JPS59121640A - Method for detecting start and end terminals of tape - Google Patents

Abstract

PURPOSE:To reduce power consumption by using the difference of light transmissibility between a transparent tape and a magnetic tape on tape start and end terminal parts to detect a disturbance light level, and when the level is low, controlling a tape start and end terminal detector so that the sensitivity of a photodetecting element is increased and current flowing into a light emitting element is reduced. CONSTITUTION:To detect the tape start and end terminals, the disturbance light level is detected at first. In order to detect said level, a low level signal is sent from an output terminal 9 of a microcomputer 7 to turn off a current amplifier 8 and then turn off the light emitting diode LED1. Subsequently, a low level signal is sent from an output terminal 11 of the microcomputer 7 so that the sensitivity of a phototransistor PQ1 is increased and only low current is made flow into a light emitting diode LED1, and then the output of the 1st voltage comparator 2 is read from an input terminal 13 of the microcomputer 7 at the timing synchronizing with the period that the light emitting diode LED1 is on. The transparent tape is detected by changing the sensitivity of the phototransistor PQ1 and the current flowing into the light emitting diode LED1 in accordance with the strength of the influence of disturbance light.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention provides a method for detecting the beginning and end of a tape in a magnetic recording/reproducing device by utilizing the difference in the amount of light transmitted between a transparent tape and a magnetic tape provided at the beginning and end of the tape. It is related to.

Conventional configuration and its problems FIG. 1 shows the configuration of a conventional tape start/end detection system.

In Figure 1, (LED, ) is a light emitting diode,
(R1) is a resistor, +1) is a tape, and (PQI) is a tape Il that connects the light emitted from a light emitting diode (LED).
(R2) is a resistor d, +2 connected between the emitter terminal of the phototransistor (PQ1) and the ground.
1 is the voltage comparator, (3) is the output d of the voltage comparator (2)
(4) is the reference potential Va.

This is the power supply for supplying the voltage to the voltage comparator (2). That is, if the voltage comparator (2) sends a signal indicating that the tape is a transparent tape while the tape +11 is running, the sequential control circuit (3) operates to stop the running of the tape (1). do. FIG. 2 is an explanatory diagram of the characteristics of the basic phototransistor, showing the relationship between the illuminance L received by the phototransistor and the current ICE flowing between the collector emitter of the phototransistor.

A conventional method for detecting the beginning and end of a tape will be explained. Light emitted by the light emitting diode (LED θ) passes through the tape +11 and reaches the phototransistor (PQI).If the tape il+ is fixed with the transparent tape, a current ICE flows through the phototransistor (PQl) K, and the phototransistor ("QJ) The emitter potential Vp becomes low. Then, this potential Vp becomes higher than the reference potential ■a, and a signal is issued from the voltage comparator (2) to the control circuit and power, and tape running is stopped. If the tape +11 is a magnetic tape, the light emitted from the light emitting diode (LED) will hardly be received by the phototransistor (PQI) -1', and the potential VP will exceed the reference potential Va. In other words, the difference in light transmittance between transparent tape and magnetic tape was used to distinguish between transparent tape and magnetic tape.

Figure 5 shows the current ■D of the light emitting diode (LEDl) and the phototransistor (D) in the start/end detection circuit shown in Figure 1.
FIG. 3 is an explanatory diagram of the relationship between the emitter potential Vp of PQI) and the emitter potential Vp. In Figure 6, the solid line (A) indicates the phototransistor (
This graph shows the relationship between the twist and vp of a transparent tape under conditions where no disturbance light other than the light emitted from the light emitting diode (LED, ) has any effect on PQ□), and the solid line (b) indicates the disturbance light. This figure shows the relationship between Il) and vp on a magnetic tape under conditions where it is most affected by .

The reference potential Va is determined in consideration of the characteristics shown by solid lines (A) and (B). In other words, if va is set to a large value such as Va1, it will be strong against disturbance light, but the light emitting diode (IJ
'D,) If the current applied to
When set to a small value, the phototransistor (PQI) receives the disturbance light even on the magnetic tape, and
becomes high, making it impossible to distinguish it from transparent tape. When va is set as shown in FIG. 5, the light emitting diode (LEDj) K is required to flow a current of at least 18 or more.

FIG. 4, like FIG. 6, is an explanatory diagram showing the relationship between Il) and Vp in the circuit shown in FIG. 1, with the solid line (c)
The characteristics shown by the solid line (A) in Fig. 6 are the characteristics of the resistor (R2).
It shows the characteristics when the resistance value Rp is changed. That is, the solid line (c) represents the characteristics when the RpO value is larger than the characteristics shown in FIG. 5, and the solid line (c) represents the characteristics when the RpO value is small. Similarly, the curve of the influence of disturbance light on magnetic tape is
Depending on the value of Rp, the slope of the solid line (B) in Fig. 6 becomes flat, or
I stand up. That is, the sensitivity of the phototransistor (PQJ) is determined by the value of Rp.

In this way, if the resistance value 7 Rp is set to lower the sensitivity as shown by the solid line in Figure 4, the influence of ambient light can be reduced, but only one light emitting diode (LED)
It becomes necessary to increase the current flowing through the sensor, and if the resistance value Rp is set to increase the sensitivity as shown by the solid line (c) in Figure 4, the detection circuit will become unstable against ambient light. .

That is, in the past, constants were determined so as not to malfunction even under direct light on a sunny day in summer.

As a result, stability of the sensitivity of the phototransistor (PQ,) was ensured by lowering the resistance value Rp to lower the sensitivity and allowing a large current ID to flow. For this reason, Il
) will flow a large current of several tens of mA, and in reality, in order to reduce the current, light emitting diodes (LEDs) are intermittently connected.
, ). However, in such a conventional method, power is wasted because a large current flows in the same way even when there is no influence of ambient light such as indoors.

OBJECTS OF THE INVENTION The present invention solves the above-mentioned conventional drawbacks, and an object of the present invention is to provide a method for detecting the beginning and end of a tape, which can reduce power consumption.

Structure of the Invention In order to achieve the above object, the tape start/end detection method of the present invention utilizes the difference in light transmittance between a transparent tape and a magnetic tape provided at the tape start/end. A tape start/end edge detection method detects the tape start/end edge using a light receiving element provided to transmit emitted light through a tape and receive the light, and detects a disturbance light level, and when the level is small, the light receiving element detects the tape start/end edge. This is a configuration in which control is performed to increase the sensitivity of the element and reduce the current flowing through the light emitting element.

DESCRIPTION OF EMBODIMENTS An embodiment of the present invention will be described below based on one drawing.

FIG. 5 is a circuit block diagram of the tape start/end detection circuit, and the same components as those shown in FIG. 1 are given the same reference numerals and their explanations will be omitted.

(5) is a second voltage comparator; (6) is a power supply for providing the second reference potential VB t- to the second voltage comparator (5);
(7) is a microcomputer whose inputs are the output (e) of the first voltage comparator (2) and the output (6) of the second voltage comparator (5); (8) c microcomputer (7)
The light emitting diode (L
A current amplifier for lighting up ED,), (Q,) (
Ql) #i Output terminal αO of microcomputer (7)
A transistor (R3) that operates according to instructions from
c) Collector of transistor CQs) and light emitting diode (
A resistor (R4) is connected between the emitter of the phototransistor (PQl) and the collector of the transistor (Ql), (R'
5) is a transistor (Q,),! : A resistor connected between the output terminal α°C of the microcomputer (7).

FIG. 6 is a flowchart of the processing procedure for detecting the start and end ends performed by the microcomputer (7).

Figure 7 is an explanatory diagram of the relationship between the current flowing through a light emitting diode (LED) and the emitter potential Vp of a phototransistor (PQl). (Ql) In the case of the transparent tape when it is turned off, the solid line (F) is the solid line (E), and in the case of the magnetic tape in the same state as the solid line (G), the solid line (G) is the state when the transistor is strongly affected by ambient light. (Q,)
In the case of the transparent tape when turned on, the solid line (A) shows the case of the magnetic tape in the same state as the solid line (G).

FIG. 8 shows the potentials Vp and vb and the microcomputer (7
) is an explanatory diagram of the relationship with the input/output timing. (a) C is the output waveform from the output terminal (9) of the microcomputer (7), and the light emitting diode (LED, ) is turned on only during the period when this output is at a high level. Light. (b) shows the timing of reading the output signal of the second voltage comparator (5),
During the high level period, the output signal of the second voltage comparator (5) is input to the input terminal (6) of the microcomputer (7), and the input signal is latched until the next input signal is ready to be read. (C) shows the magnitude relationship between the potential Vp and the potential vb. (d) is the output waveform from terminal 00α of the microcomputer (7), and when this output is at a high level, @K) Rungis J (QJ) (Ql) is turned on. (e) shows the timing of reading the output signal of the first voltage comparator (2).
) is read into the input end (to). The timing of this reading is synchronized with the timing at which the light emitting diode (LED) lights up.

To detect the beginning and end of the tape, the level of disturbance light is detected.

Therefore, a low level signal is sent from the output terminal (9) of the microcomputer (7) to turn on the current amplifier (8).
Turn off the light emitting diode (LED).

t, send a low level signal from the output terminal α℃ of the microcomputer (7), and send it to the phototransistor (PQJ).
Increase the sensitivity. At this time, the microcomputer (7) reads the output of the second voltage comparator (5) from the input terminal at the timing shown in FIG. 8(b). If the potential Vp is lower than the potential Vb, the microcomputer (
7) Sends a signal from the output terminal (LOtll) of jc to turn off the transistor (Ql) (Ql). In this way, while the phototransistor (PQI) is heated to a high temperature, only a small current flows through the light emitting diode (LED), and the output of the first voltage comparator (2) is
As shown in Figure (e), a light emitting diode (LED,
) is lit from the input terminal (to) of the microcomputer [7] at a timing synchronized with the period when the light is on. If it is not affected by ambient light, the solid line (
Light emitting diode (LED)
, ), it is possible to distinguish between a magnetic tape and a transparent tape even with a small current if the current flowing through the tape exceeds the voltage 3 (Fig. 7). Conversely, if the influence of disturbance light is strong and the potential vp is higher than the potential vb, the output terminal flO of the microcomputer (7)
(11) Send a color high level signal 9, transistor (
Ql) (Q2) is turned on, and the phototransistor (PQ
The sensitivity of I) is lowered, the current flowing through the light emitting diode (LED) is increased, and the output of the first voltage comparator (2) is set at the same timing as the period when the light emitting diode (LEI) is lit. is read from the input terminal (to) of the microcomputer (7). In this way, when the influence of ambient light is strong, the characteristics shown by the solid lines (G) and (A) in Figure 7 are shown, so a current of 14 or more (Figure 7) should be passed through the light emitting diode (LED). Otherwise, magnetic tape and transparent tape cannot be distinguished.
As shown in Figure 6, photo effects vary depending on the influence of disturbance light.
Transistor (PQI) sensitivity, light emitting diode (LE)
The transparent tape is detected by changing the current applied to D,).

The output of the first voltage comparator (2) is connected to a light emitting diode (LE).
If the microcomputer (7) inputs data in synchronization with the period when D , ) is on, the period when one light emitting diode (LED , ) is off can be detected without incorrect information being input. It is reliable.

When a high level signal is input from the first voltage comparator (2) to the input terminal (to) of the microcomputer (7),
Control circuit (not shown) from microcomputer (7)
A command is issued to stop tape running. Input end (
When a low level signal is input to (to), detection of the beginning and end of the tape is performed successively. When the tape il+ is a transparent tape, the level of disturbance light is higher than when it is a magnetic tape. Therefore, if the tape ill is a transparent tape than the start and end search start, the potential Vp may become even higher than the height of the light emitting diode (LED , ), but as you can see from the processing procedure in Figure 6, it is immediately detected that it is a transparent tape, so the current consumption of the light emitting diode (LED , ) is reduced. has little effect on the increase in

Note that in the above embodiment, the transistor (Ql) (Q
2), we have explained an example in which the two output terminals (10ell) of the microcomputer (7) are used to control the microcomputer (7), but since the timing of these two outputs is exactly the same, output terminal 1 [1◇ is It may be shared as two output terminals.

DETAILED DESCRIPTION OF THE INVENTION According to the present invention, it is determined whether the influence of ambient light is strong or not, and when the influence is weak and not strong, the current consumption of the light emitting element is controlled to be reduced. By taking into account the influence of incidentally occurring ambient light, such as when the influence of ambient light is small, it is possible to reduce power consumption compared to when a large current is passed through the light emitting element in the same way as when the influence of ambient light is large. .

[Brief explanation of drawings]

Figure 1 is a circuit block diagram of the tape start/end detection circuit used in the conventional method, Figure 2 is an explanatory diagram of the relationship between the received light intensity of the phototransistor and the current flowing between its collector emitter, and Figure 6 is the disturbance caused by the conventional method. An explanatory diagram of the relationship between Il) and Vp in the case of transparent tape under conditions where there is little influence of light and in the case of magnetic tape under conditions where it is strongly influenced by disturbance light. Figure 4 shows the light reception of the phototransistor. An explanatory diagram of the relationship between Vp and Vp, which changes depending on the magnitude of sensitivity,
Fig. 5 is a circuit block diagram of a tape start/end detection circuit used in an embodiment of the present invention, Fig. 6 is a flowchart of a tape start/end detection method in an embodiment of the present invention, and Fig. 7 is an influence of ambient light. ID when strongly affected and when not
FIG. 8 is an explanatory diagram of the relationship between the disturbance light level and the input/output timing of the microcomputer. +1+...Tape, (2) (5)...Voltage comparator, (7)...Microcomputer, (8)...Current f@ width meter, (LED, )...Light emitting diode, (
PQI)...Phototransistor agent Mori
Yoshihiro Moto Figure 1 Figure 2 rF Figure 4 D Chiku R Figure 5 Figure 27 υ μ Figure 7 Figure 3-Cause

Claims (1)

[Claims] 1. Utilizing the difference in light transmittance between the transparent tape and the magnetic tape provided at the beginning and end of the tape, a light emitting element and light emitted from the light emitting element are transmitted through the tape and received. A method for detecting the beginning and end of a tape by detecting the beginning and end of the tape using a light-receiving element provided to A tape start/end detection method that controls the current to be small. 2. When the light emitting element is turned off, the level of disturbance light is detected by the light receiving element, and if the level becomes small, the sensitivity of the light receiving element is increased and the light emitting element is turned on intermittently to reduce the current flowing to the light emitting element. A method for inspecting the beginning and end of a tape according to claim 1.