JPS6150299B2 - - Google Patents

Description

[Detailed description of the invention]

The present invention relates to an electronic timepiece for a camera equipped with a film imprinting display section and a monitor display section thereof. Electronic clocks for cameras are broadly divided into a low-power monitor display device made of a liquid crystal display (LCD) that constantly monitors the contents of the film imprint, a film imprint display device made of a light emitting diode (LED), and a battery. There is. Among these, the monitor display device and clock circuit consume low power, so even if the battery voltage drops due to low temperatures, their operation is hardly affected, and they can operate over a fairly wide temperature range in practice. be. but
Display devices using LEDs require a large current, approximately seven times that of LCD display devices, due to their driving efficiency. In addition, the internal impedance of a battery is greatly affected by temperature; at low temperatures, for example around -10°C, its internal impedance becomes approximately 10 times that at room temperature (25°C). (see table).

[Table] Therefore, when the light emission operation of the film imprinting display device is started by a shutter input in a low temperature atmosphere such as in a cold region, the output impedance increases and the light emitting operation of the imprinting display device starts. When current flows through the battery, the voltage drop across the battery is greater than that at room temperature (see table), which could cause the clock circuit to stop oscillating or cause the counting and control circuits to malfunction. This invention detects the battery voltage when the first light emitting operation of the film imprinting display device is performed after the shutter is input, and when that value is less than a specified value, the subsequent light emitting operation of the film imprinting display device is performed. It is an object of the present invention to provide an electronic timepiece for a camera which eliminates the above-mentioned drawbacks of the conventional camera by stopping the camera and displaying its state on a monitor display device. Embodiments of the present invention will be described below based on the drawings. FIG. 1 is a block diagram showing an example of an electronic timepiece for a camera according to the present invention, in which 1 is an oscillation circuit that oscillates a signal of a predetermined frequency, and 2 is an oscillation circuit that divides the oscillation output to produce a signal with a period of 1 second. A frequency divider circuit for obtaining pulses is shown, and a one-second pulse from this frequency divider circuit 2 is introduced into a time counter 3. The timekeeping circuit 3 consists of counters for seconds, minutes, hours, days, months, etc. The timekeeping contents of these counters are output as a BCD code, and sent to a monitor display device consisting of a liquid crystal via a decoder/drive circuit 4. 5, digital display is performed using a static drive method. Reference numeral 6 denotes a data latch that temporarily stores the time measurement contents of the counter such as seconds, hours, minutes, months, and days in the time counter 3 for each digit, and a control signal output from the input control circuit 7 when the camera shutter is pressed. The clock data of the time counter 3 is transferred to the data latch 6 by the clock counter 3, and the stored data for each digit in the data latch 6 is transferred to the clock from the frequency divider circuit 2 and the shutter input from the input control circuit 7. A digital display is sequentially outputted to a film imprinting display device 9 consisting of an LED through a decoder/drive circuit 8 controlled by a signal. In addition to the shutter input, signals from switches SW ₁ and SW ₂ are input to the input control circuit 7, and when the switches SW ₁ and SW ₂ are turned ON-
By turning it off, the contents of the time counter 3 can be corrected and the display mode displayed on each display device 5 and 9 can be changed. Reference numeral 10 denotes a battery voltage detection circuit that detects the voltage level of the battery voltage V _SS when the film imprinting display device performs the first light emitting operation. When the detection position is set by the signal output from the input control circuit 7 and a large current is applied to drive the film imprinting display device 9, the battery voltage is set to the specified value (the voltage required to drive the clock circuit). ), the system control circuit 11 determines whether it is below a specified value, and if it is below a specified value, the system control circuit 11 sends an operation stop signal to the decoder/drive circuit 8, and A display signal is sent to the decoder/drive circuit 4 to indicate that the display device 9 will not imprint on the film, and the monitor display device 5 will display this fact. Next, the operation of the present invention configured as described above will be explained. First, the normal display of the time, month, day, etc. is done by the monitor display device 5, but in this case, the count contents of the time counter 3 (time signal)
is outputted as a BCD code only to the decoder/drive circuit 4, thereby causing the count contents of the time counter 3, ie, hours, minutes, month and day, etc., to be digitally displayed on the monitor display device 5. At this time, the monitor display device 5 is driven by a static drive method. Furthermore, when the shutter button is pressed to display the counted contents of the time counter 3 on the film imprinting display device 9, a control signal is sent from the input control circuit 7 to the data latch 6, the decoder/drive circuit 8, and the battery voltage detection circuit 10. As a result, the time data of the time counter 3 is stored in the data latch 6 for each digit. The decode/drive circuit 8 is set to the operating state by the control signal from the input control circuit 7, and at the same time, the time data for each digit in the data clutch 6 is read by the clock introduced from the frequency divider circuit 2. The images are sequentially sent to the imprinting display device 9 through the decode/drive circuit 8 and digitally displayed using a dynamic drive method. Further, the time measurement data displayed on the display device 9 will be imprinted on the film. Fig. 2 schematically shows a timing chart of the above-mentioned film imprinting operation under normal conditions, in which a shows the shutter input waveform, b to d show the time-divided display digit drive signal waveform, and e shows the shutter input waveform. Further, f indicates the battery voltage detection pulse, and f indicates the battery voltage. In FIG. 2 above, after the shutter input, the first drive signal is applied to the display device 9, and the LED
When the device emits light for the first time, a detection pulse causes the battery voltage detection circuit 10 to enter an operating state, and detects a voltage drop caused by a large current flowing to drive the display device. At this time, if the ambient temperature of the battery is at room temperature (25°C) and the battery life has not yet come to an end, the voltage drop caused by driving the film imprinting display device 9 will be slight (because the internal impedance of the battery is small). ), the battery voltage level is maintained at a level as shown in FIG. Therefore, no output signal is sent from the system control circuit 11, and the display device 9 performs a normal film imprinting operation. On the other hand, if the time data imprint operation is performed when the battery is placed in a cold region where the ambient temperature is -10°C, or when the internal impedance of the battery has increased due to the end of its life,
When the shutter is pressed, the first drive signal is applied to the display device 9 after the shutter input (see Figure 3a), as in the normal operation above, and at the same time the LED starts emitting light, the detection pulse (3rd
As shown in Figure e), the battery voltage detection circuit 10 enters the operating position and detects the battery voltage accompanying the LED light emission. At this time, as is clear from the table above, since the internal impedance of the battery is large, when a large current flows for LED light emission in the display device 9, the drop in battery voltage due to this becomes larger than that under normal conditions. As a result, the battery voltage level drops below the specified value level L, as shown in FIG. 3f. Then, line 1 of the system control circuit 11
1a, a display stop signal having a waveform as shown in FIG. 3g is sent, and this signal is applied to the decode/drive circuit 8 to stop its operation. For this reason,
The first drive signal (FIG. 3b) supplied to the display device 9 becomes "L" midway through, and the second and subsequent drive signals (FIG. 3c, d) are no longer output. That is, if the battery voltage due to the voltage drop during the light emitting operation of the display device 9 for film imprinting is below the specified value, the light emitting operation of the display device 9 is immediately stopped, and the operation of the clock circuit due to the voltage drop is prevented. I'll try not to come. Simultaneously with the stop command to the imprint display device 9, a display command signal is introduced from the system control circuit 11 to the decode/drive circuit 4 through the line 11b, and even if the shutter is pressed, the contents of the time counter 3 are imprinted onto the film. The rare occurrences are displayed on the monitor display device 5. As a display means at this time, the entire display on the monitor display device 5 may be flashed, or a separately provided dedicated display section may be driven. As described above, according to the camera electronic clock of the present invention, the battery voltage is detected when the first light emitting operation of the film imprinting display device is performed after the shutter is input, and the battery voltage is detected thereafter when the other values are below the specified values. Since the light emitting operation of the film imprinting display device is stopped, even if the internal impedance of the battery has increased due to temperature changes, there will be no drop in battery voltage as in the past when taking photographs. If the clock circuit stops oscillating or
In addition, there is no possibility that the time counter, control circuit, etc. will malfunction. Further, since the stop of light emission of the film imprinting display device is displayed on the monitor display device, it is easy to determine whether or not to imprint timing data on the film.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an example of an electronic timepiece for a camera according to the present invention, and FIGS. 2 and 3 are timing charts illustrating the film imprinting operation in the present invention. DESCRIPTION OF SYMBOLS 1... Oscillation circuit, 2... Frequency division circuit, 3... Time counter, 4... Decoder/drive circuit, 5...
...Monitor display device, 6...Data latch, 7...
...Input control circuit, 8...Decoder/drive circuit, 9...Display device for film imprinting, 10...
...Battery voltage detection circuit, 11...System control circuit.

Claims (1)

[Claims] 1. A clock circuit consisting of an oscillator, a frequency divider, and a time counter, a monitor display device that digitally displays the count contents of the time counter, and a dynamic drive system that operates when the camera shutter is pressed to display the count contents of the time counter. a display device for digitally displaying a film; a battery voltage detection circuit for detecting a battery voltage when the first light emitting operation of the display device for film printing is performed after inputting the camera shutter; An electronic timepiece for a camera, comprising a control circuit that determines whether or not is below a specified value, and gives a command to the film imprinting display device to stop emitting light when it is below the specified value.