JPH079682B2 - Recording current rising waveform equalizing method and rising waveform equalizing device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to rising waveform equalization (transient current compensation) for speeding up the rising of the recording current in digital magnetic recording.
The present invention relates to a method and a rising waveform equalizer for implementing the method.

[Prior art]

Conventionally, the recording current of digital magnetic recording has a damping coefficient ζ of a secondary system determined by L, R, and C of about 0.7 in order to make it a rectangular wave. However, when attempting to realize a high-speed data transfer system using a magnetic head having a relatively large inductance such as a ferrite magnetic head, limitation of the rise time of the recording current is becoming a problem.

[Object of the Invention]

An object of the present invention is to perform a rising waveform equalizing method of a recording current capable of speeding up the rising time of a recording current of digital magnetic recording to about 1/2 that of a conventional method, and a rising waveform for implementing the method. It is to provide an equalizer.

[Structure of Invention]

According to the present invention, the direction of the current supplied to the magnetic head changes in the direction of the current determined by the change of the data signal only for a certain time after a certain time elapses from the time when the direction is switched corresponding to the change of the data signal. On the other hand, it is characterized by supplying a current in the opposite direction.

When the rising waveform equalization condition of the recording current is a special case, the hardware for controlling the direction of the supplied current simply uses a specific time width after a certain time has elapsed from the time of the change of the data signal. Only the logic gate for inserting the change of the pseudo data signal of is necessary, and the recording circuit itself can be a simple current switch.

When the present invention is applied, it is assumed that the damping coefficient ζ of the secondary resonance system based on the circuit parameters L, R, and C constituting the magnetic head system can be set to 0.707 or less. The two types of time described above are set within the time during which the transient vibration of the current that occurs when ζ = 0.707 occurs.

〔Example〕

Examples of the present invention will be described below. FIG. 1 is a diagram showing an embodiment thereof, and FIG.
(B) shows a timing chart of the operation. The same figure (a)
In the above, 4 is the inductance of the magnetic head, 5 is the damping resistance, and 6 is the capacitance including the wiring capacitance. Data signals 2 and 3 indicate the direction in which the current I _O determined by the constant current source 1 flows through the inductance 4. It is a first differential type current switch transistor for switching by. Further, 7 and 8 are currents (n + 1) I _O (where n ≧ 0) determined by the constant current source 11, and 9 and 10 are currents (n + 1) I _O determined by the constant current source 12, respectively. Is a second current switch transistor for supplying to the inductance 4 by. V _C1 , V _C2 , V _C3 , V _C4
Is a power supply terminal.

These are operated by a signal from a pulse signal generator (not shown) that generates a pulse signal in the timing chart shown in FIG. 1 (b). That is, from the time when the transistor 2 is turned on by the data signal Q _D,
During the time t ₀ after td has elapsed, the transistor 7 is turned on by the control signal Q _C1 . As a result, the oscillation of the transient current of the insufficient braking caused by the turning on of the transistor 2 is canceled out, and a non-oscillating rectangular transient current "if-ir" is obtained in a form in which the transient time of the insufficient braking current is kept short. be able to. Similarly, the inverted data signal From the time when the transistor 3 is turned on by the control signal Q _C2 during the time t ₀ after the time td elapses.
Turn 0 on.

By increasing the current value (n + 1) _IO of the constant current sources 11 and 12, the speed can be further increased. For example, when n = 5, the damping resistor 5 is normally adjusted and ζ =
It can be shortened to half the rise time of the transient current in the case of 0.707. The differential type current switching transistors 7 to 10 shown in FIG. 1A do not necessarily have to be the differential type. Further, the current value of the constant current sources 11 and 12 is set to nI _O , and the constant current source 1 is set to the inversion control signal. It may be configured to turn on / off at the OR output timing of. The transistor may be either a bipolar transistor or a field effect transistor.

FIG. 2 is a diagram showing a second embodiment, (a) shows its circuit configuration, and (b) shows an operation timing chart. In FIG. 2 (a), 13 and 16 are transistors for a differential type current switch, which determine the direction of a predetermined current. Reference numerals 14 and 15 are also transistors for differential type current switch, and it is possible to form a current path in a direction opposite to the current in the transistors 13 and 16 for differential type current switch. 17 and 18 is also a transistor differential current switch, the current value is connected to the constant current source 22 of the nI _O. 19 and 20 is a transistor for differential current switch, the current value is connected to the constant current source 21 of the nI _O. V
_C5 , V _C6 , and V _C7 are power supply terminals.

Also in this circuit, a control signal is generated in accordance with a signal from a pulse signal generator (not shown) for generating a pulse signal in the timing chart shown in FIG. 2 (b). To operate. That is, the data signal Q _D causes the transistor 15
Is turned on, and a transient current occurs due to the current ir flowing in the inductance 4. A transistor 19 forming a current path of the transistor 15 during a time t ₀ ′ after a certain time td ′ has passed since the transistor 15 was turned on.
_Is turned off by the control signal Q _C3 , and at the same time, the transistor 1
Inversion control signal through transistor 18 forming a current path of 3 By turning on the
to form a current path of the current if the current value nI _O flowing to the ir opposite direction. By forming a current path that flows only during the time t ₀ ′, suppressing the vibration associated with the change (polarity inversion) of the data signal as the “ir-if” current and causing a rectangular current transient transition. You can The set of current switch transistors 17 and 18 and the set of 19 and 20 do not necessarily have to be of the differential type.

FIG. 3 shows a third embodiment, (a) shows the circuit configuration, and (b) shows an operation timing chart.
This embodiment corresponds to the special case where n = 1 in the second embodiment, and is realized by modifying the change of the data signal as a result. That is, the change of the data signal corresponding to the control signal Q _C3 of FIG. 2B is realized by inserting it into the original data signal. This data signal And Reference numerals 23 and 24 are differential type current switching transistors, and 25 is a constant current source for the current I _O.

The present embodiment has an advantage that the structure is simple and the effect is relatively large without changing the basic circuit structure that has been often used in the past and simply adding some ingenuity to the data signal.

FIGS. 4 (a) and 4 (b) show experimental examples in which n = 1 in the cases of the first embodiment and the second embodiment, respectively. FIG. 4 (c) shows an experimental example of the third embodiment. The rise time is halved compared to the conventional example, and the rise speed is increased. The damping coefficient ζ of the system is about 0.2, and the times td, td ′, td ″, t ₀ , t ₀ ′, t ₀ ″.
Is about 20 ns. In the second embodiment, n is 1
With the above, it is possible to further increase the speed.

〔The invention's effect〕

As described above, according to the present invention, the rising waveform of the recording current of digital magnetic recording can be made to have a steep rising. Therefore, even when it is used for a magnetic head having a relatively large inductance, it is about 2 times as large as the conventional design. There is an advantage that double high-speed data transfer can be realized.

[Brief description of drawings]

FIG. 1 shows a first embodiment of the present invention, (a) is a circuit configuration diagram thereof, (b) is an operation timing chart, and FIG. 2 shows a second embodiment. ) Is its circuit configuration diagram, (b) is an operation timing chart, FIG. 3 shows a third embodiment, and (a) is its circuit configuration diagram.
FIG. 4B is an operation timing chart, and FIG.
(C) is a characteristic diagram showing experimental results. 1, 11, 12, 21, 22, 25 ... Constant current source, 4 ... Magnetic head inductance, 5 ... Damping resistance, 6 ... Magnetic head capacitance including wiring capacitance, (2,
3), (13, 16), (14, 15), ... a pair of current switch (first current switch) transistors for switching the direction of the current flowing to the magnetic head according to the data signal,
(7, 8), (9, 10) ... Transistor current compensation (equalization) current switch (second current switch) transistor pair, (17, 18), (19, 20) ... ( 13, 1
6), a pair of transistors for the current switch (second current switch) for switching the constant current source connection path of the current switch of (14, 15), (23, 24) ... by the data signal including the control signal A pair of current switch transistors for switching the direction of the current flowing through the magnetic head.

Claims (4)

[Claims] 1. A method for equalizing a rising waveform of a recording current supplied to a magnetic head for recording a data signal in a digital magnetic recording device, wherein the data signal is passed through a first current switch for switching the direction of the current. Of a current corresponding to the change of the magnetic head for a fixed time after a fixed time from the time,
A rising waveform equalizing method for a recording current, characterized in that a current in a direction opposite to a current corresponding to a change in the data signal is supplied to the magnetic head through a second current switch. 2. The supply of current corresponding to the change of the data signal by the first current switch is interrupted in synchronism with the supply of current in the reverse direction. The rising waveform equalizing method of the recording current according to the item 1. 3. A method of equalizing a rising waveform of a recording current supplied to a magnetic head for recording a data signal in a digital magnetic recording device, wherein a change of the data signal is caused through a current switch for switching a current flowing direction. The current switch is switched so that a current flows in a direction opposite to the direction of the current corresponding to the change in the data signal only for a certain time after a certain time has elapsed from the time when the corresponding current was supplied to the magnetic head. Equalizing method for rising waveform of recording current. 4. A rising waveform equalizer for equalizing a rising waveform of a recording current supplied to a magnetic head for recording a data signal in a digital magnetic recording device, in which a change in the data signal supplied to the magnetic head occurs. A first current switch corresponding to switching the direction of the recording current is provided, and a second current switch for supplying a current in a direction opposite to the direction of the current generated as a result of the switching of the first current switch to the magnetic head. A current signal is provided, and the pulse signal for switching the first current switch, and the second current so as to supply the reverse current only for a certain time after a certain time has elapsed from the time when the first current switch was switched. A rising waveform equalization device comprising a pulse signal generator for generating a pulse signal for switching a current switch.