JPS6180131A - Flash photographic device - Google Patents

Abstract

PURPOSE:To perform switching between photography in which the quantity of flash light emission based upon the TTL direct photometry and normal flash photography easily and securely by reading an external photographic mode discrimination signal and permitting or allowing emit emission quantity control. CONSTITUTION:Photographic mode data transmitted by radio from a remote controller VI equipped with a photographic mode changeover switch 50, transmission part 52, etc., is received by the reception part II at the side of a camera I. Then, the photographic mode discrimination signal is read and when the photographic mode is a natural light photographic mode, the control over the quantity of light emission by an electronic flash device III is permitted and flash light emission control photography based upon the TTL direct photometry is made effective; when a flash photographic mode is entered, the control over the quantity of light emission is inhibited and normal flash light photography is made effective. The photographic switching corresponding to a specified mode is performed easily and securely by the automatic switching.

Description

[Detailed description of the invention]

The present invention allows the film to pass through the WL shadow lens during film exposure.
The so-called TTL measures the subject light reflected from the film screen.
Direct photometry) When the integral value reaches a predetermined value, the electronic flash
Sends a light emission stop signal to the optical device to control the amount of light emitted by the electronic flash device.
Regarding the flash photography and Q5 device controlled by ff1lJ. l1 to Akira λ Based on TTL direct photometry, an electronic flash device (hereinafter referred to as
7) A flash that controls the amount of light emitted by
The tb device is used during film exposure (i.e., when the camera is working).
It is designed so that it operates only when
has been completed. In other words, this flash photography device
The desired exposure of the desired part of the subject is achieved by flashing the flash.
For the special purpose of
When the light is fired independently, the flash meter gives off 7 mm.
When determining the amount of light, it operates and I/1 ~ 1 (i.e.
, Camera 1 is not working and no light emission stop signal is output.)
. At this time, a predetermined light emission is performed prior to the activation of the 7 lash force camera.
The flash meter is set to this amount of light.
Based on the exposure control design, the desired part of the subject gets the desired exposure.
data (aperture or shutter speed). follow
The exposure control data calculated by the flash meter
When performing flash photography based on predetermined data
, the flash emits the same amount of light as in the calculation above.
For example, desired photography can be performed. However, TTL direct
In a flash photography device that performs flash photography based on photometry,
Camera's TTL direct metering light receiver and flash
The light receiving angle is different from the meter's light receiving part, and each light receiving part is not able to measure.
The parts of the subject that are illuminated are often different (1), so the above specified
The light emission stop signal is activated when the light emission level reaches a level different from the light emission level.
It happens more often. In other words, the amount of light emitted differs from that measured by a flash meter.
Therefore, there is a high probability that the desired photographing will not be possible. The present invention is based on TTL direct metering to solve the problem that Akira is trying to solve.
In a flash photography device that controls the amount of light emitted by
Flash photography cannot be performed with the flash output when setting the shadow data.
The purpose is to ensure that 1. The present invention works in conjunction with an electronic flash device having a light emission amount control means.
natural light or
In photographic devices that use flash exposure control, the above
The data is for flash photography data and natural light photography data.
Distinction signal input hand that inputs a signal indicating either
By reading this distinction signal, it is possible to use natural light photography.
In the case of data, the light emission amount is controlled based on TTL direct metering.
TT for data for flash photography.
Features.・ External input data is natural light wt shadow data and flash photography
It is possible to read the discrimination signal indicating whether the data is
Therefore, the above external input data is natural light wi shadow data.
If so, light emission amount control based on TTL direct metering
is allowed, and if the data is for flash photography, use TTL dye.
The above light emission control based on rectphotometry is prohibited and the flash
The shutter emits a predetermined amount of light. Actual IL Figure 1 shows the appearance of the entire camera system to which this invention is applied.
It is a diagram. This camera system consists of a camera body (I),
Receiver (hereinafter referred to as receiver) (■). 7 Latssie device (I[l), r5 output meter (hereinafter referred to as meter)
) (■), transmission n A (hereinafter referred to as remote control A)
) (V) and transmitter B (hereinafter referred to as remote control B) (■)
(R), and the camera body (1) or flash
Connect the device (I) to a light meter (■), remote control A (V) or
It is controlled by either controller B (Vlr).
Ru. In Figure 1, the camera body (H's real shoe (1)
) is equipped with a receiver (I[) or a flash device (I[)
I) is connected. The camera body (r) has a shooting T-hair lens.
(10) is attached. In the receiver (II), the light receiving part (3) is
A, B (V), (VI) or meter (■)
It receives an optical signal for data transfer. (・t) is remote
Send optical signals for data transfer to controllers A, B (V), (Vl)
It is a light emitting part that believes in (5) is installed in the receiver (If).
The light emission start point is set for the flash device (III) to be attached.
In order to output the S signal, we receive the light emitted from the pond by 7 lanterns.
This is the light receiving section. (6) is a meter (IV).
(Data from remote controllers A, B (V), (Vl) is normal.)
This is the display section that indicates when the bank picks up.
. (11) is the data specifying the channel of receiver (n).
It's earl. This receiver (II) also has a camera body.
Similar to (1), a hot shoe (7) is provided,
This hot shoe (7) has a 7 latsier device (III).
is mounted by the mounting part (8). 7. Noshie device
(1) and (9) are light emitting parts for illuminating the subject. The camera body (1), receiver (II), and frame shown above
A block showing the overall circuit configuration of the circuit of the lash device (I[l)
A lock diagram is shown in FIG. And inside the camera body
data transfer circuit (INF) and light emission control circuit (FL
A specific example of C) is shown in Figure 6.
Microcomputer (hereinafter referred to as microcomputer) (MC, J)
70-charts showing the operation are shown in Figures 17 and 8.
be. The power / Ukimoto is equipped with the display shown in Figure 2.
. In the 21st JJ, P, A, S, M, EXT are exposed
This is the area that displays the control mode, and the aperture value and exposure time.
Programmed automatic exposure automatically determined according to brightness
P is displayed when in control mode (hereinafter referred to as P mode).
Well, the price and exposure time are the same! 1iIJ exposure control mode (
In the following example, A mode is used (8), A is displayed, and the exposure
Time data automatic exposure control mode (hereinafter referred to as S mode)
S is displayed and both the aperture value and V exposure time are
Manual exposure control mode, which is controlled to the manually set value
(hereinafter referred to as M mode), M is displayed. Also, send from the meter (■) or remote control A (V).
Exposure control mode based on exposure control data (see below)
(external mode), EXT is displayed and the frame is
If the data is from Rush i, use FLASH, natural light photography.
If it is shadow data, AMBI I is displayed. The ISO part contains ISO data that indicates film sensitivity.
The SS part shows the exposure time data, and the F part shows the aperture value.
Each data is displayed numerically. Also, the displayed exposure control data may cause overexposure.
When 0VER is displayed, it becomes underexposed.
At this time, UNDER is displayed. Also, N1 mode
When setting the iffff light exposure using the displayed data,
When it is done, an OK message is displayed. In addition, the display section
The 7 Lassocie mark in (55) is the 7 Lassocie device (I
II) When the preparation for emitting light is completed, it will blink at a certain period and the flash will turn off.
When the flash device (I[[) is automatically adjusted, the light emission level is
It flashes for a certain period of time at a faster rate than when it is ready. In addition, the receipt
Specific examples of the bar ([1) are shown in Figures 9 to 14.
. Further, a specific example of the 7-rancil device (I[I) is the 15th
- Shown in Figure 17. The table shown in Figure 3 is on the back of the 7-lash Vc position (I[[).
A display section is provided. In Figure 3, the display section (5G
) is a 7 lash device ([[) lights up when the light emitting quasi-pongee is completed.
The display section (57) shows the flash device (lI[)'s self.
When dynamic dimming is performed, it blinks for a certain period of time. Furthermore, this automatic
5.1 light is TTL direct metering on camera body)
It is carried out based on. Also, when in C mode (automatically open)
AUTO is displayed, indicating the manually set flash output.
M A N if it is a manual constant likelihood mode that emits light.
U will be displayed. In this manual flash mode,
, when full light emission is set, the FULL table will be displayed.
The emission is 0.5 EV less than the total emission.
-0,5 if the amount is set, -1,0,1 if it is IEv
, -1,5 for 5 Ev minutes, and the same for up to 3 Ev minutes.
When a small amount of light emission is set, -3 is displayed. 180
(Film sensitivity) is the I sent from camera (1)
SO data is displayed, and the SO data sent from the camera is displayed at the F position.
The print value data will be displayed. Self in position D! l17
In J flash control mode, the ISO and
Aperture value data and minimum light emission at 7 rasochew VC setting (I[[)
Compensated sequence of appropriate exposure determined from
The moving distance range is displayed, and in manual flash mode this
Appropriate exposure determined from light emission amount, ISO and aperture value data
The maximum shooting distance that can be obtained is displayed. (■) is a meter, and its specific example is shown in Figures 18 to 23.
This is shown below. (15) is a light receiving bulb for incident light photometry.
A light receiving element is provided below this sphere (15). (16) converts the data obtained from the meter (IV) into an optical signal.
A transmitter (17) is a receiver (II) for sending out data.
a receiving unit that receives data transmitted from the light emitting unit (4) of the
It is. (19) is the mode switch for changing the measurement mode.
switch, and if it is in position 1, it is in ambient light measurement mode (hereinafter referred to as AMB).
(referred to as I mode), and in position 2, coded flash measurement is possible.
constant mode (hereinafter referred to as C0RD mode), position 3
This becomes a non-code 7-runche measurement mode (hereinafter referred to as N0NCORD mode). C0RD mode
In this case, press the measurement button (27) and the 7 lash
One signal is output from the terminal (30), and the measurement
The elephant's 7-lash device emits light. On the other hand, N0NCORD
When in mode, press and hold the measurement button (27) for 7 seconds.
When the flash device emits light, the rise of these 7 flashes of light
Upon detection, measurement begins. In the meter (IV), (22) is for setting the exposure time
key, (23) is the key for setting the film sensitivity, (24) is the key for setting the film sensitivity.
) is change amount data that changes the measured flash emission amount.
It is a setting key, and these three keys - and the UP key (25)
3 types of exposure control in combination with the and DOWN key (26)
control data is set. (28) is the transmission key, and when this key (28) is pressed,
The data obtained in the meter (IV) is sent to the transmitter (
16) as an optical signal. (29) is a test
This is a key for emitting light, and press this key (29) for sending.
When the key (28) is pressed, the test flash signal is sent to the transmitter (16).
It is sent out as an optical signal from This signal is sent to the receiver (
When it is received by the receiver (■),
7 u/sh device (I[[) emits light and the meter (I
V), the 7 lash device (I[
The luminescence amount of [) is measured. Test flash key (29)
If the send key (28) is pressed without being pressed
, the channel selected with the channel selection dial (21)
The receiver (II) corresponding to the channel is installed.
The exposure control operation of the camera (I) starts. Channel is 1
There are up to 5, and in the No position, data is only sent.
Do not release the camera, and set it to the ALL position.
receiver (II') regardless of the channel.
The exposure control operation of all cameras equipped with the
Ru. (20) clears the data sent to camera (I)
This is the key to send data for Meter (IV)
An example of the display on the display section (18) is shown in FIG. In the figure
In AMBI mode, AMB I, Co
In RD mode, C0RD, N0NCORD-f knee
)' case 1: l! N ON CORD is displayed.
Ru. Set the ISO position with the meter (■) or press the camera.
(1) The ISO data sent from the side is displayed and
The exposure time data set on the meter (IV) is in the S position.
data is displayed. Also, at the Gv position, there is a change indicator for the amount of light emitted.
The data is displayed, and this data is +3 to +3 in 0.5Ev units.
It changes with the opening of -3. Measurement using a photodetector is at position F.
5 based on the setting values such as value and l5O1 exposure time, light emission amount change, etc.
1. The fringing value for proper exposure is displayed. This display is 1
1: F value display section at vjlj position and 1/8 E v unit
It is purchased with a display section in OUT is meter (IV
) is not linked to the control of the camera <, I )
OK is displayed when control is possible. F C+4 is the light emitting part of the 7u7 unit (III), 11
REL is displayed when the camera (I) exposure is completed.
Displayed when an output control operation is performed. Also, O.V.
For E R and UNDER, the print value is meter ([V)]
If the display is not linked or the control of Kamu (I) is not linked.
Displayed when In the remote control A (V) in Figure 1, (45) is the remote control
The data set in channel A (V) is sent to receiver (I[).
The transmitter (46) transmits data from the receiver ([[)
This is a receiving unit that receives transmitted data. (35) is a dial for manually setting the exposure time, (36)
is a dial for manually setting the aperture value, and is a data transmitter.
Read the indicated value of a meter that has no power.
, dial this (35). If set to (36), the meter (■) has a sending function.
It will work the same way. (37) is the transmitted exposure
Lights up when the control data is not linked to camera (1) control.
The display part (38) is a light emitting unit of 7 lamps (III).
The display that lights up when preparation is complete, (39) is the camera
This is a display that lights up when an exposure control operation is performed.
. (41) is the mist control data to be sent for natural light 'A'?
This is a switch for switching between 7-ranche light photography and automatic shooting.
If the natural light mark O (on the left) is located, the natural light
If the data is in the position of the flash light (on the right side)
A signal indicating that the data is for flash light oscillation is displayed on the receiver.
server (n). (42) is single frame shooting mode
This is a switch that switches between continuous shooting mode and continuous shooting mode.
, press the send button (47) once in 1# shooting mode.
When pressed, 1, the piece's Fu, and the shadow are performed. On the other hand, the position of C
If it is, it will be in continuous shooting mode and press the send button (47) 1
Press twice to display the camera (1) inside the iIL or attached module.
Continuous shooting starts from 1 motor drive, and the transmit button is pressed.
If button (47) is pressed again, continuous shooting operation will stop.
. (=43) is the meter (IV) dial (21)
Channel designation dial with the same configuration, (40) is a meter
- Clear key with the same configuration as the dial (20) of (IV)
Then press this key (40) and press the send button (47).
When this happens, the data sent to the camera <1) will be cleared.
. (44) is the display section], and the receipt from the camera (I) is displayed.
Various data sent via the bar (II) will be displayed.
It will be done. A specific example of this remote control A (V) is shown in Figure 1jIJ24.
This is shown below. The remote control B (VT) in the rjS1 diagram is connected to the remote control A (V).
In comparison, data reception from receiver (n)
, and the exposure control data transmission function are omitted. Therefore, in this remote control B (VI), continuous @Aya/1
．． Frame shooting mode selector switch (50), channel selection
Selection dial (51), transmission section (52), transmission button (5
Only 3) is provided. This remote control B (VI)
A specific example is shown in figure fjS25. Next, we will explain the data transfer system in this system.
Ru. First, the camera body (I), receiver (II) and
7 Ranciu device (I [[) between Clos/Klein
Two-line electrical serial data bus
Data transfer is not performed automatically. On the other hand, the receiver (I
I), meter (IV), remote control A (V), remote control
B (~T) using a priori method using high-frequency infrared light.
Serial data transmission takes place. This transfer method is “1”
Time to send high frequency infrared light with signal and “0” signal
By changing the interval, it corresponds to the middle time between “1” and “O°゛”.
Determine whether infrared light is incident at the relevant time
This determines whether it is 1" or "0" and reads this data.
It looks like this. Table 1 shows the meter (IV), remote control A (V), B (Vi
) to the receiver (II), and the receiver (I[
) to the camera (H).
MT3). Table 1 Table 2 (MTO) is meter NV), remote control A (V), B (
~T) to the first 8 bits input to the receiver (II)
This is the data of The 1st bit (b,) is a dog.
(MTi) and (MT2) data for natural light photography
If it is for 7-ray light photography, it should be “0”.
ing. (M T O) bottle) (b, ) ~ (b3)
is selected using the meter (IV) and remote control A (V) and B (W).
There is data (see Table 2) indicating which channels were used. This data is sent to the dial (11) of the receiver (II).
``Matches the data of the selected channel''
, the camera (1) to which this receiver (It) is attached
)'s exposure control shift begins. (MTO) Pino) (
13,) is 1'! If it is PJFu Akira mode, it is “1”, continuous
In continuous shooting mode, it is 0". Note that the meter
- (IV) has a switch to switch between 1-frame wL shadow and continuous shooting.
is not provided and is always "1", 1-frame shooting r + Numode's belief.
The number is output. (MTO) bins) (b, ), (+), ) are shown in Table 3.
This is data that indicates the source of the data.
If it is “01”, the transmitting source is a meter (1’/) or a relay.
Indicates remote control A (V), and if 11", remote control B (Vl)
shows. If 00" is input, the receiver (II)
The data sent to the reading camera (r) is cleared.
Ru. (MTI) is calculated by meter (IV) or by remote control.
Indicates the threshold value data set in A(V) in 1 byte,
(MT2) with the meter (■) or remote control t\(V).
Indicates the set exposure time in 1 byte. (MT3) (1].) ~ (hp) are spare bits
All are “0”. (b,) of (MT3) is 7
, the data indicates the direction of change in the amount of light emission.
"1" means ten directions (increase), "0" means one direction (decrease).
(low). (Its) to (b7) are shown in Table 4.
This shows the change data for the amount of light emitted. In addition, the remote control
In case of B (■), (MTI), (MT2), (MT
All “OOH” data is output from the 3 bytes in 3).
be done. Table 5 is sent from camera (1) to range bar (II),
Receiver (II) to remote control A (V) or meter
(IV) Data sent to (RMO) or RM! 3
) is shown. Table 5 In Table 5, bits (1].) to (11
2) is a spare and is marked "O" on the pan. (b,
) from the meter (1”/) or remote control A (V)
The sent data is out of control linkage of camera (I).
”, if within the continuous IHJ range, it will be 0″’. (b,) is
Camera (1) is meter (IY), remote control A (V), B
When the exposure control operation is performed using the signal from (■), tilw,
If it has not been performed, it will be "0". (b,) is a flash
A signal indicating whether the flash device (1) is ready to emit light.
This is the bit that outputs the flash device (III).
(I) of the main capacitor of the 7 lash device.
A signal indicating that the charging voltage has reached a predetermined value (charging complete).
If the completion signal) is input, a “1” signal indicates charging is complete.
If no signal is input to the camera (I), the signal is “0”
is output. Via ) (bs), red from (b7)
Indicates that the oscillation source of the external light signal is the receiver (II).
The data "10" is output, and the (MTO) beep) (
bs) Distinguished from (by)'s 01'', '11'', and '00''
be done. (RM1)+(RM2C(RMx) are each camera
(4) Shortest exposure time data T vMc, longest exposure time
Data T voc 7 synchronization limit exposure time for rash photography
Data TV “/!” is indicated by 1 byte. (RM4) is I
Attach SO data Sv (RM5) to camera (1) 3
Two-component lens X at t: Maximum that is the minimum diameter of (10)
A vMc (RM 6) is the aperture value of the interchangeable lens (10
) is the open aperture value (minimum aperture value) Avoc
1 byte each. Table 6 Table 6 is from the 7 lash device (III) to the camera body (1)
The data (FCO) to be read into is shown. (FCO>
The bit (b,) of the
If the switch is ON, “1”, if it is OFF, “
0” and this signal is read into the camera body (1).
Ru. Please note that the power switch of this flash device (II[)
If the chip is OFF, all 1 byte of (FCO) is “O”.
''.(Mu,) means the main capacitor is in the photoelectric completion state.
If so, it will be “1”, and if it is not charged, it will be “0”. (b2
) is the 7-round process for proper exposure in the flash device (1).
m When it is determined that automatic light adjustment has been performed, a certain period of time will elapse.
It becomes "0", and becomes "1" in other cases. (bi
) is a flash device compatible with this system.
It is always “0” (I), and this number 13 is printed with the camera (I).
Used for t11 depending on whether the 7 lashes are compatible with the stem or not.
It will be done. (m,) ~ (b7) are spare bits, and are
bit is “0”. Table 7 Table 8 Table 7 is sent from camera (1) to 7Rush CI [I].
(CF O) or CF3). (CFO) is the control aperture value for flash photography\V,
(CFI) is the focal length gIIf of the interchangeable lens (10)
are each indicated by 1 byte. (b2) of (CF 2 )
) indicates the exposure control mode of the camera, Table 8
As shown in , “000” in P mode and “000” in A mode.
“001”, “010” in S mode, “010” in N4 mode
7"011", "100" in external mode
. In the 5 bits (b, ) to (b7) of (CF2), the camera
The engineering So data used in La (I) is sent. Bit (1) of (CF3). ), (+), ) are reserved “
OO”. (b2) is the receiver (II)
The data read by the camera (1) through the camera is taken using natural light.
When the data for
The light emission of the position (III) is prohibited. -, other
When in mode, there are 7 lashes (I[[) at °0”.
Light emission occurs. (+11) is manual flash mode
(Model that fires only the flash amount set in the flash.
Set to “1” when it is necessary to emit light at
Ru. This is done by the test flash signal from the meter (■).
7 When the lash device (lIf) emits light, the camera (+
) does not work, so the camera does not output a light emission stop signal.
The automatic light control for 7 m long cannot be changed. Therefore
, the meter (1'/) when a test flash is fired.
is a state in which automatic light adjustment is not performed, that is, in manual flash mode.
The amount of light emitted in 7 lashes will be measured. This makes sense
Exposure control of camera (1) using control data calculated by
is carried out, so you can automatically control the exposure when actually controlling the exposure. I! IJ tone
If the light is
Shadows may not work. So, such a test
In case of light emission, automatic light adjustment is not performed during exposure control.
Set “1” to (b3) for manual flash mode.
Output. In addition, in other cases, a 7-runchie device (III
) is determined by the number 'self!' I! lI dimming mode or
0” is output to fire in the manual flash mode.
. (b4) to (b,) of (CF 3 ) are (MT3)
The data is the same as (b,) to (1) t), and
The amount of change in the amount of light emitted used during calculation by the controller (IV) and
Indicates the direction of change. This data is sent to the 7 Rancier device (III).
・The amount of light emitted by the engine will be changed based on this data. Figure 5 shows camera (1), receiver (II),
This is a professional diagram showing the overall configuration of the processing device T[(III>
Ru. The lower left of Figure 5 shows the block diagram of the camera body (1).
, this camera book (Do(1) connector (CN,) has
into the interchangeable lens (10) via the connector (CN,)
The installed circuit (LEC) is connected. Second child
Power by Necta (CN o), (CN,), Nora book [
de(I) and exchange lens r(10),! : Harain ((,,
), (rl), (r2), (!,), (1,) by
electrically connected. The line (N,) is the F runno star (T) for powering the camera body.
r2) to the lens circuit (LEC) via the protective tear resistance.
This is the line that supplies power, and (f,) is the line that connects the camera body (1
) and the lens circuit (LEC).
This is the line. There is a replacement lens inside the lens circuit (LEC).
ROM, which fixedly stores various data specific to the lens,
Input the ROM addresses in sequence from line (12).
Address instructions are specified sequentially based on the clock pulses that occur.
and sequentially clock the data output from the ROM.
Hand that outputs serially from line (1,) based on pulses
It is equipped with steps. Line (11) to Ren r (10)
A lens circuit (LEC) equipped with these means
A signal ")Iigl+" is input which makes the active state. Input from the interchangeable lens (10) to the camera body (1)
Data includes open aperture value, maximum aperture value (Q small aperture)
(shape value), focal length, other exposure control and automatic focus adjustment
There are various data for maintenance. Furthermore, the connector (CN 2) (first
Figure: At the hot shade (1) position of the camera body (1)
) and connector (CN, ) (Fig. 1 Receiver (II)
) on the bottom of the mounting part (2) of the receiver (
If) is electrically applied to the camera body (1).
Ru. And the receiver (n) connector (, CN + ) (
Q'S Hot shade (7) of receiver (II) in Figure 1
) and the connector (CN 5) (as shown in Figure 1).
7 At the bottom of the mounting part (8) of the cleaning device (III).
) via flash f! (III) is the receiver
(II) electrically! pA is connected. Furthermore, this 7
U7 device (I[[) is attached directly to the cuff 2 body (1)
In this case, the connector (CN
2) and (CN5) will be directly connected. Signal line between camera body (1) and receiver (II)
In is (ST,), (STY), (ST,), (ST,
), (STs) and the ground line, and the receiver
-I word between (II) and 7 lacquer VC placement (II)
The lines are (ST,), (ST2), (ST3) and ground
There is a line. (STY) is the X connection of the camera body.
Closing signal of point (S x) or control of receiver ('II)
The “Low” signal from the control circuit (RCC) is sent to the camera body (
1) Or 7 lacs 1 device (■) from the receiver (n)
(ST2) is a line for transmitting serial data.
The above data (MTO) ~ (MT3
), (CFO) ~ (CF 3 >, (RMO) ~ (R
MO) and (FCO) are in series, and the clock from (STY) is
camera body (■) and receiver (■),
Transferred between 7 ranoshu devices (I[[). series of actions
First of all, what about the 7 Lanonyu device? Camera book from f(III)
(FCO) is sent to the body (1), followed by the receiver (
II) From the camera book (・do (1) to (MTO) ~ (MT
3) is sent. Exposure control on the camera body 4) based on these data
Q (When II is completed, the output from the camera body (N)
(CFO) to (CF3) is 72. device (
It is read in 1) and output to the dog from the camera body (1).
(RMO) ~ (RMO) is read into receiver (II)
be caught. In addition, while the above data is not being exchanged,
/sh device (m> main capacitor (hqc>)
If the charging voltage has reached the predetermined value, a “HiHI+” signal will be displayed.
, if the LoIll'' signal does not reach 7
It is output from the device to line (ST2). Furthermore, when the xenon tube (XE) starts emitting light, the flash
The line (ST,) is forced by the push device (1)
When set to “Low”, the camera body (1) is set to control the amount of light emitted.
This becomes a signal that causes an integral operation to be performed. (ST,) first sets the camera's operating mode to 7.
for communicating to the device (I[[) and the receiver (II)
Outputs the signal. This signal is a pulse “HigI+”
from the signal line (S T ,).
Rush device t(III), derailleur from lane bar (If)
Directly reading data (FCO), (MTO) ~ (MT3)
In the front, for example, output a pulse with a width of 5011 see,
〆U (1) to 7 lashes (1), receiver (II)
For example, before sending data to 1001. tsec width
For example, before outputting pulses and starting exposure control operation,
For example, a pulse with a width of 150 μsec is output. And (ST
, ), during data transfer, camera book 4) is 8 pieces.
Seven clock pulses for synchronization are output, and exposure control is also performed.
The pulse to stop the flash device (■) is being output.
Powered. (S T ,) is not provided in the 7 lasso device (III).
from the receiver (II) to the camera body (1).
is input, and from this line, the record that becomes Lou+″′ is input.
A leak signal (exposure control operation start No. 15) is sent. (STY) is also provided in the flash device (III).
Not only from the receiver (II) to the camera body (1).
is input. From this line (ST5) is the photometry start signal.
(signal to start the preparation operation for exposure control) is input.
. Note that this line (ST,), (ST,) is
without transmitting through the receiver (II)
A socket is provided on the camera body (1), and both sockets are
f people using a cable with plugs at both ends that are connected to
You may also try to reach it. In the camera body (1), (BAB) is the power battery.
The power line (10E) is connected directly from this power battery (BAB).
) via microcontroller (MC,), AND circuit (AG,)
, (A N ,), NAND circuit (NA,), automatic focus adjustment
Cleaning circuit (AFC), buffer (BF), display circuit
(BDP), supply to interface (INF)
electricity is carried out. A transistor (Trz) is a microcomputer (
When the terminal (P3) of MCo) goes low, the buffer
conduction through the power supply line (BF) and from the power supply line (+Vl).
, exposure control data output circuit (SDO), photometry circuit (L
MC), fringe pulse output circuit (FPG), exposure control MC)
net circuit (MC,), flash likelihood control circuit (
FLC) is supplied with power. In addition, the light emission amount control circuit
(FLC) and interface circuit (INF) details
An example is shown in FIG. In the receiver (n), (BARC) is the power battery.
Yes, the main switch (
directly via MSRC)? 'Li Source Liar Line'2)
Power is supplied to the entire circuit from. (CHS) specifies the channel of receiver (II)
This is a circuit that outputs the data obtained by dialing the dial (11) in Figure 1.
) outputs channel data according to the settings. (RE
Po) is provided in the receiving section (3) in FIG. A light receiving element consisting of a PIN photodiode, for example.
There is. (PAM) is the output of the light receiving element (REPo).
A preamplifier that converts into waves (signals for dinotal processing).
be. (S L P ) is provided in the light receiving part (5) in Figure 1.
A preamplifier connected to this photodetector.
Synchronized with the rise of 1 light from 7 runci (SLAM)
A pulse is output. (CHL) is the infrared light provided in the transmitter (4) in Figure 1.
In response to the signal from the control circuit (RCC) with a light emitting diode
Driven by a transistor (Tr, ) that turns 0N-OFF when
and sends out an infrared light signal. (OUL,) is the m1 diagram
This is a light emitting diode provided in the display section (6). Baa
(I'+'), remote control A (V), B (VI)
When it is determined that the data has been read correctly, the control
transistor for a certain period of time based on the signal from the circuit (RCC)
The transistor (Tr,) becomes conductive, and the light emitting diode (OU L,
) lights up, indicating to the operator that the data has been loaded correctly.
Let it be. 7 In the Lanossie device (III), (BAFL)
(MsFL) is the main switch. The output of the power battery (13AFL) goes into the external pressure circuit (DD).
The external pressure output of the booster circuit (DD) is connected to the diode (D
The main capacitor (MC) is charged through the
Ru. The charging voltage of the main capacitor (MC) is monitored.
– is monitored by the circuit (CHM), and this monitor
The output (CH+) of the circuit (CHM) is the charging state detection circuit.
(CHD) manually. The detection circuit (CHD) is
of the external pressure circuit (DD) based on the output (cr-r, ) of the external pressure circuit (DD).
Controls the operation and charges the signal line (CH2)
Outputs a signal indicating whether it is completed or not. main capacitor
A known flash light emitting circuit is connected in parallel to (MC).
ing. (TRC) is the line from the control circuit (FLCC)
Based on the light emission start signal input via (FSTA)
The bird puts - on the xenon tube (XE) once.
(SC) is a -
This makes the main thyristor conductive. (STC) is the terminal (FSTP) of the control circuit (FLCC)
Based on the light emission stop signal output from the main cyrisk (
SC) is made non-conductive and the emission of (XE) of the xenon tube is stopped.
This is a light emission stop circuit. The low voltage output of the secondary side output of the external pressure circuit (DD) is
Iode (D2), Zener diode (ZD) and transistor
A constant voltage circuit using a transistor (Tr) was installed in the power supply line.
(VF), and this line (\/F) is connected to
The output of the power supply battery (BAFL) is guiode (D,, >
connected via. And capacitor (CC)
is provided to stabilize the power supply. (AMD) has data for automatic light control mode and manual setting flash output.
(FDP) is a display circuit.
Ru. Note that the charging state detection circuit (CHD) has a signal line.
reference clock from the control circuit (STY) and control circuit (FLCC).
(φF) is input, and the signal line (ST3) is
Measures a certain amount of time (for example, 3+nin) every time you stand up
A timer is provided to perform this. and this timer
External pressure operation is performed only when the
. Therefore, the camera body (1) and the 7-lanoshu device (I[l
) while signals are being exchanged with
! a, and the external pressure is further increased for a certain period of time after the signal transmission and reception is completed.
Operation continues, and boost operation stops after a certain period of time
An example of the sea lion sea lion will be described later based on Figure 15.
Ru. Next, based on Figures 5 to 8, we will mainly focus on the camera.
The operation of La Hon Hon (1) will be explained. Release button (not shown)
) is pushed to the first step and the photometer switch (Sl) is closed.
or the receiver (If) is connected to the line (
ST,) through l-0-''jl','l)e start
When a signal is input, the output of the AND circuit (AG u) is
falls to ``Low'', and the interrupt pin (iLo) is set to vj
No. S inputs, and the microcomputer (MC,) reads #1 in Figure 7.
Start operation from step. In step #1,
Set terminal (P,) to “Low” and connect via 8777 (BF).
to make the transistor (Try) conductive and connect the power supply line (Try).
■Power is supplied via 1). Next, the lens circuit (LEC)
) to read data from end 7-(P,Z)
Set it to “High”. Then the signal line (C3L) becomes “
11g1+'', the AND circuit (A
N6) and (AN?) become active, and the line
(pl) becomes "High" and the lens' circuit (LEC) becomes "High".
) becomes active. In step #3, register k is
Set “0” and move to step 4, serial input/output
Perform an action (sro). In this step, the microcontroller (MC0) terminal (SCK
) outputs eight clock pulses, and this pulse
is the AND circuit (A N
G ) (ffi 6 figure) and output to line (r2)
and sent to the lens circuit ([, IEc). Then Len
The signal from the current σ circuit (LEC) is the same as the rising edge of σ.
Data is transferred from the lower bit to the line (2 bits/bit at a time).
,) is output. This data is then
AND circuit (AN,) of the base (INF). Stop the OR circuit (OR2) and turn on the microcontroller (MC6).
input to the power terminal (SIN) and from the terminal (SCK)
One pin at a time at the falling edge of the output clock
The input/output register l0Ri in the microcontroller (MC,,)
Loaded. Note that during this series input/output operation, the
The rise of the beam from the output terminal (SOU) 9
Data is output bit by bit from the lower bit in synchronization with
It will be done. When the operation of the I/T step is completed, the Renos for Hitodeba is
Data (OR) (2) The read data is used for lens data setting.
Set Renosuf [R,,, and set the contents of the register to “1”.
Add the contents of the register in step #7 or 11”
It should be "11" depending on the PL.
Return to step #4 and read the next data W\,'
Perform l action. The contents of the step t register in #7 are
n'', the data for the “+1” feed required in this case will be recorded.
from the lens circuit (LEC) to the 2-channel camera body (1).
In the n registers of registers RL, , ~RLu-,
Now that the settings have been set, move on to step #8 and
Set the child (P1□) to “Lou+” and change the line (!,) to “
Set LoI11''.Next, step #9? is based on the data read from the lens.
Determine whether the lens is attached based on the This is a one-stop solution for addresses that have strayed from the exchange list on the pan.
Store the specified data (check data) and
Check if this check data is loaded in Kimoto
It is determined by i. When it is determined that the interchangeable lens is attached to the MC,
In step #10, set up the automatic focus adjustment device for the interchangeable lens.
Output the data to port) (P,) and automatically 5. (One-point tone-3
Start the operation of the power supply circuit (AFC). On the other hand, the exchange
As mentioned above, if the lenses are not worn, there will be a penalty of 1.
Do not perform automatic focus adjustment 2 operation and move on to step 12.
Ru. Step #12 is the exposure of the camera body (1)
Data from control data output circuit (SDO)
Read from (P,). The data to be read is
output control mode, set exposure time, set fringe value, film capacity
The code pattern on the device is automatically read and automatically set.
There are film speeds that can be manually set or manually set. Next
In step 13, the light metering circuit (LMC)
Connect the photometry output input to the log input terminal (ANI) to the terminal.
A-D conversion is performed based on the reference voltage input to
Ru. From step #14, the flash device (III) and
The operation of reading data from the Seaver (II) is performed.
It will be done. First, output “Higb” to the terminal (P,).
, the signal line (C3F) is set to "Higl+". this
The AND circuit (A N , ), (A N
2), (A N 3) (A N,) is in active state.
Ru. Then, connect the terminal (P, .) between T1 (50 μsec
) 50μ to the line (CMO) as “Hi gl+”
Outputs a “High” pulse of sec. this pulse
is output from the AND circuit (A N + ), and the NOR circuit
(No,) outputs a "Low" pulse for 50μsec
do. As a result, the transistor (Tr4゜) becomes 50
The signal line (S T , ) is conductive for 50 μsec.
A “Higl+” pulse with a width of μsee is output. The flash device (I[[) and receiver (IT) are connected to this
When it is determined that a pulse of 50μSee has been input, the
The state is set to output data. First, in Step 7 of #16
is the data from the 7 Lassie device ([) to the camera body (I).
Performs serial input/output operation. That is, flash (I)
The above-mentioned data (FCO) is output from the lower bits.
. In the tjS6 diagram, this operation first occurs at the terminal (SCK
) is an AND circuit (AN2).
is output from the circuit, is inverted by the NOR circuit (No,), and is output from the
The registers (Tr, , ), (Tr, ko) are alternately 0N-O.
FF. As a result, the terminal (STz) is connected to the terminal (S
A clock that is in phase with the clock from CK) is output. Then, based on this clock, a signal is sent to the terminal (ST2').
The data (FCO) is input. . At this time, “Lon+” is output from the terminal (P1+).
Therefore, the output of the NAND circuit (NA, ) is High”
, the output of the AND circuit (ANs) becomes “LOI11”.
The transistors (Tr□) and (Tr, 5) are non-conducting.
It is well known. Therefore 1. Input to rako (Sr1)
The transistor (T r4.) is set to 0 according to the data that is received.
N-OFF, and the line (S) from the inverter (IN,)
The same data that is input to r1) is output.
. This data is an AND circuit (AN, ), an OR (OR2)
from the data input terminal (SIN) to the input/output register via
IO[This is read. Reno matari on step 17
IOR+: 3-dimensional data is stored in register FCR (
: Set and move to step 18. In step #18, set register k to “0”
Then, data is transferred from the receiver (II) to the main body (1).
Performs serial input/output operation. This crest is the receiver (n
) is outputting data (MTO), and this data
is read into register IOR. The contents of this reno person I(”)R are register MTR,
, is set to . Next, add “1” to register k and
11 by subtracting 1.
”, go back to step #19 and move on to the next data.
Read the data. Therefore, step #22
゛It is determined that the contents of the register become “4”.
When moving to step #23, register M
T RolM T RIs M T R:, M T R
3, the data MT from the aforementioned receiver (II), respectively.
o, MTl, MT2, MT are set.
Ru. To the dog, at the step of well 23, at the edge T-<P9), say “LOLI”.
+'' is output, and the 7 second input device (Iff), receiver
Stop the data acquisition operation from (Il). and,
Bits (+3.) and (b6) of register MTR9
Sort the contents by tlI. At this time, (b7), (+)G)
If is 00'', 11'', 01'', it is clear from Table 3.
The receiver (II) has a meter (IV) or
Exposure control data is read from remote control A (V).
Since there is no one, move on to step #70 and step 7 of #12.
Exposure control based on camera data read by the software 11
Perform the operation to calculate the data for use. On the other hand, M T Ro
If (b7) and (116) are “10”, then the meter (
IV) or the exposure control data is input from the remote control A(V).
Since there is a possibility that the
Ru. In step #26, the contents of register NτTR are “0”.
0) 1'' is determined by tlI. This register M T
R3 has data (MTI), i.e. meter (IV) or
is remote control A (V) or C) threshold value data Av or "0"
011" is input. Therefore, if "OOH"
Since no data has been entered, move on to step #70.
Ru. If the contents of register MTR are not “0o11”
Aperture value data from meter (■) or remote control A (V)
has been loaded and you can move on to step #27.
Ru. In step #27, the lens mounting is done in the same way as step #9.
If the lens is attached, #29
Move to step. On the other hand, if the lens is not attached
If so, move on to step #28 and the lens is attached.
Enter the data “0111” to indicate that there is no
Position display register AV D R1: Set, I31
Data indicating that the number of refinement stages is “0” in the step
Set the data “001” to the register A V CR, and #3
At step 5, 7 lights are displayed to indicate that the control is not interlocked.
Set the graph RF to “1” and use the display screen in step #39.
Bits (+) 2), (I]l), (b,
) is set to “100” to indicate external mode.
Move to the state where it will be used and move to the step 1 of well 40. well
Step 27: The lens is attached in Step 2!
When separated, the print read in the register (MTR,)
The value data is wider than the maximum aperture value of the interchangeable lens.
It is determined in step #29 whether the value is on the release side. The aperture value data is on the open side than the open aperture value A voc.
If this is determined, the Avoc is registered in step 7 of step 30.
After setting the star A■DR, the above-mentioned #31゜well 35. #
After passing through step 39, the process moves to step #40. one
On the other hand, the aperture value data is smaller than the open aperture value A voc.
When it is determined that it is on the side, the next step is #32.
value data or exceeds the maximum aperture value Avn+c of the interchangeable lens.
Determine whether the If it exceeds #33
Maximum aperture value A vMc in step to register AVDR
Control the register A V CR at step 34.
Refinement y, number A vMc -A voc! /:setting
After that, go through the steps of Noi 35 and #39 mentioned above to #・t
Go to f'5 line in step o. It has not been exceeded,
At step #3G, register the threshold value data A V D
R1,: Set and register A V at step #3S.
CR has the number of refinement stages for control (MTR,)
Set Avoc. In this case, since it is within the control interlocking range, use 7 lag RF.
Set to “'0” and go through step #39, then step #4o
to move to. Here, the contents of register DPR and P and A in FIG. S, M, EXT, FLASH, AMB I +0
VER. Indicates the relationship with the display of UNDER, OK,...
I'll keep it. Table 10 Observed exposure time data (MTR- is the best exposure time T
Rather than voc, 艮sho time separates the country by '1'. It is determined that (M T R2) < T voc.
Then, the maximum exposure is set in the control exposure time register TVCR.
Set the time and date T voc and go to step 7 of R44.
R3TT. (MTR,) and T voc
1. Once separated by 1, the exposure time data is displayed at step R42.
(M T R2) than the shortest exposure time data TvMc
There is a difference between short seconds and short seconds. Here, (MT
R2) > T vMc, the shortest second data T
Set vMc to register TVCR and step R44
to move to. If (M T R2) < T vMc, the exposure time
Since the data (M T Rz) is within the interlocking range, this data
Set the data (MTR,) in the register TVCR, and then
I・At the +6 step, 7 lag RF is “1” 1
I will decide whether or not there is one. Here, if “1”, it is a crest.
Since the value is outside the interlocking range, move to step R44,
If “o”, it is within the interlocking range, so step 48
to move to. Register RMR is the data R shown in Table 5.
M O is now set, and its business
J,) indicates that the read Crest 9 value or exposure time is outside the linked range.
If it is in "1" (indicating outside the interlocking range (No. 3)), (R4
4) Both the read fringe value and exposure time are linked together.
“0” if within the range (indicates within the interlocking range (No. H)
(R48) 2. At the step of R49, J sold t'! , wa(direct(M)
TR, ) and exposure time (MTR2) are measured by itching.
Exposure value Eve that is the appropriate exposure based on the measured value of (■)
Calculate the control fringe value (A to 7DR) and the exposure time.
The control mist value Evc is calculated from the time (TVCR). Na
Oh, if no lens is attached, register A V
Data of 01” is set in D R, and normal
Since it is a specially smaller value than the aperture value data,
Evc also has a particularly small value. Next step R51
Determine whether Eve<Evc, and set Ev
If it is determined that e<Evc, the exposure will be incorrect.
Therefore, “1” is added to (+37) and (b6) of Tonostar DPR.
Set 0'' to display overexposure.
The process moves to step 56. On the other hand, if Eve≧Evc
If it is determined that E ve
＞E Determine what Vc is. Here, Eve<I
If it is Evc, it will be overexposed, so register DP
Set “01” to (b,) and (110) of R and set the exposure mode.
Move to step 56 with the bar displayed.
do. If it is Eve2E, VC, it will be a proper exposure.
0 in (117) and (116) of register [')r'fl
0" to display the proper exposure.
Move to the next step. In step R56, register M T Ro's Pino) (
+1. ) is '1'. Bit (b,
J) If it is “1 pa,” as shown in Table 1,
The data is for flash photography, and this
Then move on to the R57 step. At the step of R57
is “0” (7 U) in bit (+12>) of register CFR.
/sh device (IIT) indicates that it can emit light (r signal)
Set. Here, register CFR, has the values shown in Table 7.
Data (CF3) is set. to the dog
, CFR3 biy) (b)) is 1” (auto dimming
Prohibited signals). The reason for prohibiting automatic dimming
, the meter (IV) uses the test light (i.e. automatic dimming).
For this measurement, measure the emitted light (when no
This is because the appropriate exposure value is calculated based on this. next
Set “1” to display register DPR (bff)
Set the condition to display that it is in 7-shot shooting mode.
state and r. At step R60, read the meter (J) and
Data for changing the amount of light emission): Register CFR, (
+3. ) to (b7) and control aperture value (AVDR).
Set to AV F R for 7-shot shooting.
The process moves to step 1 of R90 in FIG. At R90 step, when exposed from meter (1'/)
The time data (MTR,) is from the tuning limit exposure time Tvr2.
It's also a short second, but it's worth +1. here,
The exposure time data is shorter than the synchronization limit exposure time TyrV
If it is seconds, this limit exposure time Tvr1. control dew
Set the output time in the register TVCR and register RM.
(11) of Ro indicates that the control is not interlocked.
Set the number "1" and set the register D U' R (111,
), (b7) is set to “10” and overexposure is displayed.
Then, the process moves to step 96. -・way
, the exposure time data (MTR=) is the tuning limit exposure time T
If the time is longer than vrl, Kei #96's stage will be displayed.
to the top. In step #5G, register MTR. When (bo) is “0”, it is sent from the meter (IV), etc.
The exposure control data that has been used is data for natural light photography.
At), in this case, proceed to step #62. In step 62, the register CFR is
]:) to “1”. This is a certain amount of flash equipment
Even if it is possible to emit more than 7 lashes of light,
This is to prevent light from emitting. dog; this regis
TA CFR, (113) l ko “0” (self’Jh M light
(signal indicating that it is permissible to
register DPR to indicate that the shadow is done.
Beep) Set (b)) to '0'' and enter the ambient light shooting mode.
The state is set to display that it is. In step 65, "0" is set as the change data for the luminescence amount.
11” in register CFR, bits (b4) to ([17
) and proceed to step #95 in FIG. Then, in step #95, the frit value Av for 7 lashes is set.
Set f in register A V F R and proceed to step I96.
move to Now, returning to Figure 7, steps #24, 25, and 26
data from the meter (IV) and remote control A (V).
It was determined that the message had not been sent.
. In this case, in order to perform calculations based on photometric values from the camera,
Therefore, proceed to step #70. #70 step
, it is possible to determine whether a transliteration lens is attached.
Separately, if you are wearing VC, natural light photography based on open metering.
Exposure calculations are performed for both the
If not, use 7 for natural light photography based on embedded photometry.
Perform the exposure calculation for the shadow and step #75.
move to In step 7 of #75, the register FCR bin)
1 whether (b3) is “0”! Separate. Be “0”
A 7 runciever device compatible with the tobacco system is installed.
Therefore, Step 7 of #76 τ Renosta FOR
(bl) is "1" (charging completion signal is input)
It is determined by M whether the signal indicates here
, when it is determined that a charging completion signal is being input.
Since 7 shots will be taken, 7 shots will be taken.
embossed value Avr, embossed stage number A vf −A vo
c, exposure time Tvf is 1';A\'
D R, A XI CR, T V CRl: Setting L,
°Set bit C++i) of Nostar DPR to 1” to 7
Display that the 7k shooting will be performed and #6 mentioned above.
Move on to step 5. On the other hand, steps #75 and #76
・If the flash wt'A3 is not performed on the
In this case, the pattern for natural light photography is determined.
value Ava, number of aperture steps Ava-1 to VOC, during exposure
Between Tva and register respectively, to \7DRSAVCR, TV
Set the register DPR via ) (b3) to CR.
Set to 0" to indicate whether natural light photography is being done.
The process moves to step 65. In step I96 of FIG.
) register F in which data (FCO) is set
Check whether the CR bottle) (+13) is “0” or not.
1 to Yru. If Pino) (bz) is “1”, this system
It is a flash device that does not damage the stem, #101
In step , bit (1) of display register DPfl is set to 4.
), (b-2) Iko (Sat, 7 Ranon Yumark in Figure 2) (
55) ;Set the data “00” to light up #10
Move on to step 2. On the other hand, the bit of I'l'CR
If (I average) is 0”, next is the pin where the FCC signal is set.
)(+12) is "0". Here,
ノ) If (b, ) is 0”, mark (55) is 3Hz.
Point 2: To bits (b,) and (bs) of DPR,
is set to "01" and moves to #102. FCR's Bi
y) (Il?) is “1”, then the charging completion signal is
Set the contents of l” (Z R pinot) (b,) to 1
! If it is “0”, the DPR bin) (b, ), (b
s) to “00” and turn off the mark (55),
° If it is 1”, mark (55) is set to 2) (z to make it blink.
Set bits (13,) and (Its) of DPR to “10”.
Then, the process moves to step #102. In step #102, the exposure control operation has not yet started.
Since there is no register RM R,, (data (RMO)
Set “0” to Pino) (b4) of the register to be set.
Then, flash device (III) and lens wire (II)
Data (cFy) ~ (CF 3 ), (Shakuhachi 10) ~
(Proceed to the subroutine that transfers RM[3). this
The subroutine executes step 11 from step #180.
Now. Step #180 is compatible with this system
7 The Lanossie device arrives at the VC and registers FCR's bit/) [
Determine whether Itz) is 0". Here, Pip) (bu) is 7 that fits this system.
If the Lanoshu device is installed, it will be “0”.
Ru. Therefore, if it is 1, then it is 1, and for the receiver (fl),
To send an uncharged signal, the bits in register RMRO
Bit (b,) of FOR is set to 'O''. On the other hand, bit (b,) of FOR is set to 'O''.
, ) is 0", then bit (b,) of FOR is "1"
If it is “1”, it will send a signal that charging is complete.
In order to
However, if the charging completion signal is not input (if it does),
(bs) is set to “0”. Next, move to step #140 and connect the terminal (P,) to “
Hi8b” and connect the terminal (Plo) to T2 (for example, 1
00μ5ec) Output a “HigI+” pulse. child
The pulse is generated by the AND circuit (AND) and the NOR circuit (
NO, ), the signal line is connected through the transistor (Tr, 2).
Output on (8 guns,), 7 rough E/x! (D
I), the lens (II) receives data from the camera (I).
It becomes a mode where you sell 2 pieces of data. 1 large terminal (P,,)
By outputting "2-riHI+6" to the signal line (F
IO) becomes “)(iBb” and becomes a NAND circuit (N A
+), the AND circuit (AN,) becomes active, and the data
From the output terminal (Sou) through the AND circuit (AN-)
The output data is output from an AND circuit (A N s>,
circuit (N A +), transistor (T r+s),
Output to the signal line (ST2) via (Tr4t)
It becomes a state where At step #143, register ΔV
F R1,: Set 7-shot shooting control
Set the aperture value Avf in the serial input/output register rOH,
This data (equivalent to data (CFI)) is output in series.
Ru. Note that the data to be output in series is
After serial input/output and once set in register IOH, serial output is performed.
Powered. Next, in step #145, the focus of the lens is
' Distance data fv (corresponding to data (CF, )) in series
Output. At step #147 on the dog, register for display.
Set in bits (bo), (b, ), (+12) of data DPR.
The data of the exposure control mode that has been set is stored in the register CFR.
Set to 2 bi-nod (b.), (1+,), (+)Z)
Then, the film sensitivity data Sv is stored in the register CFR2.
Set this register CFR to 2 bits (+11) to (b7).
Outputs the contents of 2 (corresponding to data <CI'2) in series.
Ru. Next, register C is set with data (CF 3 ).
Output the contents of FR3. j2) The above data is sequentially 7
It is read into the file ¥c (1). Then the register
Outputs the data (RM,) set in RMR8 in series.
and then set the minimum exposure time TvMc (data (RM l
) is output in series. Next, the longest exposure time Tv
oc (equivalent to data (RM r )) is output in series,
Next, Tvf (! (data (RM
(equivalent to 3)) is output in series. And TSO Day
Output the data Sv (corresponding to the battery B514) in series.
The process moves to step 163. In step #163
The interchangeable lens (10) is installed in U 3, but what do you think?
If 211 is installed, #164 is installed.
If not, the process moves to step #168. Well 164
In the step, the maximum aperture value ΔvMc (data (RM5))
equivalent) in series. And the minimum fringe (lflA
voc (equivalent to data (RM 6)) is output in series,
At step 172, connect terminals (P,), (P,,);
Output “Low” and return to step #10・t.Meanwhile
, the interchangeable lens (10) is attached at step 163.
When it is determined that the data is not
5), output 0111″ as (RM6) and enter 172
Then, the process returns to step #104. The above de
The data (RMO) to (RM6) are read to the receiver (■).
be included. I104 de 1±Renostar A V D R! : set
The control threshold value (Baud) (P, ) to the display circuit (1'3
DP), and #105 sets it in register TV CR.
Display circuit (BDI') for displaying the set II + exposure time
In #106, register DPR1 is set.
Send display data such as mode to the display circuit (BDP),
Well 1071' is a circuit for displaying ISO data Sv (B D
P). Then interrupt with #108 Ste Knob
#10 allows receiving interrupt signals from terminal (itI)
Move to step 9. In step #109, the terminal (P,) is connected to Lou
+”.Here, check whether the terminal
The input level of (P o) is cashier, <- (II) force,
The photometric switch (Sl) is connected via signal lines (STs).
) is closed, "LOIIl" occurs. “L
ow'', perform operations from #2 to #108.
Set a timer to continue for a certain period of time (e.g. 15 seconds)
Start counting from the initial value and go to step #2.
Go back and repeat the same action. On the other hand, the terminal (PG) is “
If Higl+'', the timer is set in step #111.
Determine whether the count has ended and end
If not, return to step #2. After the photometry signal disappears or the photometry switch (Sl)
If a certain amount of time has passed since the was released, #112
Move to step. Automatic in steps after stirring 112
Stops the focus adjustment circuit (AFC) and closes the display register.
Set 00” to ([++), (b,) of Star DPR]
Set this data and transfer it from the display circuit (B) (P2) to the display circuit (B
DP) to turn off the flash mark (55)
. Also, it does not accept interrupt signals from the terminal (it+),
The interrupt signal from (ito) is accepted, and the terminal
(P,) and outputs “Higb” to the transistor (T).
rz) to stop supplying power from the power line (+Vl).
Then, the microcomputer (MC,...) stops operating. Preparations for exposure control on the microcomputer (MCo) have been completed, and
When the charging of the exposure control operation is completed, reset the switch.
($4) is released and the release button is pressed to the second step.
When pressed, switch (S2) closes and outputs 1+) to the terminal.
These interrupt signals are accepted, and the microcontroller (MCo) receives #
The operations from step 120 are performed. Also, the receiver
- Ishi line (ST,) from (II) is “L”
This movement can also be caused by the relay X signal caused by
The work is done. Note that the reset switch (S4) is
Output control rock (closed if sound churn is not completed)
Since the relay r switch (S2) is closed,
When the relay X signal υ is input, the AND rotation y11(A
Even if the output of No.
When the switch (S4) is closed, the NAND circuit
The output of (NA,) remains “Higb” and the terminal (it,
) do not input interrupt signals. First, in the #120 stem, the terminal (Pg) +
Output “iBI+” and set the signal line (C8F) to HiHI.
+” 13 to terminal CP +, ) at the step of Toshii 121
(e.g. 150 μsec) “)(iEh” pulse)
and then output “LoIu” to the terminal (P,).
Ru. This pulse is transmitted to the flash device (III) and the receiver.
- (II) is read and the exposure control operation is performed.
This happens at tq'7J11. In step #123, install the automatic focus adjustment circuit (A) on your dog.
FC) operation is stopped and controlled by the event counter EC○.
Regular refinement stage number data (AVCR) = (AVOR)
Avoc is set and the allocation by event counter ECO is performed.
In order to enable the
Output the route. This allows the release magnet to
The exposure control mechanism is unlocked and the exposure control mechanism is activated.
starts. In step 127, −゛・definite
Count the time above 〇, and when this count ends, the terminal
(P6) outputs a “Higl+” pulse and mirrors the mirror.
Make the net work. This causes the mirror to start rising and step #129.
Wait for a certain period of time and then count. 1+(1 time is
To embed the emblem + 5' from the open position to the minimum aperture position.
Corresponds to the best time required, 1. The mirror begins to rise.
This corresponds to the length of one temple required to complete the ascent. this
1. +1. In between, the crest is embossed in conjunction with the embossed movement of the crest.
A pulse is output from the pulse output circuit (FPG). This pulse axes the Q child (CKI) and counts the event.
The contents of the event counter ECO are
Rusu nails: This will continue to decrease. And event counter E
When the content of CO becomes “0”, the emblem will be at the desired embossed level.
I ended up being stuck in school for a few minutes. This will cause the event counter
Interrupted by printer ECO, step #137
, a pulse is output from the terminal (P,) and
The movement becomes unlatched. At step #129, [When the 1 hour count ends]
, when the control system set in register TVCR is output.
timer registers Tf and R, and connect the terminals (F7
) outputs a pulse. This allows the front curtain of the shank to
The run starts and step #132 is the actual exposure.
Count 2-T' for 1 hour, and
When the process is completed, a pulse is output to the terminal (P,) and the
The trailing curtain starts running. In this state, the trailing curtain cannot run.
Once completed, the reset switch (S,) is set to αI and the terminal is
Wait until (P2) becomes “Low”. And exposure system
When the operation is completed, the bit (b
, ) is set to '1'' to indicate that the exposure control operation has been performed.
Data (CF) is a state in which a signal indicating
, (RM), and then the previous
Proceed to step #109 above. In addition, the microcomputer
(hi C,, line (STO) from terminal (CKo)
P), automatic focusing circuit (AFC) and data
What is sent to the output circuit (SDO) is the Kijuku Kurotsuku
It's a pulse. The above is an explanation of the operation of the microcomputer (MC). Table 13 shows the Renos used in the operation explanation of the Myfun above.
Let's summarize the Noh of the flag. The dog is equipped with a light emission amount control circuit (F
The operation of LC) will be explained based on FIG. First, the analog output terminal (ANO) of the microcontroller (MC*)
) is the voltage that converted the ISO data Sv into an analog signal.
A pressure signal is output, and this signal is passed through the bar/7a (OA, ).
Then, it goes to the non-inverting input of the amplifier (OA,) and outputs J. There is a resistance between the two terminals of the amplifier (OA=) from the film surface.
A photodetector (PD) is installed to receive the reflected light from the subject.
This amplifier's (OA=) return path is filled with N number of compressed cotton.
A diode (Do) is provided. Therefore, an
(From OA-, [S
A voltage signal obtained by adding O sensitivity is output, and this output is used as a
The current is applied logarithmically by the resistor (T",.). At the time when the release operation starts, the output is output from the terminal (P,).
7 linops and 70 tubes (F F ,
) is seso) 3jt, the Q output becomes "Low". Then, when the X' contact (Sx) is closed, the 7
< II-f (for) starts emitting light, and the signal line (S
T,) decreases to ".LOLl+") to γ. Then the transistor (T
r,,6) becomes non-conductive and the output of the inverter (rN,)
(1'IC) becomes "Low".
The surface input of the road (N' Ot+) becomes "Lou+".
, the transistor (Tr, 1) becomes non-conductive. That is, X tangent
In response to the closure of point (S9), the transistor (Tr+u
) is multiplied by the capacitor (C211).
divided. And the rectangular value is the output of the constant voltage source (CE, )
(When Mr. Kotsuji says that the output of the comparator (A C+) is “H”
Is it a one-shot circuit (OS, ) by inverting iHl+″1?
A pulse is output. This pulse causes a 7A circuit (
A pulse of °'Lou+'' is output from NO3), and this pulse
During the pulse, transistor (Tr4□) h' conducts, and the signal line
A pulse for stopping light emission is output to the input (ST,).
. And the 72 noshi device (III) is in automatic dimming mode.
If it is, the light emission will stop due to this light emission stop signal V
Ru. Then, in order to start the running of the shank trailing curtain,
When a pulse is output from the child (P6), this pulse remains for a certain period of time.
Output at the desk delayed by the delay circuit (DL,)
Then, this pulse resets the 7 lip and 707 lip (FF,).
, ・The transistor (Tr, , ) becomes conductive and the capacitor is turned on.
(C: Integration of J is stopped and the cutting state is reached. The dog is given a t register based on Figures 9 to 14 -/?-(
■) Explain an example of just a sea lion. The f59 diagram is of Resino〈-
(This is a block diagram showing the δ configuration. (OSC) is an oscillator.
Yes, (DrV) is the clock pulse from the oscillator (OSC).
The reference clock pulses (φ, ), (φ,
), (φ3), and the frequency is φ1>φ2
〉φ. X connection from signal line (ST,)
The open signal at point (S x) is applied to the transistor (Tr, , ).
Therefore, it is detected and activated as a "High" light emission start signal.
The signal is input to the operation mode detection circuit (MODE). On the other hand, faith
The light emitted from line No. 48 (FST) is a transistor (
Detected by T “1°),” “Lou+” starts emitting light.
13"; 3 outputs to the signal line (ST,). The data from the signal line (ST2) is this data:
A transistor (Tr, , ) that turns 0N-OFF
The output is connected to an inverter (INo) that inverts the output.
data output circuit (DOP). Also read the data.
The data read by the reading circuit (DERE) is sent to the transformer.
given to the base of Tr, , (Trys)
It is output to the signal line (ST2). “HiFi” at Uni
When outputting No. 13 of “b”, use the tranno” star (Tr
lj), (Tr, -) become non-conductive, and the transistor
(Trz) and (TrlS) conduct, and the transistor (T
r, , ) are in a constant current driven state. -Power, “Lo”
When outputting No. 45 of u+'', the transistor (T
r, , ), (Tr, 6) becomes conductive, and (Tr, ', )
, (Trl,) are non-conductive. Therefore, “■,
“HiεII” is better when outputting the “OII+” signal.
The output impedance is lower than when outputting a signal (
It has become. Also, when not outputting data,
transistor (Tr, 6) conducts, (Tr, 3), (, Tr
, , ), (Trl5) are non-conductive, and camera =
Data exchange between F book (1) and 7-lanoshu device (1)
, and the data from the camera body (1) to the receiver (I[)-
It is designed not to give an evil 7-hairs' office when reading data.
Ru. The signal from the signal line (STY) is transmitted through a transistor (Tr
l,), the same (changed to location) by inverter (IN,)
operation mode detection circuit (MODE) and data output.
circuit (DOP) and data reading circuit (DERE)
Input. Exposure control ill fJ output circuit (CO3E)
A photometry start signal is output to the line (LMST),
This signal makes the transistors (Tr, , ) conductive,
This “Low” signal passes through the line (STs) to the camera.
The camera is sent to the main body (I) to prepare for camera exposure control.
starts. In addition, exposure control signal output circuit (CO3E)
The line (R1-ST) indicates the exposure control operation start point.
The signal (release signal) is output, and this signal triggers the trigger.
The transistor (Trl1) becomes conductive and this “Low” signal
The number is connected to the camera body (1) via the line (ST,)ffr.
The exposure control operation of the sent camera 11 starts. Part below
Figures 10-14; Based on this, explain the details of each block in Figure 9.
Explain an example. Figure 10 shows Kure II of the dynamic mode detection circuit (MODE).
-This is an example. This circuit is sent from line 13 (ST Yu).
(50, 100, 150μ5Ce)
) is detected, the camera's movement 1: mode is determined, and the recipe is
Determine the worker's work IY. 7 Ranoshiyu: W: (nT
) starts emitting light (S''
;J, , :I, not sent, transistor (Tr,
l) is non-conducting and the AND circuit (A N , , ) is active.
When , a pulse is sent to the believe line (ST,)
This pulse is transmitted by transistors (Tr, , ) and inverters.
Output from the AND circuit (AN I O) via (IN,)
Powered. This pulse HiH1+'' continues.
The reset state of the counter (CO,) is canceled while
The color/return (CO,) is the reference clock pulse (φ1).
Counter. Furthermore, the output from the AND circuit (AN+)
1 of t (φ1) in synchronization with the rise of the pulse.
The pulse for 7 minutes is output from the AND circuit (AN,,)
7 slots and 70 slots (FF) to (FF6) are set.
I can't see it. Tecorg (DE,) is a counter (CO,
): Outputs the ti number of &14. Table 14 Also, the AND circuit (A N l□) is fU Klein S
Reference tarot synchronized with the falling edge of the pulse from T,)
Outputs a pulse equivalent to one clock pulse (φ1).
The AND circuit (AN13) is the output of the AND circuit (AN, 2).
Outputs a pulse delayed by one clock from the input signal. Therefore, 50μ5ecll'j from the camera body (1)
The pulse is sent at the falling edge of this pulse (
Earth 7s, knobs, and 70 knobs (FF) are reset, (
Since FF, ,) is set to 7), the AND circuit (A
The pulse from the AND circuit (AN, .) is output from Nl,).
Forced 7 limp, 70 tube (F F ,), (F F
,) will be senotosareru. In addition, a pulse with a width of 100 μsec
is being sent, and at the falling edge of this pulse,
7 rip・70/b (F F )), (F F 4)
It has been reset and the AND circuit (AN+c)
The pulse from the circuit (ANl:) is output and 7 renobu・7
0 points (F F ,), (F F ,,,) are cents
It will be done. Furthermore, a pulse with a width of 150μSee is sent.
When the pulse of 70/70/p (F
F.). (F F ,) and (F F S) have been reset.
AND circuit (AN17) to AND circuit (AN,,
) is output, and 7 lip/70 pulse (F
F, 1) is reset. In this way, the turtle
The width of the pulse signal indicating the operating mode sent from the
7s, 7s, 707s (FF)) - (F F s)
) or (FF9) - (FF, , ) or (FF11) is set
will be cut. In addition, a clock for data transfer is connected to the signal line (ST).
When output, the width of the clock pulse is 30μSe
Since it is shorter than C, the pulse from the AND circuit (ANB)
is an AND circuit (A N + 5L (A N + 6) - (ΔN
17) is not output and H5T is not given for determination. So
Then, by the pulse from the AND circuit (A N +3)
7 lips, 70 pieces (FF3) ~ (F'F6)
Be sure to reset it. In addition, the inside of 180μScc
When a wide pulse is input, this pulse falls.
At the point when the decoder (DE+) output (eo) ~ (C
3) are all “Hi3b”, so it is 7. All flops and props (FF3) to (FF6) are reset.
The pulse from the AND circuit (ANl2)
What is output from (AN 1s) ~ (ANl,) is
do not have. 7 renobu・70 knob (FF, L (FF,) is set
When the circuit is turned on, first the terminal (FC) and the OR circuit (OR circuit) are connected.
,) becomes 'Hill-', and the counter (C
, 02) The cent state is released and the decoder (DE2
) becomes active. If the terminal (FC) is “Higl+”
Sometimes 7 ranosi 1 set rlL ([[) to the camera body (
1), the data (FCO) is sent to
The loop (φ1) is an AND circuit (AN,,), an inverter
Enter the counter (IN,) into the counter (CO2), and
) 1l(l[(kn+ to ++ to 2))
Decoder (DE2) terminals, ) to (C7) in order
Next, a "HIgl+" signal is output. Then, count the three clock pulses and set the counter (
The 4th bit (k3) of “HiFib” (CO2)
Then, the ()th clock falls and the reference clock
The AND circuit (AN
, , ) are output from the AND circuit (8N1.)
When the flip flop (F[',) is reset
As a result, the end P (FC) becomes "Lo...". This results in
AND circuit (A N = s) no small output MT) is “H”
i1. l+'' and is taken into the receiver (II).
data (MTO), (M T 1 ), (M
T 2 )l(to IT3) is output mode. Then, 4 bytes of data is output, and the above data (F
In addition to C (1), the counter (CO2) terminal (k5)
, (k4), (k,) becomes 101", the AND circuit
(AN22) output becomes “HiFi[+” and
The circuit (ANl9) outputs the output from the AND circuit (AN,3).
signal is output and the 7ri knob and 70 knob (FF,) are reset.
will be cut. As a result, the terminal (MT) becomes °'Lou+
” and the counter (CO2) is set.
Table 15 summarizes the operations at this time. Table, 15 7 lip/70 lip (FF,), (r F,,)
When CF is set, the terminal (CF) is set to ``High''.
data from camera (1) (CFO), (
CF1). (CF 2 ), (CF 3 ) are 7 units (I
II). And the counter (C02)
output<k,). When (k,) and (k3.) become “100”, the AND circuit
(The output of A N 2° becomes “Higl+”, and
The pulse from the circuit (AN1,) is sent to the AND circuit (AN2.
), and 7 lips and 70 lips (FF, ) are reset.
will be cut. This: Therefore, the terminal (CF) becomes “Low” and the
The output (RM) of the control circuit (AN26) is “Higb”.
data () from the camera (1) to the receiver (■).
RMO) to (RkiG) are read. stop
Then, (CFO) ~ (CF3) and (RMO) ~ (RM6
) When 11 bytes of data (including
Output of printer (CO2) (ka) - (ks) - (k4)l
(ks) becomes “1011”, and the AND circuit (A N
2. ) becomes ``High1+'' and the AND circuit (
The pulse from ANlz) is sent from the AND circuit (ANT+)
The output is 7 resops and 70 nbu (F F ,,) is rese 7
'The output (RM) of the AND circuit (t\N9.) is
“Lo”--The data reading operation stops. Write down this movement ('l:) in Table IG. Table 16 If 7s, 7p, 70p (FF, ,) are cent jx
In this case, the camera (I) performs an exposure control operation.
(at), the terminal (ES) becomes “High”. this condition
In this state, the trailing curtain completes running and the X contact (SX) is opened.
The transistor (Tr, , ) becomes non-conductive, and this transistor
The output of the input star (Tr) falls to "Low". Then, from the AND circuit (A N , ,), this falling
One clock pulse of the basic clock pulse is output in synchronization with the clock pulse.
Then, through the OR circuit (ORB), 7 rip and 70 rip (
F
The terminal (E S ) becomes “tIi g
II”, the counter (CO,) is reset.
The released force output (C○,) is the reference clock pulse (φ
1) Count. Then, for a certain period of time (for example, 5 seconds)
c), the output of the decoder (DE, ) becomes “Hi6”.
1+''. The 7linop props (FF, l) are reset. This counter (COs) is
F,,) is set and it stays at t times.
It is provided to prevent 7 rip and 707 b (F
After F aL (FF ILI) is set)
The output of the decoder (DEN) causes 7 limp.
・70, reset pu(FF,)-(FF,,,)
It would be better to do it before you do it. ':jS11 figure is meter
- ([V) Or harig!・, A/S7
) II Z 1 'y Q / vI
I As L call' /7
Infrared light transmitted data +: Data reading circuit to read
This is a specific example of (DERE). Also, Figure 12 shows the mail
(IV) or remote control, ＼(V) by infrared light.
A specific example of a data output circuit (DOP) that transmits data
can be,? Figure tS13 explains the operation of these circuits.
This is a time chart for 'js 11 figure smell
The signal received from the preamplifier (rrNM) in Figure 9 (corresponding to 0) is
When the second pulse is manually applied, the second pulse rises.
The pulse synchronized with the reference clock (φ1) is connected to the AND circuit.
Output from (AN3.) (13th FW), 7th linop
・70 knobs (FF,,,) are set (Fig. 13 β
1). 7 linops and 70 tubes (F F,,) are set.
When the output is “L our”, the counter (COs
) The state is canceled and the counter (COS) returns to its original value.
Start counting the quasi-clock (φ1). Then the terminal
(N,), (ffi,), 12. ), from (ff3)
(β2), (β,), (β,), (β,) in Figure 13
The first signal is output from the AND circuit (AN33).
The signal in Figure 3 (β,) is from the AND circuit (1\N32)
is the 13th FW (B,)'s iπ land h (: middle, powered and 7.
- The rising and falling point of the output of the second 7-V circuit (AN.)
te' is sent as shown in Figure 13 (d, o).
of (when No. 3 is 1", "!-1i61+"+"0
”, it becomes “Lou+”. Therefore, this
The rise of the output of the AND circuit (N33)
The output of the reamplifier (PΔM) is transferred to the shift register (SHR,
), the sent data ``1'' or ``0'' will be
It will be taken into the shift register (SHR,)
(Figure 13 (SHR)). Furthermore, the output of the AND circuit (AN, z) is “Lou+”
from the AND circuit (AN, , ) in synchronization with falling to
One clock of the reference clock pulse (φ,) is output.
, 7 linops and 70 tubes (F F ,,) have been reset.
The powers that be (COs) are resettled. and next
When data of bits is sent, 7 rip/7
0 knob (F F , 5) is set and the same operation as above is performed.
operation is performed and the dog bit data is transferred to the shift register.
(SHR,). On top of this: Strain and sequentially de
The data is captured bit by bit, (81TO), (
4-byte data of (MTl), (MT2)t(MT3)
When the data is loaded, the meter (■) or remote control is pressed again.
The same 4-byte data is sent from A(V) and B(VI).
It's coming. Therefore, the most recent shift register (SHR,)
The upper bit data is from the AND circuit (AN33).
At the rise of the output, it becomes D7 Linop/Fronob (DF9).
It is captured. Then, the shift register (SHR,)
Data input to the lowest focus and D7
(D F ,) + the imported data match.
What is different is determined by exclusive OR circuit (EO)
be done. In other words, the next same 4 bytes of data are read.
In the mouth, the previously loaded data is correctly loaded.
However, the first bit is stabbed all the time. By the way, the first 4 bytes of data are being read.
The terminal (Ill) of the counter (CO, ) is “Low” between
, and the AND circuit (AN36) becomes active.
The pulse from the AND circuit (lXN, 1) is
from the node circuit (A N 3J to the NOR circuit (>to,)
is given to the clock input terminal of the counter (Co,).
Therefore, in the end, the clock of 4 x 8 = 32 g is input as is.
do. And when 32 tarotsuku are counted, the end is
The child (1+,) becomes “Hilly” and the AND circuit (A
N++++) is in disabled state, (A N 3J is in active state)
Become. And the bit read by Moe and the year read
If the bits match, D7, 7, 70 (D
From the output of F9) and the least significant bit read once
Since the data do not match, an exclusive OR circuit (
The output of EO) is Higl+'' and the reAND circuit (AN3
The pulses from +) are counted by the counter (CQ, ).
It goes down. And if you have a 32-pinto...
The counter (Co,) counts 64 pulses.
Therefore, the terminal (11°) becomes "Hilly". Once all the data has been read, the data (M T O
) bits (t+,), (IIG) are 10", "11
．． ”. °Which of “00” is read is
Circuit (A N :l-,), (A N Js), (A
N zt) and whether any data has been read.
If so, the AND circuit (A N ij+(A N >j+(A
h+ B) One of them is "IIi, It'!-?-
n f7@IN(OV)tnshinh l+“Hi81+
”. In this state, the camera (1> and 7 Lanonyu (II)
I) Or send data to (U)
If not, the output of the 77 circuit (N('),,) will be "
This makes the AND circuit
(AN,,), the output of the OR circuit (OR,:) is “H”
igb'' and shifts to the shift register (Sl(R,)).
Loaded data (MTO) ~ (MT3)
It is preset to Ren'star (SHR2).
, the rise of the output of the AND circuit (AN, 1) is exposed.
Output 1i'l Connect the terminal (LS) to the H signal output circuit (CO8E).
) I will send a power bow instead. Furthermore, “[(iSb”) from the AND circuit (AN, 1)
(No. 3 is 7s/p 7 via OR circuit (○R, 2)
Sent to 0 knob (F F 16) 711 knob °70 knob
("Fl・) will be reset. This 7 linop・70 no
(F F , 6) is received from the preamplifier', PAM).
7s/bu/70/gote is sent when a signal is input.
゛Yes, this 7s/bu・70/pu(FF,,)kaQ
When the output becomes “HigI+”, the counter (C
O7) The 7-node state is divided by the angle T. Also, this
○ Output IJ transfers the agent (RCT) to π and sends it to the IS circuit (D'C
)P), and in order to prevent interference, the sending G is sent during reception.
It is used as a signal to stop. Please note that the camera
(1) and 7/shu device (III) or receiver.
(III) and the NOR circuit (
NO6)・, when the input is HiHt+''
Since the output of the NOR circuit (NO=) is °'Lou+''
The above operation is not performed, the data exchange is completed, and the Noah cycle is completed.
When the output of NOG becomes H1811'', the above data
Operations such as data presetting are performed. The data was not read correctly and the counter (Co,) terminal
(112) never becomes “HiHb”
or read the signal from the receiver in the pond and collect the data.
(\ITO) and node (1 core), (bG) is “01”
becomes r:, then the output of the AND circuit (AN41)
is “Low”. In this case, 7 resop 70
Reset state when Tsubu (FF16) performs cent J
The counter (CO6) that is cleared becomes valid. Reset
The data on the pan will be read from the moment the auto state is released.
In rare cases, data is being exchanged with the camera.
After sufficient time has elapsed to prepare for
The output of the counter (CO6) becomes “trich” and becomes 7
Lip 70 knobs (F F , , ) are set. vinegar
At this time, data is not being exchanged with the camera.
If not, the output power of the AND circuit (A N , , ) is t″High
l+” and data i? is being received again.
When the operation (1:) is completed, the AND circuit (AN4o) outputs
becomes "HiHb", and the output of the OR circuit (OR12) becomes "
Hi and II”. By this, 7 renobu and 70tsu
The counter (t” r;”,,) is reset.
COcL7 Renobu 70/Bu (FF,,). The power output (CO,) is reset and returns to the initial state. By the way, this easy-to-understand 1.
2) It is not necessary to transfer the data to Moe's data.
It remains as it is, and Hi to the end f (LS)
The rising signal of ``HI+'' is not transmitted.
When the MT) becomes “HiBb”, the AND circuit (7\n4
4□). (A N , 3), (A N , ,) become active.
, the data imported into Sea Train Star (SHR2)
Camera Honjo (I) is in the state of transmitting. And the first
From the line <S T , ) in Figure 9 to the transistor (Tr,
), the inverter (iNz) is π and the input clock is
The clock is output from the AND circuit (AN4+), and this clock is output from the AND circuit (AN4+).
After that, the shift register (Sl-
Data is output from the IR- output terminal (S○(1) to each pin one by one.
data will be output. This data is input to the input terminal (SIN).
The signal is sent to the shift register (SH) at the falling edge of the clock.
R:) is read again. This is the following data jL output
There are many cases where new data for
, Repeatedly send the same data to camera book 1 (to send it to IE)
be. Furthermore, the data from the output of the shift register (SI-tR,)
If the data is “)Ii61+” then the AND circuit ()\N, 2)
output is 'High', AND circuit (ANI+)
The output of is Ill, oIIIN, and the output is Ill and oIIIN.
(T1.), (Trll) goes through, ° “To1ight”
A signal is sent to the °f signal line (ST). - The output of the shift register (S) JR,) is “LO field”.
Now 7 circuit (A bl , -1), river) 11
The output of y"T, +++++"-/8M,-'1 is "
HiH1+'', and the transistor (Tr1=)-(
Tr, , ) conducts, and the “Low” signal power 1 (=signal
2 in (SI2). The above explanation is the meter
- (■), remote control l\(VLB (■) to infrared light
Read the data and insert this data into the camera book 1ts (1).
This is the action of sending data. Explain to your dog the common example of the data output circuit (DOP) in Figure 12.
6 cameras that illuminate the receiver (II)
The data to be sent (RMO) to (RM6) are connected to the signal line (S
Tz), first, the operation mode detection circuit (
MODE) terminal (RM) becomes ``Higl+''.
, AND circuits (l to N9.) become active. Koto
from the signal line (ST,) to the trunk (Tr, ,
). For data transfer that generates and inputs the inverter (IN2)
The clock is an AND circuit (ANS+), an OR circuit (OR1)
6) Tarot of shift register (S[-[R3)
Input to the input terminals (C, K). At this time, 7 linops
The 70 knob (FF2.) has been reset, so it is
The code circuit (ANs2) is in the active state9, so
, from the Ishi Line (SI2) to the Tranzosta (T "1°
). Data (RM
O) ~ (16 to R) is an AND circuit (AtJs=), or
Shift Renosph (SHRj) via circuit (OR+6)
input to the data input terminal (SIN) of these days
The data is shifted in synchronization with the falling edge of the input signal.
(SHR3). All data (RMO) to (RM6) have been imported.
Then, the terminal (RM) becomes “L aw” and 77 circuits (N
Olo) yells “'Higl+”. Then, at this time
Detects operation mode if receiver (If) is not receiving data
The terminal ('RCT) of the circuit (Mol)E) is “Loll
” Therefore, from the AND circuit (ANsu), 77 circuits (N0
1 of the reference pulse (φ1) in synchronization with the rising edge of
A clock pulse is output (Fig. 13 (ff,)
). And with this pulse, 7, 7, 70 Tsubu (F F
2. ) is sent (Figure 13 (α5)), and the counter (
CO, , ) is released from the reset state, and the AND circuit (A
N53) becomes active. Note that the terminal (RM) is “L”
ou+'', the receiver (II) is receiving
, if the terminal (RCT) is “+11g11”, it is a NOR circuit (
No, , ) output remains 'Lou+'' and reception
ended and became Zu1zko (RCT)hi “Lou+”
Somewhere there is a NOR circuit (No, ,);'> output is “HiH”
When the reset state of the counter (CO, , ) is released, the counter
The counter (CO,,,) receives the reference clock pulse (φl).
Count. Then, from the terminal (ql), there is a signal for the carrier wave.
A high frequency clock pulse is output. In addition, the terminal (q
2) From ~(q,), CC in Figure 13! o)～(αko)
The clock pulse of is output, and the AND circuit (AN, 9>
The pulse (α8) in the m13 diagram is output from the or
Shift Renosph (SHR3G) via circuit (ORIS)
is applied to the clock input terminal (CK) of . this shift
Renosuf (SHR,) has data at the falling edge of the clock i).
Data is taken in and data is output at the rising edge.
It has become. Therefore, Schif'trenosta (SHR,)
The signal shown in FIG. 13(a) is output from the circuit. this
In the example, the data is output as ``1011...''
ing. Furthermore, from the NAND circuit (NA, ), Figure 13 (α7)
The signal in FIG. 13 (α,
) signal is output. These signals (α,). As is clear from Fig. 13, (α7) is the terminal (q3).
), which corresponds to one clock cycle and three clock cycles.
``1'' and 0'' are distinguished by the difference between them.Then, the shift register (SHR3) outputs a 0'' signal.
When output, the width from the AND circuit (AN5-),
'rJ, Iharus (a6) is an AND circuit (l~N5t)
, is output via the OR circuit (OR17), and a 1” signal is output.
When is output, the width change from the NAND circuit (NAa)
The pulse (α,) is an AND circuit (ANzaL OR circuit (O
fJ is output from R17) (Fig. 13 (α, , )). The output from this OR circuit (() le 1+) and the terminal (
The carrier wave clock pulse from the AND circuit (l
XNs+) is sent to the transistor (Tr, ), and the red
The external light emitting diode (OULo) is based on this signal.
blinks. Furthermore, as shown in Fig. 13, the receiving
On the fg side, as soon as two cycles of (β,) are completed,
Then, at the end of the second period (α1), the received Zugo issue is “
"°0" because "Tol1H1+" is determining the
If it is “Low”, if it is 1, it is definitely “HiHb”
This allows for accurate data exchange. Receiver (II) sends the same data twice f5
Shift Renosuf (S HRd to
The output data is sent to the AND circuit (AN, J) again. Through the OR circuit (OR+6), the fall of black and 7
It is imported by And (RMO) ~ (RM6)
If the data is sent twice (8X7X2=112 bits, 7 bits)
), terminal (q,), (q7), (q6) (terminal (q
6) is the bit 4 bits higher than the terminal (q5))
are all “HiH1+” and the AND circuit () ~ N,
,,) output becomes “Hi61+” and becomes 7 linops/70 ts.
The counters (FF,...) are reset and the counters (CO1=
) #J lyse/T state: Returns to the initial state. More than
Sending data f! This is an explanation. The exposure control signal output circuit (CO3
The operation of E) will be explained. Data reception completed successfully
and the terminal (LS) of the data reading circuit (DERE)
The pulse of "Hi Bi 11" is "input"
0 knob (F F 23) is set. And this 7
Rise of the Q output of the lip 70 pump (F "2p):
3 clots with 2 brains and 1.20 tsuku pulses (φ2) per 2 branches
A black pulse is output from the AND circuit (ANa+)
. At this time, the end "r-" of the data reading circuit (DIERE)
(d,), (d2), (C'3) Karano channel signal
(MTO b , , b , , b s ) and the recipe
Channel data output means (CH3) of server (n)
If the data match, the comparator circuit (COP) outputs
The output of the Riore circuit (OR2°) when the force is Hiε11″′
becomes “Higl+”. Also, specify the meeting channel.
To do this, (cl+L(dz)+(dco) is '111'
When , the output of the AND circuit (A N so) is
When it becomes “High”, the OR circuit (OR2,,)
The output becomes "Higb". The test light emission I= signal is input, and the terminal (d,) is “I-l-”.
If it is 1i+″′, from the AND circuit (AN62)
OR circuit (OR, l) and AND circuit (AN,,)
Pulses from are output. This pulse causes 7 litho
The 70 knob (FF,...) is set and the counter
(CO15) The glue seven throat state is released. At this time,
Camera book 1 yen - (I) is not in exposure control mode and is in operation mode.
The terminal (ES) of the mode detection circuit (SiODE) is LOIII
', then from the AND circuit (AN7.), the 7th knob
・“l (high”) signal of Q output of 70/B (FF, 4)
hl is output, and this is transmitted through the signal line (FST).
The trunk is sent to ``rr+o'' in Figure 9.
It has been a while (Tr,,) has been guided by this "HiFiI+" signal 3.
Through this, the signal line (ST,) becomes Low'', and this
The 7th and 7th Shini (III) performs a test flash. Light reception
element (SLP) and 7'7' (SLAM) are the other 7
Detects the rise of the light emission of the
Output the route. This pulse is output via the OR circuit <OR2+).
The beam has 7 lips and 70 pieces (F F ;+).
, the same as above and a flash mounted on this receiver.
make the flash device emit light. Start emitting light and wait for a certain period of time
When the counter (Co, , ) output becomes “Higb”
Nari 7 Rip 70 Knob (F [”,) is reset
The initial state fil is returned. The output of the OR circuit (OR2o) becomes “)IiEI+”
And from the AND circuit (ANa-), the AND circuit (AN61
) is output and the 7 limp/70 knob (FF=
s) is set. This allows the counter (COlG
) is released from the reset state and the counter (Co,,) returns to its original value.
Start counting the quasi-a count pulses (φyu). Then, for a certain period of time (the camera body (I) is the type for exposure control;
Sufficient time to complete the operation, i.e. the microcomputer (MC)
An interrupt is applied to the terminal (iLJ) of (,,), and from (ill)
(sufficient time to be able to accept interrupt signals)
When the output of the AND circuit (A N , G) becomes “HiHI”
+″′.At this time, IPJ shooting mode is specified.
If the terminal (d,) is “Higl+”, the AND circuit (AN6
t) becomes “'HiHI+”, and the OR circuit (OR
, , ) through the believe line (RLST) f:rS9
The trunk shown in the figure (Tr+s) is crossed. Tiger
The signal line is
(ST,) is “Lour” and recamera Kimoto (1) dew
The output control operation is started. Furthermore, after the same fixed period of time has elapsed, the AND circuit (l~NG
The output of s) becomes “HigI+” and the output is 7 and 70.
The counter (FF2.) is reset and the counter (CO+=
) is in the reset state (this means -2, AND circuit (A
N6G) output becomes “Low” and the release signal is
In addition, when continuous shooting mode is specified, the terminal (d,)
is “LOIll”, so from the AND circuit (AN66)
“Higl+” signal is from AND circuit (ANGs)
Output and 7 linop/70 tube CFFQG) are set.
Then, a release signal is output. This signal is a counter
(CO2G) continues to be output even after entering the reset state
, the camera body (1) is used to control winding exposure (R's turn).
An exposure control operation is performed each time the exposure is completed. This closes the switch (S4) on the camera body.
Each time, the exposure control operation is turned and the film is advanced.
All you need to do is install a motor drive. And then
Data is sent again from remote controllers A (V) and B (■).
Then, the output of the OR circuit (OR2,) or “)IigI+”
Then, the pulse from the AND circuit (AN, , ) is
It is output from the ring circuit (AN, ,) and has 7 rip/7 taps.
(F F 26) is reset and the release signal is sent.
will no longer occur. Therefore, when in continuous shooting mode, the release
If you output No. 13 for the camera from the remote control, the camera will shoot continuously.
Shadow operation starts and continuous shooting occurs with the second release signal
The operation will stop. In addition, the pulse from the AND circuit (AN, , ) is
・70 knob (FF, 7) is sent to 7 linop ・70 knob
(FF2.) and reset the counter (CO,,).
・Divide n1 state by n7 and convert it to katsunta (CO7).
The lock pulse (φ3) is counted one row. stop
Based on the output (q, =) of the kafunta (Co, ,),
Transistor (Tro) is ON-〇FFL, data is normal.
The two photodiodes (CI-I L
) will be displayed. In addition, after a certain period of time, 7'J
Knob 70 (FF2.) is reset and the display remains unchanged.
F-light. Also, 7 linops and 70 knobs (F F 2.)
The Q output of (Figure 9 through line 3 (LMST)
Transistor (Trz) is sent and transistor ('
rr+'+) becomes conductive. This allows the signal line (
STs) becomes “Low” and camera Honjo (f) interrupts.
The 1-inclusive signal is input to the terminal (iLg') and exposure control is prepared.
The operation starts and the read data (R!vl O)~(
RM6) into the camera book 14C(1).
It will be done. The above is the explanation of the receiver (II). To the dog, Figure 15, 16 (7I, Figure 17)
・Illustrated explanation of the 7-runchie device (1). ;lS
The IJ diagram shows the charging status monitor circuit (C1 (∆)) and charging
This is a specific example of a state production circuit (CHD). monitor times
(CHM) is connected in parallel to the main capacitor (to 4C)
J2 k resistor (R,), (R2), (R,) direct
The output terminal of the variable resistor (R2) is connected to the column circuit.
-(cr-r,) charges the main capacitor (MC).
A voltage corresponding to the electric voltage i,2 is output. This output is
Dividing the power line (VF) with resistors (R,) and (R1)
The reference voltage is compared with the frequency converter (ACs).
If the voltage is higher than the charging completion signal social 'Higb'
The signal is output to terminal: (CH2). Also, this charging
The transistor (Tr, ) in Figure 5 is completed by the completion symbol.
Continuity is established and the light emitting diode (LD) lights up. Furthermore, the reference voltage is also changed by resistors (R7) and (R8).
This voltage is applied to resistors (R4) and (R1).
The voltage is higher than the current voltage. And i': W child (
The voltage of CH,) is this resistance 1:R2)I(R*):Kyo
When the voltage turns, the comparator (AC6
) becomes “T1i61+”, and the output of the transistor (T
rs2) becomes conductive and the resistor (R3) becomes the resistor (-Re).
Connect in parallel. This causes the reference voltage to drop
. However, the base voltage in this case is also the resistance (R,), (R5
) is higher than the base voltage at the connection point. Also, the comparator
When the output of (AC,) becomes Hight+”, the AND rotation occurs.
The output of ANtl is “Lour” even if 7 linops and 70 tubes (FF, .) are in the form of seven nodes, and the output is
The resistor (Tri:+) becomes non-conductive and the external pressure as shown in Figure 5
The operation of the circuit (DD) stops. And the main conde
The charging voltage of the sensor (MC) decreases due to discharge.
And the output of the comparator (AC6) is again °'Low"
Just then, the pressure is again DU 3. ft, 7, 7
・As long as the 70 knob (FF, .) is set, the main
The charging voltage of the capacitor is charged from the terminal T-(CH,).
The completion signal is held in a state higher than the output voltage, resulting in waste.
Unfortunately, normal movement is not possible. Also, if a pulse is input from line 13 (STJ),
, this pulse is applied to the transistor (Tr=,), in(−
ritr\I-, 1f-41f middle/h2. ↓1 ”'p
11 ,, Save+pu(FF,,) is sent,
The counter (CO) is reset. Therefore, the force
Counter (CO,,,) is 1, ;' Sub line (STz)
The count starts from the initial layer state every time a pulse is input from
Is it possible that data exchange is no longer being carried out?
and constant n: ″r (DIJ, L=3+n1n) is counted.
It will be done. Then, the certain time count ends.
Then, the carry-me interval (C'l''', n, et al. pulses are
Output, 7 limbs, 70. Bu(FF,,,)garise
The reference clock is output through the AND circuit (A: LB;
clock (φF) is no longer input to the counter (CO2,)
, Furthermore, the AND circuit (1~'1.1) is a humparator (
The external pressure movement of the external pressure circuit (DD) is independent of the output of ΔCe).
1 stop. To restart sweat pressure movement 1, camera <1) ball j;
Restart l'j and output a pulse to end 7- (STJ)
If you do it like this, 7 linops and 70 knobs (FF...
, ) is set and the external pressure is resumed. In addition, the door is shown in the illustration.
However, open the power switch (MSFL) in the f:rS5 diagram.
When the power-on reset circuit
70 knobs (FF,,,) + seven knobs, power white rC
O2,, ); ') and turn on the power switch (MSr
After configuring ``L), pressure is always applied to the lips for a certain period of time.
It is necessary to rub. In addition, Bousossus
Inch f: Provided, when this button switch is pressed
Also, if you have 7 resop 7 ronob (FF'iu)
, by resetting the counter (CO, ,), the external pressure is
After it has stopped, separate the 7lassociu from the camera (1).
Depending on where it is used, the pressure may be restarted.
stomach. Power switch (hisFL) as explained here
If the camera (1) is closed, the camera (1) will
Pressure is carried out. Then, as explained in Figure 9,
When data is sent from the controller or remote controller, the receiver
Since this always causes the camera to move, 7 ranosyu (I
The external pressure at [I] will also start, and eventually the meter and
Sweat pressure movement of ([[)] can also be controlled from the remote controller.
Therefore, 7 ranonyu ([If you do not use >
has the effect of not saving electricity costs due to unnecessary promotions.
. Figure 16 shows the components of the 7-7 control circuit (FLCC) (this example).
There is a control circuit (FLCC) in Figure 17.
70- indicates the behavior of the microcomputer (ICF) that has been lost <1i
It's Chato. fJ line (S T 2), (S T
3) The transistor circuit directly connected to
It has the same configuration as the direction path of bar ("). Also, (S
It is necessary to output a signal from the flash (I[I) to T,).
Only the input transistor (Trzl) is connected.
It is continued. (MODE) is the movement of receiver (II).
This is the same circuit as the operation mode detection circuit, and a specific example is fjS1.
It is shown in Figure 0. First, a pulse with a width of 50μSee from the signal line (ST,)
is input to the operating mode detection circuit (MODE) terminal (I
'C) becomes "Higl+", AND circuit (A N
ta) ~ (A N go) becomes active, and
The circuit (ANsl) becomes disabled. In addition, data exchange
is not performed, the AND circuit CAN-,) is
Work. The state is 7 linop prop (F F,,
> has been reset, so the charging status detection circuit (CHD)
) “HiHb” charging completion signal from the terminal (CH2)
If input, AND circuit (AN, zL off circuit (OR,
. ), the output of the AND circuit (ANtc) is “Higl+”
The transistor (Tr, 5) becomes conductive and becomes “High.”
'' signal is output to the signal line (ST, ).On the other hand,
The charging is not completed and the terminal (CI-12) is “L” (111).
1", the transistors (Tr, , ) are conductive and the state is "Lo".
No. 18 of “OFF” is output to the signal line (ST2).
Operation mode detection circuit (MOD E) terminal (FC) 7
5"HiH1+"L2, 2te δ drop, J) or "I(
iBb'', the output of the AND circuit (A N , a)
becomes “High” and this signal goes to line (ST2) i
This is the data (FC(1) bit (
1". ) (power ON signal). When the dog becomes the terminal (“1”) or “HiHIt”, the AND circuit is activated.
Outputs the signal from the terminal (CH2) from (,\n4・,).
(b,>(indicator indicating charging status) of (FC○)
1" on the number). At this timing, the signal line
The signal output to (ST,) is the transistor (Tr,
)), D7 Resop 7 via inverter (Ding N21)
0/B (DF17). This is a lamp case.
Connect multiple 7-layer modules using cable connectors.
When it is 1, one of these 7 u/shu is t1 riraiji
It was finished. This is because it is better not to emit light. That's a tiger
When the transistor (Tr3.) becomes conductive, this transistor (
Try,) against (Snake's 72/Nyu's 1 range
The output current of (T rss) flows into C and eventually becomes a signal.
Signal 3 of “LOIII” is output to the signal line (ST, ).
i″L. And D7 Resop 70 knob (DF,,)
"Low" signal is taken in. Therefore, multiple lights are closed.
If at least one battery is not fully charged at the time of shooting, the camera (
Since the charging completion signal is not input to I), the camera (I)
Photographed using natural light, 7 rays, (tlI) is D7 lithography.
The ζ output of the 70 knob ([')F,,) is "Laul+"
'', so the 7-laser light is not emitted. When the terminal (f2) becomes "I (high"), the 7-ray knob/70
/B (F F 3.) ζ output is AND circuit (AN, +
, , , ) and output to (H(STY)).
It will be done. The second fL; is within a certain period of time after the start of light emission.
FDC (No. 9
It is. If the light emission stop signal is not input, turn the knob 70.
/ FF3.
Q output indicating that the 7-ranoshu shooting was not performed.
One signal of "l-1iBI+" is received from the terminal. On the other hand, when the light emission stop signal is input,
x) is opened and for a certain period of time, 7s 7bu, 70tsubu (
F F sl) is sent, and your output Lou+
” signal is output, and the proper exposure is taken.
This is a signal indicating that something has been done. Terminals (f3) to (f7
) is not connected anywhere, and via 1・(+33)~(
b7) outputs a “Low” signal as described above.
, (b3) is the camera body (1) that is compatible with the system.
It is used depending on whether it is used or not. 100/J 5e from signal line (S T 3) to dog
If the cljl pulse is manually generated, the dynamic mode will be detected.
The terminal (CF) of the line (λ10DE) becomes “f-right”.
The output of the inverter (IN=3) becomes Lou+''.
Become. As a result, the AND circuit <A N 76) + (
The output of A N 77) goes low and is in trouble.
Both transistors (T r-1) and (T ras) are non-conducting.
Become a connoisseur. Therefore, the data from the signal line (ST2)
Transistor (Tr=v) l Inverter (IN2.)
It will be in a state where it is read after 2 years. In addition, Inba-ri (I
When the output of Nri falls to "'Lou+", the microcontroller
Interruption of (CF) 59-(! L-,)
Iwa "j included fS" is input, and the microcomputer (MCF) is the 17th
The operation shown in FIG. 1 is performed. Below, the microcomputer is based on the 70-chart in Figure 17).
(MCF) operation will be explained. Power line (\7p)?
When the power supply starts, the microcontroller (rtICF)
Start operation from step. In step ■, the board
From the data output circuit (AMD> input to the gate (P5)
Import data on automatic light adjustment or luminous intensity
~M Set to R. Here, set to Pask AMR.
The relationship between the data displayed, the amount of light emitted, and the output of the decoder (DEN)
Table 17 shows the details. Table 17 *...11 , 'L Either is fine.
Table 17

[As shown here, -3,0 IEV is approximately 1
In order to reduce the amount of emitted XS by increasing the
Tr,i,) becomes conductive, and at the same time as the output IQ, the transistor (
TrcG) becomes non-conductive, and the voltage charged to the capacitor → t' (C+U) by increasing the resistance (R, ,) is the voltage determined by the constant current source (cr, , ) and the resistor (R, 7). When the value exceeds this value, the output of the frequency converter (ACs) is reversed and light emission is stopped. That is, 3EV5>light emission amount for all light emission;, I4
The light emitting time required to make it less is counted and is. Therefore, depending on the output of the decoder (DE,), the resistor (R
,,) -(R,,) and capacitors (C go1- and'>
5: The L setting changes, thereby controlling the light emission time to obtain the desired amount of light emission. In addition, when the full light is emitted, the output of the decoder (DES) is “I(i,;I
At "t", the transistors (T",.) to (Trai) are all in low conduction, and the gate electrodes (l to C'l) are completely closed. C1 is stopped (No. 8 is not output. Data from the output circuit (AMD) is shown in Table 18.
1 is shown below. Table 18 Return to the flowchart in Figure 17,
44. to the data read from Pau) 1:1m',).
11 to determine whether it is in automatic light control mode. If it is automatic light adjustment mode, set 111° in the lens register AMR to set the full range mode, and then move to step (■).If it is not automatic light adjustment mode, register ~MR
Leave the contents as they are and move on to step ■. In step (2), the light emission amount data of the register AMR is output to Baud) (P,), and then the terminal (P,.) is set to "Lo..." so that automatic light adjustment is not performed, and the light emission is stopped. In order to avoid being blocked, set the terminal (P21> to ".lTi6!+" and proceed to step (■). In step (■), set the light emission amount data (AMR) and blank display data in the display register DPR. , dog i,
, :Blank display data is also set in the display nostars DPR, -DPR, and a signal based on the data in the registers DPR, . . . -DPR, is sent to the display section (FDP). Therefore, when the power switch (MSFL) is closed, r:r
Only M A N U and light emission amount data are displayed on the display section in FIG. S2. And a microcomputer (? = iC
F) can accept an interrupt signal to the interrupt terminal (its) t(its), and has a 7-lag CE r'
ff function (described later) is reset and the operation is completed. Operation mode detection circuit (h, for) E) terminal (CF)
When the signal becomes "Higl+" and the interrupt terminal (its)'+ here is input, the microcomputer (MCF) starts operation from step (2). First, in step (2), data (CFO) input to the data input terminal (SIN) is read into the register IOR based on the falling edge of the clock pulse input to the terminal (CKI). This data is then set in register APR. This data (CFO) is
This is the control threshold value data for shooting γ. At step O, the next data (CF, ) is read and set in the register FFR. This data is the previous person χ distance data rv7' of the interchangeable lens as described above. In the incorporated data (CF2), the lower 3 bits are the camera's exposure control mode data, and the upper 5 bits are the film sensitivity S■ data. Then, the mode data is set in the register MFR, and the 7-ilm sensitivity data is set in the register SFR. Next-2 Data to read (CF 3
) is data from the meter and remote control, and this data is set in register FMR. The reading of data is completed on j, but the details of these data are already explained in Table 7.8. In step O, it is determined whether the register F M Ri:3 is set to 1! q separate. If the value is 1", the data for the meter and remote control will be sent from step 8 to 1". Proceed with the operation in which /sh does not emit light.In step O, set the degree to i (via of unnecessary renostar DPR,) [1+o),
Set the contents of the register (MFR) in which the camera's exposure control mode is set in (1) to (1), and (1)
), 1) to (+37) are set with blank display data. Okay! (Unused Renostar DPR, rS from the camera
0 data to DI) R2 is set to the control print value for 7-degree shooting from the camera, and DPR3°DPfl is set to data for blank display. Then, set the 7-lag CEF to “0” and connect the terminals (P, , ) to “I-, 'Tl-1/M width, 7.74:jH1-bJ,
The functions of the display register are shown below as we move on to step -rh. Table 19 If the fold stop signal is not input to the IR bit (!G) to the lane star F at the step O, then the via (1+, , ) of the D PR is set to 0 at the step O. Set A h
I Dr is made not to be displayed, and the terminal (P2.) is set to "Hi to l+" to enable light emission, and the process moves to step O. In step O, Renopasta F
1! distinguishes whether the bit (b) of M R is 0".Here, if it is "1", the meter (■) or...
This is a case where 7 flash FW and 'iil control data for A5 are sent from remote control A (V), and in this case, automatic light adjustment is not performed at the time of test flashing. There, in steps 6 and 9, connect the terminal (p 20) to Lo.
w" to prevent automatic light adjustment. In step O, set the 7-lag CEF to "1". The second 7-lag CEF is set to the meter (IV) or remote control A (
If the light emission amount is set based on data from V), it will be °'1'', and if the light emission amount is not set, it will be '0.
In step O, the constant light amount data from Baud) (P, ) is set to the lens star AMR, and the data obtained from =λ is set in the automatic light control mode "Q 11 Q". If there is, set the data for full light emission in the monitor AMR, and if it is not automatic mode, leave the data as is and move on to step ○.Step O is the register FMH bin) ( b,) is “0”, it is different from 1 to 1, and if it is “0”, the light emission amount is decreased, and (137) to (b
Reduce the data in 5) from the setting data (, 1iR). If this result is smaller than "°001", "001" is stored in register A MR! , : Set and move to step 7 of (). On the other hand, if (bt) is 1゜ in 6 steps of (G), the light emission amount is to be increased. Add the data and this result is “
If it exceeds 111”, step O: Shift to 6
At step 0, register \M I', 7. D
The light emission amount data Iv is selected based on the data, and rv15v-r~v'':Dv is calculated from this constant light amount data Iv, the camera's ■SQday V, and the fringe value data Av. , set this data Dv in the current DPR, so that the photographing distance that produces appropriate fog light is displayed, set blank display data in the display register DPR3, and move to step O. In the O step, Shinyumi, who plays automatic key 7e near stop,
If 7 items have not been entered, proceed to step O. In step O, data from dζ-)(P,) is set in register AMR. In this case, exposure control is performed without any waste on the data from the 7 part (IV) or the remote control l\(V), so the 7 lag CE "
is set to "0".Then, in the step O, it is determined whether or not the automatic light control mode is set.If the automatic light control mode is not set, the terminal (P2.) is set to "Lt+u+".
B Register A M F? The content of is outputted to the boat (P,), and the process moves to step 7 of O described in step 111j to display the image forming/jI that will give the proper exposure. -Power, O's status,
7p/self fJJ 174-')'6 Mort'”
C'+? ) Le:: Toh' N Another 3 Relto'1
The m child (P 211 ) is set as "'Hi61+" and the process moves to step O. ○v') Step 1 is calculated based on the maximum light intensity IVMI, and the best result is correct exposure! T, m, 5 distance i': iCD ¥) Calculate i and set it in register DPR. Okay, at step O, the minimum light emission amount I'do: Ivo+5 for two units
v-Av=Dv. The shortest photographing distance r2:Dv for proper exposure is calculated.
. is calculated and set in register DPR. Step ゛ of O is; bit (b7) of pasta D, PR, , (), (+16) ~ (1+,)
'-Nirenosk1\M The contents of R are (+13) ~ (b,
) to set the contents of MFR. Main, register SF
The content of R becomes DI'R, and the content of A PR becomes PR2.
Set to . Then reset the internal timer and enable timer interrupts.
Assume that it is possible to interrupt (iL,)t(il,c).・1
The display is based on the data from the camera.
To indicate that
Contents of R: The microcomputer (M
CF) has 17 stops per day. In Fig. 16, the terminal of the microcomputer (1 cF) - (
il6)2-]]i! *'''5-hy-bui,,,J/
Qcw+=/-IIII+r710'-(AMD) is a switch that is closed when a change in data is made. When the switch (SS) is closed, an interrupt is applied to the terminal tJ, and the microcomputer (MCI') performs operations from step O. Step ○ is 1 to check whether the 7-lag CCF is “0” or not.
If the value is not "0", the display state is not based on the data from the camera (1), and in this case, the process moves to step (3). If it is determined in step O that the 7-lag CCF is "0", a display based on the data from the camera (1) will be performed, and the process will proceed to step O. In step O, the lens ' It is determined whether the bit (b2) of the star FMH is "0". This is to determine whether the non-emission mode is set.
'1'' and is in non-emission mode, there is no setting of the emission amount data and a Ij is terminated.If it is determined that the emission mode is in step O, then 7 lag is set. Determine whether CEF is “0”. This is determined by the meter (
IV>, determines whether or not the display is being performed based on the data from the remote control A (V), with 7 lag CE
If F is "1", the data setting is ignored and the operation ends. - If the 7-lag CEF is "0", timer 3 is reset at step O and the process moves to step O. If a certain period of time (for example, 3+n1n) elapses after the above operations are not performed, the timer is shut down and the microcomputer (MCF) performs operations from step (2), returning to the state at power-on. Here, microcomputer (MC)
Table 20 summarizes the Ij-registers and flags used to explain the operation of F). Table 20 Functions of registers and flags The light emitting operation is explained based on the fjS16 diagram. When the signal line (STI) is set to "LOLI+" by the camera (1) or receiver (II), the transnoster (Tr++) becomes conductive. At this point, the signal line (
A pulse of 150μ5ecll is input from ST, ),
Meanwhile, the mode detection circuit (MODE) terminal (ES) is “H”.
igb", and the D 7 V knob/70 knob (DFll) outputs a charge completion signal of 27,000 and outputs "Hi".
gl+'', AND circuit (lXNb4),
The output of the OR circuit (OR, , ) becomes "TiF:h". Then, the end 7-(P2.) of the microcomputer (MCF)
I-1i -, h'', if the light emission is not prohibited, 7 limp 70. limp (FF, □) will be set, and the output terminal (F
The light emission start signal (No. 3 is sent from the STA) to the trigger circuit (TRC) in Figure 5, which causes the xenon tube (XE) to start emitting light. Furthermore, 7 rip 707 rip (FF, ) goes to the cent. The state of the counter (Co, □) is released and the counter (Co2゜) starts counting the time longer than the time required for full light emission.When this time has passed, 7 lithops and 70 bulbs (FF, 2 ) is reset by the output of the counter (CO=7), and the counter (C, O,,) is also reset.At this time, the end 7-(P:,) of the microcomputer (i'11cF) is I-l-1i" and in automatic dimming mode, the AND circuit (AN82) is active while the 7-lip prop (FF32) is set. During this time, the signal line (ST , ) to “HigI
+” pulse is input, this pulse is input to the AND circuit (
ANa=) - Output terminal (
FSTP) to the light emission stop circuit (STC) shown in FIG. 5, and the light emission of xenon W (XE) is stopped. In addition, when the automatic light control mode is not set, the transistor ('rrgs) becomes non-conductive based on the start of light emission, and after a period of time corresponding to the light emission amount that is manually set in the flash device (III), the fan parator (AC3) is turned off. The output of
+″′.As a result, the AND circuit (AN, □),
Output terminal (FSTP) via OR circuit (OR,,)
Light emission stop signal No. 41 is output, and the xenon tube (XE) stops emitting light. In addition, the AND circuit (
When a pulse is output from AN, □), 7s/p/7rip (FF, l) is set. Exposure control operation is completed and line 43 (ST, ) is
1-1-1i", the output of the AND circuit (ANs3) becomes "HigI+", the reset state of the counter (CO2,) is divided by negative I, and the counter (CO2+) receives the clock from the microcomputer (MCF). Pulses (φr) are counted.This causes the transistor (T
ry) is ON-○FFL at a constant period, and the light emitting diode (
LD, ) flashes to indicate that the proper exposure has been performed. Also, 7 lips and 70 tubes (
The output of FF:11) is sent to the camera as a "Lou+" FCC signal via an AND circuit (ANao). When the counter (Co2.) counts a certain period of time, the 7 lip/70 tube (FF) is reset, the counter (Cozy) is also reset, and the light emitting diode (FF) is reset.
When the LDo) goes out, the FCC signal also turns off the camera (1).
) will no longer be sent to The signal line (ST,) becomes "Lou+", and at this time, the terminal (F', s) of the operation mode detection circuit (MODE)
is “Low” and the charging state detection circuit (C
If the terminal (CH,) of HD) is “High” (charged state), the AND circuit (ANss) and the OR circuit (O
The output of R11) becomes "High". Therefore, thereafter, the xenon tube (XE) performs the light emitting operation in the same manner as the operation described in nS1. FIG. 18 is a circuit diagram showing a specific example of the meter (IV), and FIGS. 19, 20, and 21 are 70-charts showing the operation of the microcomputer (MCM) in the t518 diagram. The operation of FIG. 18 will be explained below based on this 70-chart. Power line (10 EM) from power battery (BAM)
The microcontroller (MCM) and the receiver 15 circuit (REM
), transmitting circuit (OUM), display circuit (DPC), atl
I constant mode data output circuit (LMM), channel data output circuit (CHS), AND circuit (AN, 11),
(A) J, I), (ΔN, 2), NAND circuit (NA, .), inverter (rN, , ), (IN, ,), off circuit (OR, , ), 7-lip/70-amp (FF 4.)
power supply starts. The microcomputer (MCM) starts the operation from step S1 based on this start of power supply6.
In stenop S1, go to terminal (P +1), (P1□)h]
The more constant mode data from the input measurement mode data output circuit (LMM) is taken in and set in Renostar MMR. This measurement mode data output circuit (LMM) outputs data according to the position of the slide switch (one) of m1t2I. Then, in step S2, N
ON Determine whether it is in C0RD mode. here,
In the NON C0RD mode, set the terminal (P3-) to I-l-1i+" and set the triangular length of the 7-lanon unit to mm.
In addition to making sure that the cyrisk (SC,) is not 5 due to conduction, the pulse from the detection circuit (PDT) that detects the rise of the 7-ranoshi two light is output from the AND circuit (AN, .). I'll keep it. On the other hand, N ON
If it is not the CORD mode, the terminal (P3.) is set to “L”.
ow'' to make the thyristor (SC,) conductive, and the detection circuit (P
DT) is in a state where no pulse is output. In steps S5 and S6, the output terminals (P,,), (
P3. ), (P), ), (P 3.), (P , 9),
(P,,,), (P3.), (P iz), (Pss)
"Lour" and (P71,) "I-Ti (71
−. Next, the constant ISO data vk is stored in the register SMR, and the constant exposure time data Tvk is stored in the register T.
M R, the shortest exposure time data T vmk that can be set with the meter (■) are in the register T M F
In R, the maximum value 'jyJ' and the exposure time Tvmk are initially set. Furthermore, a register G in which the light emission amount change data is set.
MH has “oooo” indicating that the amount of change is O”.
” data is initialized, and data for blank display is initialized in the register AMR to which the calculated fringe value is set.Next, in step S14, the data sent from the camera is initialized. Register AM1.R where the maximum aperture value (EL small diameter fringe value) is set: &Register AM1.R where the reading limit fringe value Av…k, open aperture value is set
The display limit value Avok is also initialized. Next, bits (+) I), (
In bo), set the contents of 1M R to the register where measurement mode data is set, and then press the remaining pins) 137) ~
(tI2') is set to "oooooo". Here, register DPR,. Table 2 shows the relationship between the data set and the display contents displayed by the display circuit (DPC).
1 (Table 21 Step S18; here, the terminal - (P, Ko) -
; Set to "High" to enter the state where data can be input from the display circuit (DPC). Next, display register DPR is added to input/output register IOR. By setting the contents of and performing serial input/output operation, a clock is output from the terminal (CKO) or 1, and based on this clock, the output terminal (SOU
) outputs data in series and reads this data into a display circuit (DPC). For the dog, data Svk in register SMR, data T'vk in register TMR,
Send the data "(') H" of register GMR and the blank data of register AMR in series, and connect the terminal (P
9. ) as "", Lou+" and proceed to step S30. Then, set the flags M CF , L MF
, reset CM F, reset the timer to enable timer interrupt, and connect the terminal (itz)t(iL+'zL
(it+a) to! 111 is enabled and the operation ends. In Figure 18, (82,,) is the measurement button (27)
The switch linked to (S21) is the TSO key (23)
(S-) is the exposure time key (22)
The switch (S = 3) linked to is the likelihood change key'-(
24) It is a switch that interlocks with i. These switches (S21,), (S;l), (S2□), (S2)
) is closed, the terminals (P, , ), (p
4o) is “LOII+”, the AND circuit (
The output of AN92) falls to "LOLI+" and an interrupt signal is input to the terminal (itz). In addition, the switch (s
24) is a switch linked to the UP key (25), and switch (S25) is a switch linked to the DOWN key (26). When an interrupt signal is input to the terminal (itz), the operation starts from step 335. S35
In step , measurement mode data is set in the register MMR, and it is determined whether the photometry switch (S2.) is ON. This operation causes (P, o) to be “Low”, (p
)9) is set to “HiH1+” and the terminal (P36) is set to “L”.
ow”.Then, switch (S
2. ) is ONL, S37, if OFF, 511
Move to step 0. In step S37, the terminal (
P5. ) as “Lou+” and Trannostar (Tr,
2), and connect the power supply line (10vM) to the photometry circuit, detection circuit (PDT), and A-D7 conversion circuit (MAD).
) starts supplying power to the Next, in step 7 of S38, the N ON CORD mode is determined and the N ON C<)RD −[=
-1''t LAS 39, NON, C0RD-T=
- If there is no i', the process moves to step S55. S39
In the step, the terminal (P39) is closed to f(igh", and the analog switch (A S , ) is made conductive. Also, the terminal (P3.) is set to "Hi8h" and the AND circuit (
When AN, 1) is disabled and (AN, .) is active, the pulse from the detection circuit (P D T ) is sent to the interrupt terminal via the AND circuit (AN, .) and the inverter (IN, .). (itzo) is accepted, the timer is reset, and the process moves to step S42. In step S42, it is determined whether the measurement switch (Szo) remains ON, and if it remains ON, it is determined whether the timer has counted Tc for a certain period of time. And-・Constant”3 I?tl T c (for example, 10 seconds)
If the count has not been completed, the process returns to step S42. Repeat steps S.12 and S.13 until the photometry switch (S2.) turns OFF.
Alternatively, if it is determined that a certain period of time Tc has elapsed, 34
The process moves to step S4, where reception of an interrupt signal from the terminal (iLlo) is disabled, and the process moves to step S45. In step S45, the registers DPR, , z)(L+
o), (b,) set the mode data of the register MMR, register AMR set the data for blank display, and send the display data to the display circuit in the same manner as steps 31 f3 to S29. (D P C), reset the 7-lag Ni CF, and reset the timer.
Timer interrupt and terminals (!Lz), (itzz), (
itz, ) is enabled and the operation (t) is terminated. Here, the flag MCF is "1" if the threshold value can be displayed, otherwise it is "0". In the 18th interval, the photoreceptor (P D 2) is a photometric photoreceptor provided in the portion of the light receiving bulb (15) in FIG.
This light receiving element (PD2) is connected between both input terminals of the amplifier (OA, l), and the output current of the light receiving element (PD2) is converted into a logarithmic pressure line voltage by a guiode (D21). If the analog switch ()\S,) is conductive, the output of the amplifier (OA+,) will be the trannosta (
Tr7゜), and the light receiving element (P D 2
) output voltage? ! It is converted into a collector current corresponding to B. This current becomes two collector currents by the current mirror multi-collector trannostar (Tr71),
One side is input to a logarithmic compression integration circuit with a guide (D2□), (D ;)) and a capacitor (C, , , ), and Ikekata is input to a detection circuit (P DT ). Detection circuit (P
When the rising edge of the 7 rush light is detected at D /B・70/P (FF, .) is set, and the analog switch (A S 2) becomes non-conductive. Therefore, the integration into the capacitor (C,.) begins. −
The output of the inverter (IN,,) becomes LoI11'', which causes the terminal (itlo) of the microcontroller (MCM) to
An interrupt occurs, and the operation starts from step S58. This operation will be described later. Step S3G
If it is determined that the mode is not N0NcORr), the terminal (Pz-) is set to “L・1111” in step 355.
'', the sirisk (SC,) is in a conductive state, and the detection circuit (PDT) is connected from the AND circuit (A N 9°).
The state is such that no pulse is output from. Next, the terminal (P
, S) are set to "H1ε11", thereby making the analog switch (AS, ) conductive. and terminal (P-3)
Outputs a “Higb” pulse to the OFF circuit (OR, ,
) to set 7s, 7b, 707p (F At the same time, the output of the AND circuit (ANsl) is
'' to guide the thyristor (SC,),
Set the signal line (ST, ) to “Low” and connect the meter (■
) 7Latsushini terminal (30) fires the flash connected to the cord. In step 358, a constant integration time Tk (for example, 1, /
64 5ect Tv=6). When this f-time period has elapsed, the terminal (P, 5) is connected to “LoI”.
The analog switch (ASI) is turned off as U'', and the integrated charge is sampled and held in the capacitor (C1°).Next, in step S60, the terminal (
Output a "HiFlh" pulse to P, l) to start the operation of the A-D converter (MAD), and wait for the terminal (P3o) to roar "Higl+" indicating that the A-[) conversion has been completed. wait. A-D conversion is completed and the terminals (P,,) are “
When it becomes High'', it outputs a Highb'' pulse to the terminal (P3=), resets the 7-lip, 70-tub (FF, .), makes the analog switch (AS2) conductive, and charges the capacitor (Czo). Discharge the charge. Then, set the terminal (P29) to “HiH1+” and convert the A-D converter (
Data is output in series from M A D ), and a serial input/output operation is performed. As a result, eight clock signals are output from the clock/return terminal (CKO), and in synchronization with this, eight clock conversion data is output in series to the serial input terminal (SIN), and this is read into the register IOR. . In step S65, it is determined whether the 7-lag LMF is 1'', and if it is 0'', the contents of the register IOR are set in the register ADR, and then it is determined whether the AMB I mode is set. If the AMBI mode is not selected, set the 7lag LMF to 1'', return to step S56, perform the same operation as described above, and measure the dog. Even if it is connected, the light will not be emitted immediately after the light is emitted, and only the steady light will be measured.Then, when the A-D conversion data is imported, the flag LMF will be set to "1'', so the fetched data is set in the register ADR2i, and the flag LMF' is set to 'blank)'' in S71.
Move to the next step. lj, A8 (When it is determined that the mode is BI mode, only one measurement is required, and the process moves to step S70 and step 371.As can be seen from the above explanation, N
ON CoRD% When in CoRD mode, measurements are performed twice, once when the light is emitted and once when the light is not emitted, and the 7-lag LMF distinguishes between the first measurement and the second measurement. In the step S71, it is determined whether the mode is ~MBT mode or not, and if it is the AMB I mode, the process moves to S72, and if it is not the AMB r mode, the process moves to steps 390 in FIG. 20.S7
In step 2, data Tv corresponding to the 7 pixel value of the constant integration time open Tk is added to the contents of the register ADR.
The data obtained by adding k is set in register BVR. This calculation is performed because the contents of [Nonostar ADR] are the integral of the subject brightness over a certain period of time, that is, By-Tvk.
This means that a performance of (r'3V-T vk) + T vk = B v has been performed. Next, in step S73, B v + S v - TV = A based on the rSO data and the set exposure time data.
v is calculated and this fringe value data is stored in register A.
M R1,: Set. Then, it is checked whether the second calculated fringe value or the maximum aperture T) value (AMXR> is exceeded. If it is, the contents of the run star A'M , the OVER display is performed, and the process moves to step S81.When it is determined in step S74 that the exposure print value is below the maximum aperture value la, the process proceeds to step S77. De A M
It is determined whether the content of R is smaller than the minimum fringe value (open aperture value). If it is determined that the value is smaller, the contents of the register AMTR are set in the register AMR, and an UNDER display is performed in S8.
Proceed to step 1 of step 7. Also, . If it is determined in step S77 that the calculated fringe value is greater than or equal to the minimum aperture value, the process proceeds to step Sol, assuming that 0VER1UNDER is not displayed.
In the step S81, the measurement mode is displayed, and the display data is transferred to the display circuit (DPC) for display in the steps S29 to S29, and the display data is displayed in the AMB r mode. In order to indicate that the measurement has been performed, the flag ΔMF is set to 1'' and the process moves to step S34. In step SS4, it is determined whether the photometry switch (S2°) is closed or not. If it is closed, S55
Return to step 1 and perform the next natural light measurement. −・
On the other hand, be sure to open the photometering switch (S);
Proceeding to step 7 of 3102 in FIG. 20, the flag indicating that measurement is occurring is set to ICF, and the timer is reset to enable timer interrupts.Next, The iq child (Pso) is set to "Hi I; 1+" to stop the power supply by the transnostar (Tr,,), and the terminals (P3.) and (r',,,) are set to "J-OLI+".
The microcomputer (MCM) terminates its operation by accepting interrupt signals to the terminals (itz), (iL12), and (it+;+). If it is determined in step S71 that the mode is not AMBI mode, the process moves to step S90 in FIG. 20. First, in the step S90, as in the step S72, (B v - T vk) + T vk = B v is calculated and this calculated value Bv is set in the register BVR. First, the amount of light received by the flash emission is calculated. When the apex value is Q vfo, register ΔDR. The data set in ~, (2Bv″?-&t
It is 2°'' month.So this data and register AD
Qvfo from the data Bv-Tvk set in R2
seek. This method is as follows. First Q
When vro-(Bv-Tvk)=a, 4 (2"-"j 2"")" (Bv
-Tvk) +40t 2=i: Glvja f
There is a relationship of 4 z (/T 2-"). Therefore, calculate α1, convert this α1 into , l'ty, (t tz-'t)1 using a table in ROM, and then bit ( 2"V-tsuka, 17g2 (Isu2-2"
Qv! . This data Qfvo is stored in register Q.
Set to V Ro. This register QVR for dogs. Add (including subtraction) the contents of the register GMR, in which the light emission amount change data is set, to the contents of , calculate the amount of light received by the flash during actual shooting, Qvr, and register QVR+. : Set and proceed to step S94. In step S9.1, the contents of the register TMR in which the exposure time is set are set to the fog-out time (TMFR) at the tuning limit.
), and if the time is t, the contents of register T M F R are stored in register T.
M
Move to step 3. 59 (In step 3, exposure time Tv, ISO data Sv, subject brightness By, received light amount data Qv by 7 random calculations (ifi,
Calculate the aperture value for iTE exposure and set it in register A to 1 shaku. This calculation power (the following is a sea urchin. Mass, Av: A, p 2 (zB'-" r 2977)
There is a relationship of O Sv and Qvr-(Bv-Tv
) = α2, Av = QJ + Sv + k, 3z (/t
AV can be found by calculating α2, which is in the relationship Z-', finding it from a table, and performing the above-mentioned calculations. Next +1s9
In step a, in the same way as steps S74 to S80, it is determined whether the calculated value Av is within the controllable range. 1. The display circuit (DPC) displays the display data as a state to display the measurement mode in 9 steps.
Since it is not AMBI mode, send 7 lag AMF to "
0" and performs the operations 51()2 to 5107 described above, and the microcomputer (MCM) stops operating. At step 53 (3) in FIG.
) is not closed, the 20th
Step 311 in the figure (step 1 is executed f times. In step 5110, it is determined whether 7-lag CM F is "1". This 7-lag CM F" has data read from camera (1). If it is not read, it will be "1", and if it is not read, it will be O". Therefore, if it is "1", there is no need to change the ISO data, so go to step S120 multiple times, and if it is "0", go to step 5111. In step S111, it is determined whether or not the ISO switch (S21) is open, and if it is not closed, the process moves to step 5120.On the other hand, if it is closed, the dog is instructed to It is determined whether the switch (S,) is closed. If the tJP switch (324) is closed, the contents of the register SMR where the ISO data is set are 1/3E. The data corresponding to +U is added to v, and it is determined whether this data is larger than the maximum value Sv+n.If it is, the maximum value Svm is stored in the register S.
Set ILi to R, and if it is not large, register SM
The process moves to step 8141, leaving the existence of R unchanged. When it is determined that the T-IP switch (S24) is not closed in step 5112, next,
At step 311G, press the DOWN switch (S,...
) is closed IIt or not by 1:η. If this DOWN switch (S25) is also not closed, the process moves to step 5102, the above-described operation is performed, and the microcomputer (MCM) stops operating. On the other hand, if the DOWN switch (S25) is set to rA, the ISO data is decreased by 1/3 Ev in step 5117, and it is determined whether the ISO data has become smaller than the minimum value Svo. And if it is smaller than Svo, register SM
Set the minimum value Svo to H, and if it is not small, leave it as 1.
Then, the process moves to step 5141. At step 5110, 7 lag CM F is “1” or 5
When it is determined that the ISO switch (S2.) is not closed using the steering knob 111, the process moves to the steering knob 5120. At step 5120, it is determined whether the exposure time switch (S2□) is closed or not.
Do many lines. At step 5121, switch on the IP switch (
S2. ) is closed, and if it is closed, the exposure time data of the register TMR is increased by IEv, and this data is set to the maximum value set in the TMR. Determine whether it is larger than the value (camera control limit), and if it is thick, store the maximum value in register T.
M R1,: Set, and if it is not large, leave it as is and proceed to step 5141. - power, LIP switch (S24) is closed rI1. When it is determined that 1 item is not set, in step 5125, the l)0~)N switch (S
2. ) is opened or not, and if it is not opened, the process moves to step 5102 described above. On the other hand, if the DOWN switch knob (S = s) is closed, the contents of register TMR are decreased by IEv,
The minimum value set in register TMRR)
If it is small, TMI
Set the content of R to TMR, and if it is not small, leave it as it is, and perform multiplexing at step 5141 (this step). At step 5132, it is determined whether the 1 to MB I mode is active, and if it is AMB I mode, the light emission amount is set. Even if the change data is set, it is useless, so move on to step i of 8102.On the other hand, if it is not AMBI mode,
! "/'! Check whether 4i11 is configured separately. And if the IP switch (S2.) is closed,
Change amount data set in register GMR to 1
/ 2Ev increase, and if this data exceeds +3Ev, set +3Ev data in GMH, and if it does not exceed, leave it as is, 5141
Shift to steno opening. On the other hand, if the CJP switch (S2.l) is released, DoWr=
Check whether 1 switch / switch (S3) is closed or not.
Separate. If it is closed, the content of GMR is 1/2Eν
and determine whether this data is below 13 tE'v. If it is below, set the data of -3Eν, and if it is not below, leave the contents of GMR as is and move on to step 5141.
If the DO■'N switch (S25) is also open with the step knob 37, the process moves to step 5102. In the Sl/tl step, UP switch (S 24)
Determine whether or not the cap is released, and if it is released, ν1
If not, wait for it to be released. This is so that the data changes by one step knob each time a key is pressed. If the UP switch (S Z-) is open, then it is determined whether the DOW N switch (S,,) is open, and if it is open (if it is 1, it is open). Wait for both Sui Nochi (S 2
4), 81 when it is determined that (82%) is released.
In step 43, it is determined whether the measurement calculation has been performed, that is, whether the flag MCF is "BI". If it is not 1, the display data is sent to the display circuit (DPC).
The process moves to Step 5103. On the other hand, if it is "1", then it is determined whether it is 7 lag A sq F or °'1", and if it is "1", the AM from step S72 in Figure @19 is
Perform calculation in BI mode, and if ° is “0”, CORD from S90 step *r: HiJ ON
CORD Noah 77 Performs calculations for CORD. This is because it is impossible to calculate a new aperture value when data is changed. Fig. 22 is a specific example of the 912 circuit (REM) in Fig. fjS18.
The drawing is almost the same as the receiving circuit (DERE) in \-(■). (RED) is the light emitting material (
This is a light-receiving element for fU that receives infrared light sent out from the amplifier (PAM), and outputs a denochle signal that is sent 1 m away from the amplifier (PAM). This signal is fIS
The data is read into the shift register (SHR, .) in the same manner as shown in FIG. While this reading operation is being performed,
The signal line (MRC) is set to 'Hil;b', and the NAND circuit <NA,,,) in Fig.
Even if OU S > is closed, it is still “HiHII”.
,: The data transmission is prohibited. 7)・
The data on the
(AGl,) becomes "HiHb", and furthermore, when the AND circuit (A G,,) determines that the data is from the receiver (It), the AND circuit (A
The output of G,, ) becomes ")[i and 11". This results in invar 9 (r N52) + 7) output (MRE)
falls to “L our” and the interrupt terminal (111□)
An interrupt signal is input to. From this point, the microcomputer (MCM) starts the operation from 81.+5 in the fjS2X diagram. At the step Sl・+5, the terminal (P51) is set to “I(iH
1+'' and the AND circuit CAC,S), (A
G 6), (Ac;, 3), NAND circuit (NA3S)
is considered to be an active state. When serial input/output operation is performed in the second state, the microcontroller (MC)
Eight clocks are input from the terminal (CK○) of M), one byte of data is output in synchronization with the rising edge of this clock, and the second data is sent to the AND circuit (AGe) in synchronization with the falling edge of the clock. ) and shift register (SH
Rz). Furthermore, if the data from the shift register (SHR,,
) becomes conductive and a high signal is input to the data input terminal (SIN) of the microcomputer (MCNi).On the other hand,
Data from Shift Renosuf (sHRt+) is “Low”
'', the output of the AND circuit (AGE) is IlHi H1+
”, the N-channel FET (FT, ) becomes conductive, and “
The signal of Lou+'' is input to the data input terminal (SIN).
'IA 7'' 9 (R%1,)L, t Set in the register RMRo of the microcomputer (MCM) J''L. Similarly, the camera's shortest exposure 11:? The data indicating the interval is set in the register TMXR, the best exposure time data is set in TMIR, and the tuning limit exposure time data for flash@color is set in T-IFR. The maximum aperture for dogs is AMXR,
The open aperture value is set to A M r Ri. Here, when the data "01H" indicating that the lens is not attached is input, it is necessary to set the limit value data of the display limit of the meter (■) in the registers 1 to MXR and AMI R. S In step 159, power, ■S from Nora
o Set the data in the register SMR; and connect it to the terminal (P
s,) as Lou+", the step of -S 1 f31,
In the program, set "1" to 7 lag C. 2, 7 lag CM F is a flag indicating that data from camera (1) has been read. 8162 is A M B T
mode, and if it is AMBI mode, determines whether the exposure time is shorter than the set exposure time (TMR) or the shortest exposure time data, and if it is short exposure time (TMR).
MXR) in the register TMR, and the process moves to step 5167. 8162 ST, PUDE A M B
When it is determined that it is not the I mode, it is determined whether the set exposure time (TMR) is shorter than the tuning limit exposure time (TMFR). Is there a tuning limit if the time is short? Set the iL exposure time in the register T and IR, and
Go to step 167. In step 8167, it is determined whether the set exposure time is longer than the best exposure time data (TMIR), and if the set exposure time is longer than the best exposure time data (TMIR), the exposure time data is set in the register TMR. In step 8169, measurement mode data (M M
R) as a display register DPR. bit (b+),
Set it to (1). In the 8170 steps for the dog,
Among the data sent from the camera 4) to the Lenher (n), it is determined whether a signal indicating that the control is not interlocked is input, and if the out-of-interlock signal is manually input, the DPR is activated. , (113) and (b2) are set to "10", and if this signal is not input, data of "01" is set. Next, No. 15 indicating whether the camera's exposure control has been performed is placed in (bz) of DPl, .
[I] Indicates whether charging is completed (i)
1) Set to 4). Then, in step 5175, it is determined whether the flag MCF is ``1'' or not by 1-1l, and ``
If the flag MCF is "1", measurement has not been performed, so the display data is transferred to the display circuit (DPC) and the process moves to step 5103.On the other hand, if the flag MCF is "1", measurement is not performed. Therefore, at step 8177, A
It is determined whether MBI mode measurement is being performed, that is, whether the flag AMF is 1''.
In MBI mode, based on the read data <AMB
In order to perform calculations in I mode, proceed to step S72, and if the mode is not A M 13 T mode, then perform calculations for CORD or N ON CORD.
The process moves to step S90. If the signal line (MRC) is at Lou+'' when the transmitting switch (OU S ) in the f1S18 diagram is opened, the output of the NAND circuit (N A , , ) is °'Lou
+'', an interrupt signal is input to the interrupt terminal (it+i), and the microcomputer [CM] performs the operation from step S1:3n'), and at step S]30, the reset switch (. RES) is closed, and if it is closed, the process moves to step 5210, and if it is not open, the process moves to step 5181. In step 5181, the register MT in which data (MTO) is set is determined. 10″ on (b7) and (b6) of R,
to determine whether it is in N ON CORD mode. If it is NON C0RD mode, it is checked whether the test light emission switch (TES) is closed or not, and if it is open, the register ? , I
The pin (hs) of TR is set to "1" to send a test light emission signal.On the other hand, if it is not closed, it is set to 0 and no test light emission signal is sent. Also, N
If it is not the ON CORD mode, (b5) is set to "0" regardless of the state of the test flash switch. Dog: Set (b,) of M T Ro to "'1" to send a 1-frame jEL W5 mode signal. Next, determine whether the TES) Q optical switch (T ES ) is closed or not (3 jt terminal (r',,,) or "Lou+", and if it is "LOLI+", release the release. (b3), (+1.), (1+
+) is set to "000" data. On the other hand, the test switch (T E S ) is closed and ν1 is turned off.
baud) from the channel data output circuit (CHS)
(b3) of MTR,
, (1+:), (Il+,). Next, at step 8190, the flag MCF is “1”
If it is "1", the measurement is being performed, so the process moves to step 1 of 5191. In step 8191, it is not determined whether the mode is AMBI mode or not.
Set (b,,) of o to "()", and set ``001('' to register MTRs for child likelihood change amount data. On the other hand, if it is not AMBT mode, MTR ,,
(+1 , , ) is “1”, and the change amount data (GM
R) is set in register MTR. And 5
MT the aperture value data (AMR) with 196 steps.
Exposure time data (TMR) is set to MTR2 in R, and the process moves to step 8216. If it is determined in step 8190 that no measurement is being performed, the process moves to step S2"'13, and the registers MTR, , MTR2, MTR) are set to "
00H" data and step 1 of 8216.
Do many lines. In addition, when it is determined in step 8180 that the lycee and 2 toss inochi (RES) are closed, "0" is set in (b7) and (bG) of the register MTRo.
0” and further set “0” for (1,s), (+)3) to (1].), and set MTR1% MTR,,MTR
, is also set to "OOH" and the process moves to step 8216. FIG. 23 shows a specific example of the data transmitting circuit (OUM) shown in FIG. 18, and has almost the same groove configuration as the circuit shown in FIG. 12. The terminal (1”52) of the microcomputer (MCM>) is “Hi61”
+”, AND circuit (AG27), (AG2a)7
C becomes active. And (MT, J), (NiT
, ), (MT:), and (MT3) are sequentially output in series from the microcomputer (MCM), and these 4 bytes of data are read into the shift register (SHR, , ). When the microcomputer CMCM> sets the terminal (P5□) to 'Lou+', the output of the inverter (IN,...) rises to 'HigI+', and based on this rise, the constant likelihood diode ( OUD
) Light No. 15 is sent out. Mainian (MCM)l! Main power source BAM)ノOl'l';'? Jf child (itl+), (it+2
), (it, 1) When a certain period of time (30 seconds) has elapsed after the end of the operation caused by the interrupt signal, an interrupt is generated by the timer, and the operation starts from step 5230. First, set all (b2) to (137) of the display register DPR, , to 0", and set blank display data in the register AMR. Then, set the terminal (P53) to "Hi".
gl+'', the contents of the register DPR,o are sent to the display circuit (DPC), and data for blank display to turn off all the displays of ISO data, exposure time, amount of change, and fringe value is sent to the display circuit (DPC). S2
Go to step 9 and stop working. Here the 19th
Table 22 summarizes the register flags used in the 70-charts in FIGS. 20 and 21. Table 22 FIG. 24 is a circuit diagram showing an example of remote control A(V). Basically, the circuit arrangement is the same as in Fig. 1112I and Fig. 12. (FiARl) is a power supply battery, and (MSR,) is a main switch. (O3C,) is the oscillator, (DI\・'l) is the oscillator (○
5C1) output is frequency-divided to generate reference pulses (φA), (φB
) is a frequency divider that outputs Su・fnochi (S,,,,)
m1 [
It is interlocked with the switching member (41) of 7I. When the switch (S, , ) is closed, it indicates that exposure control data for steady-state mode is sent, and when it is open, exposure control data for mode 7 is transmitted. (CH3,) is a circuit for outputting channel data, and outputs a data alarm according to the setting position of the dial (43) in FIG. The switch (S, ,) is the switch that switches between the consecutive 8-shot 7> mode and the 1-frame J&A mode.
, ) is closed, it is a continuous frame shooting mode, and when it is open, it is a single frame shooting mode. This switch is linked to the switching member (42) of FIG. Suinochi (S, :)
is the switch for test t'2, and this switch (S,:
) is released, a test flash start signal is sent. Note that when this switch (Sl□) is opened, the channel data output circuit (CH3,) outputs data "000" to prevent release. Also,(
Fixed data indicating remote control A (■) of "10" is output as the data of b7) and (b6). These form data (MT,) to be sent to the camera (1). S's is a switch linked to the clear button (4), and when this switch (Sw) is closed, all exposure control data becomes "OOH". ()\PS) outputs the control aperture value data set with the dial (36) in FIG. 1, and (TIS) outputs the exposure time data set with the dial (35) in FIG. When you press the call button (・7), the switch (RS
, ) is closed, and if the remote control is not receiving data at this time, 7
The output of the A circuit (NO35) rises to Higl+''. At this rise, a pulse for one clock of the reference clock (φ7\) is output from the AND circuit (A (:,,), and various setting data described in fj are output. Gun7 Torenostar (S
Hn +7N Korasochisa A Shiro. Then, the pulse for 1 cro/min of the next store-based long (φA) is output from the AND circuit (A
G , ,) is output from the light emitting diode (DOU,
) is carried out in the same manner as in FIG. Data reception is also carried out in the same manner as in FIG. 11 via the light receiving element (IRDI) and preamplifier (PAM2). When the reception is completed and it is read correctly and classified, the 7 linop/70/knob (FFG-) is set.
The decoders (DE, ) and (DEZ) become active. Then, the read data (RMI) to (RM6) are sent to the display circuit (P Dr ) via the decoder (DE, ).
・It will be displayed on the LCD. Also, charging is complete, release is complete,
Pino 1 (l
ls). (b4) + (b,) Carano f5 is def -1'(r)E
:) e through light emitting diode (L D ,), (L D
2), (L D,)! 2 shown. Then, the counter (CΩ4.) counts the basic W black/reverse (φB), and when a certain period of time has elapsed, the 7') 77' and 70 knobs (FF, , ) are reset, and the output) 1C guiode is reset. The light goes out, and after a certain period of time has passed, the 7 linop and 70 knobs (FF,...) are turned off and the liquid crystal display goes out. In addition, when reading incorrect data and starting data transmission, the OR circuit (OR,,) is reset to 7 rip and 70 rip (FF Yu,),
The display will turn off when the 7 linop/70 tube (FFG5) is reset. FIG. 25 is a circuit diagram showing an example of a remote controller B (■), which has basically the same circuit configuration as FIG. 12. (BAR,) is a power source battery, and (MSR2) is a main switch. (○5C2) is an oscillator (DT\'1)
divides the output of the oscillator (○SC,) to give the base Qf, 9
This is a frequency divider that outputs Qtsk (φl~). (CHS,) is a circuit that outputs channel data according to the setting position of the dial (51) in FIG. (S,...) is a switch linked to the switching member (50) shown in Fig. 1, which is opened in the one-shot shooting mode and closed in the continuous shooting mode. (S:t) is a switch that is opened during test emission and closed when non-light >'Q,
When this switch (S2.) is opened, a data of "001)" is output from the channel tree data output circuit (CHS:) to prevent release. Fixed data of "11" has been set for (+)7) and (+)6). By these, T-(hIT,...
, ) is formed. In addition, data (M T I
L(?, IT:2). (MT3) is set to "OOH" data. When the transmit button (53) in Fig. 1 is pressed, the switch (RS2) is closed, and the above setting data (T,,) to (MT=) are sent by the pulse from the AND circuit (AC;,,).
; 7 Trenosta (SHR,,) has lunch. Then, the pulse from the AND circuit (AG, □) enters the 7th train (the transmission of the data latched to Sr (R, ,) is similar to Fig. 12, and the light emission is 1'< D OU z)
Do it accordingly. In the above embodiments, if the camera (I) is not equipped with a double lens or a double lens,
It is easy to use the unequipped lock, and it is easy to set up the lock 1, or the unequipped 1 position), and the data output is (1t1 not increased, the bellows 'le γ's swing I〉to the crisis) is 2nd place. It also includes the cases where it is done. Also, 7 runcill device (III) to camera book 1 (1)
The following connection force method is available for the receiver (-<n). Provide a connection part with the same contact shape as the contact point at the position of the phone 1 button (1) on the bottom of the camera, prepare a power adapter such as a power green knob that has a connection part that corresponds to this bottom connection part, and attach it to the top of this adapter. Provide a shoe. If you do this, you can separate the 7 shoes (I [
I) and the receiver (II), and there is no need to provide a hot shoe (7) on the receiver (n). In this case, since a motor drive may be installed at the bottom of the camera, it is necessary to provide a signal path within the motor drive so that the signal from the connector at the bottom of the camera is output through the bottom of the motor drive. . Further, the distance between the camera main IF (1) and the receiver (II), the intermediate wire (n) and the seven-layer assembly (III) may be connected by a cable. Furthermore, the receiving section (3) and transmitting section (4) of the receiver (■) are installed on the front side of the camera body, and the ('3. In the above embodiment, the receiver (III),
The meter (■) and the remote controller (V) are for both transmission and reception.
I have Y fj2, but the receiver (IT)
I”r C to increase the power meter (■), remote control A
(V) may be omitted. If you do this, data (RMO) to (RMO) will be unnecessary. Furthermore, from the meter (IV) and remote control A (V), The brightness of the subject or the amount of light received by flash emission may be sent, and the camera body may calculate the exposure control data based on this data. In addition, when increasing or decreasing the current light emission amount, data indicating how many steps:υ can be increased is sent from the 7 u/sh (m) to the camera body, and this data is sent to the camera body. It may also be sent to the meter (1'/) via the lane bar (n).In this way, the meter can automatically limit the change amount data based on this read data. Because it is possible to
Uncontrollable data: Kiride with two stores, ¥1C Seri will no longer be held. Also, from the camera (I) via the receiver (II),
C. The signal that is sent out that is not interlocked with control may be sent as a signal that indicates which data is not interlocked with control. In addition, from the camera book Todo (1) to the 7 Ranoshyu device (III
), if the camera (1) is operating, it will always send data (CF O) to (CF 3 ) for the camera (1), but the force / ° body (1) The performance for 7-ray photography is performed only when a charging completion signal is input to the 7-ray photography data (CFO).
(CF 3 ) may be sent. Furthermore, it was not possible to specify the channel for the receiver (n) slave function and test emission performance.
The parts for transmitting the Leeds signal are the meter (■) and the remote control l.
\(V), [3(VT)] If this iroke is treated as the same as the eggplant 1 light emission signal, the release signal and channel signal will become independent signals, and the death 1
- It is now possible to specify channels for light emission and slave light emission. Furthermore, in the continuous shooting mode: 5 mode, data on the number of shots may be sent from the remote control to the receiver every 7 inches. In this place a・, remote control;・j in fjl,
+,. Set the color number setting dial to 0 if you do not want to release the camera.
．． When using 1-frame shooting mode, 1.2. '('J Takeju Otsu)・
2, quaternary 1, position up to 5 corresponding to 5 pieces, and as in the example, if the send button (47) or (53) is pressed again, ``continuously (perform up to 7>''): 2. Provide a corresponding position C. Regino then compares the read data with the count value of the number of times the X contact of the camera body is closed from the signal line (ST), and if the two match, the relay will be trusted. All you have to do is not output J′. Also, from the meter LEE or remote control,
〉 data for Jt and δ;
))'s P) (Ig) was used to send a signal of °°1", but there is also an alternative method as shown below. fill, self::, q:
Receive a signal indicating that the data is for the likely form.
When the 7th line is read, the photoelectric completion signal is output by the transistor shown in Fig.
Transmit 17 Tr, 3) and connect 'I to the signal line (ST=).
−ou+” is 8 times higher. This is the terminal (FC) and (
1) and the inversion of (d, J), and connect this AND and the circuit (Δt14□) to the base of the transistor (Tr, i) by ORing the circuit. .Then, the 7-rush transistor (Tr, s
) conducts, this output current flows through the transistor (Trl
, ), and the transistor (T
r3z) becomes non-conductive, and D7 linop/70 mp(
D F , 7) latches the "I-0'n" signal. Therefore, the X contact of the flash closes when the charging completion signal is received.
C also does not emit light. Furthermore, since the charging unit does not read the charging completion signal, it does not indicate that charging is complete. In addition, although data is exchanged between the meter, remote controller, and receiver using infrared radiation, other means such as ultrasonic waves may also be used.
, may be replaced with a push-button system and the dial may be eliminated. In addition, in the above-mentioned example, the force 2 degrees is applied (1) (from the second receiver (■) to the 7th exposure device (fI). [
5 (Data (CF3
)'s (+13)) was sent, and when the 7-7 device (1') received this signal, it was configured not to respond to the stop signal sent from the camera (I).
The following alternative methods can be used to prohibit automatic light control as described in 2. That is, in the camera (1), the receiver (I
When data for 7-lash photography is input from I), do not output the light emission stop signal to the line (ST, )? - A delay circuit is installed to output one light emission stop signal after the time required for the 7 lash device (III) to emit all light, and a delay circuit is provided to output one light emission stop signal after the time required for the 7 lash device (III) to emit all light. By controlling the operation and power supply so that the circuit is inactive, the self-Er adjustment of the 7-run system 0 (DI) can be achieved just by configuring the circuit groove of the camera (1). Alternatively, in the receiver (II), the meter (1
'/) or remote controller A (V) and that the X contact (SX) is closed; When "L Q jQ" is set to 2 -C, even if a pulse of "HiHI+" is output after the camera (N) stops emitting light, this pulse will absorb the current in the Lenher and cause t-+ OIII. ” If you do this, the flash (■) will not emit light, and the automatic light adjustment will not be performed. According to the present invention, the light emitting amount control means is
Exposure control using natural light or flash light based on external input data
Kana 5 Reru Sen/j! I was in the darkest position, and the above jl top part, kadek, and c flash photography data and self:,::
:. 7j; r:'='; Indicates which of the data for J1
The above section is based on X'1. , was controlled by two responses,
If the above external input data is predetermined data for flash photography according to the predetermined amount of 7Rannonyu2, ;U(the older brother equivalent to TTL direct measurement); ■Movement 1" [, stops with - 5 and controls Kemera's exposure using the above data for flash photography and fires a predetermined amount at position 7"/:C
72 shots (retrieve the desired exposure to the desired part of the IH) Intentional (ni r5,,,・"r l'f',")
. Therefore, if the above external input data is for natural light (7), it is possible to take unintentional shots where the flash device's light emission is controlled based on TTL direct data. So, I did the intentional @τ) mentioned above)! ! ! , If the above specified starlight is determined by TTL measurement and measurement, °C means q, > 1+, then the inconvenience will be resolved.

[Brief explanation of the drawing]

(S) Figure 1 shows the outer edges of the camera system according to the present invention;
Camera book (,)ζN)17 in Figure 1
Indicates the display section of the Ranone device (■) and meter (IV).
[Zu I, No. 514 is the 7th book (Book (I), Receiver
((■) IG circuit purchase j7j7, 77r figure, m!”+
[::1 is the camera name fj2 (1) in Figure 5, 1 and 2.
Circuit section (T'゛1F), (FLC) (7) only 1
4s example circuit diagram, Figure 7 shows the operation of the microcomputer (MC0) of the camera Kimoto (1), and Figure 9 shows the operation of the microcomputer (MC0) of the camera Kimoto (1). FIG. 10 is a circuit diagram showing a typical circuit configuration. 11, 12, and 14 are the circuit sections (MODE), <DERE), and <DOP in FIG. 9, respectively.
) and (CO5E), FIG. 13 is a timing chart showing the operation of these circuit parts, and FIG. Figure 17 is a flowchart showing the operation of the microcomputer (MCF) in the flash I/F. The meter (IV) circuit in the fjS1 diagram (circuit diagram showing the components, 1st
Figures 9 to 21 show the meter (IV) microcomputer (M
70-Chart showing the operation of CM), Figure 22 and f
: rS23 figure is respectively Figure 18: Koker/-tar (
IV) circuit section (RCM) and (Ot, l x, 1
), and FIGS. 2, 1, and 25 are circuit diagrams showing the circuit configurations of remote controller A(V) and remote controller B('/I) in FIG. 51, respectively. I...Camera, ■...Electronic flash device, MTl. MT2...exposure control data, FLC, ST,...light emission stop signal means, ST,, SIN...discrimination signal input means,
M To (13z)...Discrimination signal, M C. (@56x#58+#62), 501J, ST2...Control signal means. Applicant Minolta Camera Co., Ltd.

Claims (1)

[Claims] 1. In a photographing device that cooperates with an electronic flash device having a light emission amount control means and performs exposure control by natural light photography or flash photography based on data input from the outside, the film passes through the photographic lens during film exposure. A light emission stop signal output means that measures subject light reflected from a surface and outputs a signal to stop the light emission of an electronic flash device when the integral value reaches a predetermined value; a discrimination signal input means for inputting a discrimination signal indicating which data it is; and a discrimination signal input means for inputting a discrimination signal indicating which data it is; Controls the light emission amount control operation of the electronic flash device based on the light emission stop signal so as to permit the light emission amount control operation and prohibit the light emission amount control operation of the electronic flash device based on the light emission stop signal in the case of data for flash photography. 1. A flash photography device comprising: control signal output means for outputting a signal for