preset speed information and preset direction information when the operation means is operated;
Preset speed information stored in the storage means is stored in the storage means in response to operation of a control start operation means different from the storage instruction operation means when the drive command operation means is not operated. And an arithmetic processing circuit for performing speed / direction preset driving control for driving in a direction corresponding to preset direction information stored in the storage means at a speed corresponding to. The arithmetic processing circuit compares the actual driving speed of the optical adjustment means with the driving speed corresponding to the preset speed information when performing the speed / direction preset driving control, and substantially matches the both driving speeds. The optical apparatus according to claim 1, wherein the control of the actual driving speed of the optical adjusting means is performed as described above. 4. The optical apparatus according to claim 1, further comprising display means for displaying that the speed / direction preset drive control is being performed. A speed selection operation means operated to select whether the driving speed of the optical adjusting means is a driving speed corresponding to preset speed information or a maximum driving speed that can be driven;
5. The optical apparatus according to claim 1, wherein the arithmetic processing circuit drives the optical adjustment unit at a driving speed selected by an operation of the speed selection operation unit. The arithmetic processing circuit, when performing the speed / direction preset drive control, stops the speed / direction preset drive control in response to the operation of the control start operation means. Item 6. The optical device according to Item 5. In an optical device drive unit mounted or connected to an optical device body having a lens or other optical adjustment means, and performing preset drive control using preset information stored in advance for the optical adjustment means,
Before starting the preset drive control, when the optical adjustment unit is driven and the storage instruction operation unit is operated in advance, the actual drive speed of the optical adjustment unit at the time of operation of the storage instruction operation unit and Storage means for storing the actual driving direction as preset speed information and preset direction information;
Control start different from the storage instruction operation means when the drive command operation means operated to generate the drive speed command and drive direction command of the optical adjustment means according to the operation amount and the operation direction is not operated In response to operation of the operation means, the optical adjustment means is driven in a direction corresponding to the preset direction information stored in the storage means at a speed corresponding to the preset speed information stored in the storage means. An optical device drive unit comprising: an arithmetic processing circuit for performing speed / direction preset drive control. In an optical device drive unit mounted or connected to an optical device body having a lens or other optical adjustment means, and performing preset drive control using preset information stored in advance for the optical adjustment means,
Prior to starting the preset drive control, a drive command operating means operated to generate a drive speed command and a drive direction command of the optical adjusting means according to an operation amount and an operation direction is operated in advance and a storage instruction is issued Storage means for storing the drive speed command and the drive direction command of the optical adjusting means at the time of operation of the storage instruction operation means as preset speed information and preset direction information when the operation means is operated;
Preset speed information stored in the storage means is stored in the storage means in response to operation of a control start operation means different from the storage instruction operation means when the drive command operation means is not operated. And an arithmetic processing circuit for performing speed / direction preset drive control for driving in a direction corresponding to the preset direction information stored in the storage means at a speed corresponding to. The arithmetic processing circuit compares the actual driving speed of the optical adjustment means with the driving speed corresponding to the preset speed information when performing the speed / direction preset driving control, and substantially matches the both driving speeds. The optical device drive unit according to claim 7 or 8, wherein the control of the actual drive speed of the optical adjusting means is controlled as described above. 10. The optical device drive unit according to claim 7, further comprising display means for displaying that the speed / direction preset drive control is being performed. A speed selection operation means operated to select whether the driving speed of the optical adjusting means is a driving speed corresponding to preset speed information or a maximum driving speed that can be driven;
11. The optical device driving unit according to claim 7, wherein the arithmetic processing circuit drives the optical adjusting unit at a driving speed selected by an operation of the speed selecting operation unit. The arithmetic processing circuit, when performing the speed / direction preset drive control, stops the speed / direction preset drive control in response to the operation of the control start operation means. Item 12. The optical device drive unit according to Item 11. A camera system comprising the optical device according to claim 1 and a camera to which the optical device is mounted. An optical device drive unit according to any one of claims 7 to 12, an optical device main body to which the drive unit is attached or connected, and a camera to which the optical device main body is attached. A featured camera system.

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