JPH0233715A - Envelope meter for dat - Google Patents

Abstract

PURPOSE:To quantitatively grasp a condition, in which a head traces a track on a tape, exactly deciding the result to control a mechanism part in a tape traveling system and to controlling in a short time by deciding the inclination of an envelope with an envelope meter for DAT. CONSTITUTION:An RF signal 1a, which is obtained by the head of the DAT with tracing the track on the tape, is inputted from an input terminal 1 of the envelope meter to an RF amplifier 2 and a signal to be amplifier by the amplifier 2 is detected by an envelope detector 3 and held to a sample-hold circuit 4. This circuit 4 and an A/D converter 5 are controlled by a microcomputer 6 and a digital voltage to be A/D converted and operated is displayed on a display 8. The envelope of the RF signal is measured by the computer 6 with using an envelope measuring means, which is composed of the circuit 4, converter 5 and computer 6, by plural times. Then, a maximum value and a minimum value are respectively obtained from a measured value. After that, the envelope is decided according to the display result of the display 8 by this obtained value.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to an envelope meter for AT, which is suitable for evaluating or adjusting the tape path of DAT.

(Example) Problems to be solved by the prior art/invention Conventionally, the adjustment of the DAT tape path has been performed by directly observing the RF and other signals obtained from the head of the DAT using an oscilloscope, and determining the minimum value from the slope of the envelope of the waveform. By intuitively recognizing the maximum value, the tracing state of the head on the track was judged, and adjustments were made based on the results of this judgment.

However, the above-mentioned conventional adjustment work relies on the feel and skill of the adjuster, and has the disadvantage that adjustment errors may occur depending on the adjuster, and that adjustment takes time.

The present invention has been made in view of the above-mentioned points, and its object is to provide an envelope meter for DAT that can quantitatively grasp the state of a tape bus.

(C) Means for solving the problem FIG. 5 is a functional block diagram of the present invention. An RF amplifier that amplifies the RF signal (X-), an envelope detection circuit that detects the output of this RF amplifier, a sunblink bold circuit that sunblinks and holds the output voltage of this envelope detection circuit, and this sampler. A DAT consisting of an A/D converter that converts the output voltage of the hold circuit into a digital voltage, a microcomputer that controls the sunblink bold circuit and the A/D converter, and a display that displays the calculation results of this microcomputer. In the envelope meter for use in Japan, there is an envelope measuring means for measuring the envelope of the RF vessel multiple times, a maximum value searching means for finding the maximum value from the measured values obtained by the envelope measuring means, and a measurement obtained by the envelope measuring means. Minimum value searching means for determining the minimum value from the values; and envelope determining means for determining the slope of the RF multiplied signal envelope based on the maximum value obtained by the maximum value searching means and the minimum value obtained by the minimum value searching means. It was established.

(d) Effect The operation of this invention will be explained using FIG. 5.

According to this invention, the DAT head includes an RF amplifier that amplifies the RF signal obtained by tracing the tracks of the tape 4, and a detector 1 that detects the output of this RF amplifier.
An envelope detection circuit that samples and holds the output voltage of this envelope detection circuit, a sampler bold circuit that samples and holds the output voltage of this envelope detection circuit, an A/D converter that converts the output voltage of this sampler hold circuit into a digital voltage, and a sampling halt circuit. An envelope measuring means for measuring an RF multiplied signal envelope multiple times in an envelope meter for DAT, which is composed of a microcomputer that controls a circuit and an A/D converter, and a display that displays the calculation results of this microcomputer. and maximum value searching means for finding the maximum value from the measured values obtained by the envelope measuring means, minimum value searching means for finding the minimum value from the measured values obtained by the envelope measuring means, and the maximum value searching means. Since the envelope determining means for determining the slope of the RF multiplied signal envelope based on the obtained maximum value and the minimum value obtained by the minimum value searching means is provided, it is possible to quantitatively grasp the state of the tape path. I'll come.

(P) Embodiment An embodiment of the envelope meter for DAT according to the present invention will be described with reference to FIGS. 1 to 5.

Figure 1 is a block diagram, Figure 2 is a timing diagram,
Figure 2 (A) is a waveform diagram of the head switching signal, Figure 2 (B)
is an RF double signal waveform diagram, Figure 3 (A) is a diagram schematically showing a state in which a track on a tape is traced from the head, and Figure 3 (B) is an RF signal waveform diagram corresponding to the tracing state (No. 2 waveform). 4A and 4B are flowcharts, and FIG. 5 is a functional block diagram.

In the figure, 1 is the RF obtained by tracing the DAT head (not shown) or the Chiputo track.
Input terminal for inputting double signal manually to this envelope meter, 1a is RF double signal 2 is RF (No. 3 R to amplify 1a)
F amplifier, 3 is an envelope detection circuit that detects the output of the RF amplifier 2, 4 is a sampling and hold circuit that samples and holds the output voltage of the envelope detection circuit, and 5 is a converter that converts the output voltage of the sampling and hold circuit 4 into a digital voltage. 6 is a microcomputer that controls the sunblink bold circuit 4 and the A/D converter 5, and also takes in the output of the A/D converter 5 and performs arithmetic processing; 7 is a DAT A and B; An input terminal for inputting the head switching signal of the head to the microcomputer 6, 7a is the head switching signal, 8 is a display for displaying the calculation results of the microcomputer 6, 9 is a display for driving the display 8 The circuit 10 is an operation switch for changing the display state of the display 8 (for example, data for A head, data for B head, etc.).

The sunblink hold circuit 4, A/D converter 5, input terminal 7, and operation switch 10 are connected via an input/output port of a microcomputer 6, and the microcomputer 6 is connected to the enherobe meter. It consists of a ROM that stores programs, a RAM that stores calculation results, and a timer that measures measurement timing.

In the enherobe meter configured as described above, the head switching signal 7a is input manually to the input terminal 7, and as shown in FIG. 2, the head switching signal 7a is an RF signal from the A head. “L” when 1a is obtained
level, when the RF Shingetsu 1a2 is obtained from the B head, the pulse signal of "H" level or the microcomputer 6
is now entered.

Note that the numbers 1 to 8 shown in FIG. As you did, it was measured 8 times.

FIG. 3(A) is a diagram schematically showing a state in which a head traces a track on a tape, and FIG. 3(B) is a diagram of an RF multiplied signal waveform obtained as a result of the tracing.

In the figure, TA is tape, t r Llli tape T
The track recorded on A, T is the running direction of the tape TA, and H is the head tracing direction.

When the head traces the track tr as shown in (2) in FIG. 3(A), RF signals having substantially equal heights as shown in (2) in FIG. 3(B) are obtained. Further, if traced as shown in ``■'' in FIG. 3(A), an RF multiplied signal with a downward slope to the right as shown in ``■'' in FIG. 3(B) will be obtained. This RF multiplied signal is a normal RF multiplied signal when the head starts tracing the track tr, but becomes an abnormal RF multiplied signal when the tracing ends.

Furthermore, when tracing is performed as shown in (■) in FIG. 3(A), an RF multiplied signal as shown in O in FIG. 3(B) is obtained. When this RF double signal head starts tracing the track tr, the RF (i-q waveform) is not normal, but when the tracing ends, it is a normal RF waveform.

Next, the operation of the above embodiment will be explained based on the flowcharts shown in FIGS. 4(A) and 4(B).

When the measurement is started, edges of the head switching signal 7a are detected (step Sl). If the edge is detected and the falling edge ■ is detected, the RF signal 1a obtained by
If a rising edge is detected, the edge is determined for measuring the RF signal 1a2 obtained by the B head (step S2), and then a timer is started (step S3). When a certain period of time has elapsed after the timer started (step S4), the microcomputer 6
In step S5), the A/D converter 5 is instructed to sample and hold the output of the envelope detection circuit 3.
starts an A/D conversion operation for converting the output voltage of the sampling and holding circuit 3 into a digital voltage (step S6). When A/D conversion is completed (step S7)
, the microcomputer 6 reads the output data of the A/D converter 5 (step S9), and sends this data to the RA.
The data is stored in M (step S9).

If head A is currently being measured, in the above state, the voltage of the envelope at point 1 of the RF signal 1a in FIG. 2 has been measured.

In this embodiment, since the above-mentioned envelope measurement is repeated eight times, steps S3 to S9 are repeated again. And RF(
The voltages of the envelope at points 2, 3° 4.5, 6, and 7.8 of No. M 1a are measured in order.

After completing the eight measurements of the RF signal 1a, the maximum value is first searched for from the measured data (step 5ly), then the minimum value is searched for (step 512), and then the maximum value is compared to the maximum value (step 512). Calculate the ratio of the minimum value (step 513)
). Then, it is determined whether the maximum value and the minimum value are detected in the left half or the right half of the RF signal in FIG. If the minimum value is detected with the right half R, the slope of the envelope is determined to be a downward slope as shown in the waveform diagram shown in Figure 3 (B), and the minimum value is detected with the left half R. If the maximum value or the right half R is detected, the slope of the envelope is determined to be at the lower left, since the waveform is as shown in ■ in Figure 3 (B).The above ratio and determination result are used. is displayed on the display 8, and the next measurement is performed again from step S1.

Note that in determining the slope of the envelope, data such that the maximum value and the minimum value are both detected in the left half of the RF signal, or both are detected in the right half R, or in step 51,
4, it is displayed on the display 8 as undeterminable.

In this way, according to the present invention, the slope of the envelope can be changed to Y
1], it is possible to quantitatively and accurately determine the state in which the head traces the track on the tape.

(f) Effects of the Invention According to the DAT envelope meter of the present invention, the state of the tape path of the DAT can be quantitatively grasped using the above-described configuration.

Therefore, if the mechanical part of the tape running system of a DAT deck is adjusted using the envelope meter for DAT according to the present invention, the adjustment can be made in a short time and without individual errors by the adjuster.

[Brief explanation of the drawing]

1 to 5 show an embodiment of an envelope meter for DAT according to the present invention, FIG. 1 is a block diagram, and FIG. 2 is a timing diagram.
Figure 2 (A) is a waveform diagram of the head switching signal, Figure 2 (B)
is a waveform diagram of an RF signal, and Figure 3 (A) is a diagram schematically showing the state in which a head traces a track on a tape.
FIG. 3(B) is a waveform diagram of the RF signal according to the trace state, 41:R](A) and FIG. 4(B) are flowcharts, and FIG. 5 is a functional block diagram. Explanation of main symbols 1.7: Input terminal 1a: RF signal 2: RF amplifier 3: Envelope detection circuit 4: Sampler hold circuit 5/A/D converter 6 Microcomputer 7a: Head switching signal 8, indicator 9 ;Display circuit IO: Operation switch Patent applicant Kenwood Co., Ltd. @ ■ @

Claims (1)

[Claims] An RF amplifier that amplifies an RF signal obtained by tracing a track on a tape by a DAT head, an envelope detection circuit that detects the output of this RF amplifier, and an envelope detection circuit that detects the output of this RF amplifier. A sampling and holding circuit that samples and holds the output voltage, and an A/D that converts the output voltage of this sampling and holding circuit into a digital voltage.
An envelope meter for DAT that is composed of a converter, a microcomputer that controls a sampling and holding circuit, and an A/D converter, and a display that displays the calculation results of this microcomputer measures the envelope of an RF signal multiple times. An envelope measuring means, a maximum value searching means for finding a maximum value from the measured value obtained by the envelope measuring means, a minimum value searching means for finding a minimum value from the measured value obtained by the envelope measuring means, and the maximum value searching means. 1. An envelope meter for DAT, comprising envelope determining means for determining the slope of an envelope of an RF signal based on the maximum value obtained by the means and the minimum value obtained by the minimum value searching means.