JPH0458669B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides a floppy disk drive device that can switch and set the rotational speed of a magnetic disk in two stages, and The present invention relates to a drive control method for a floppy disk drive device in which the rotational speed of a magnetic disk in the device is switched and set from an external control unit.

[Prior Art] A floppy disk used as a magnetic disk in a floppy disk drive device has different speeds of rotation for recording/reproduction and current of a write circuit depending on the type of magnetic layer formed on its recording surface. There are some that have different values specified. For example, regarding the rotation speed, there are 300 rpm and 360 rpm. Therefore, data recorded in 300 rpm mode must be played back in 300 rpm mode.

Therefore, some floppy disk drive devices are designed to change the rotation speed of the magnetic disk depending on the type of floppy disk or the writing mode. FIG. 5 shows an example in which two such floppy disk drive devices (FDD) 1 and 2, which can switch and set the rotational speed of a magnetic disk, are connected to a host computer 3. The host computer 3 sends drive select signals 0 and 1 to each floppy disk drive device 1 and 2 indicating that the device has been selected, and also sends a signal common to each floppy disk drive device 1 and 2. One mode selection signal MS is then sent out. This mode selection signal is a signal for selecting and setting the rotation speed of the magnetic disk in each floppy disk drive device 1, 2. For example, in the case of H level, it is set to 360 rpm, and in the case of L level, it is set to 300 rpm. .

A time chart of each drive select signal 0, 1 and mode selection signal MS when copying data between floppy disks with different rotational speeds using such two floppy disk drive devices 1 and 2 is shown below. It is shown in FIG. First, a predetermined amount of data is read from the 360 rpm floppy disk drive device 1 during period T ₁ , and then during period T ₂ .
The data is written to the floppy disk drive device 2 at 300 rpm. Furthermore, the next predetermined amount of data is read from the floppy disk drive device 1 again in a period _T3 , and written to the floppy disk drive device 2 in a period _T4 .

[Problems to be Solved by the Invention] However, when copying data between floppy disks with different rotational speeds as described above, each time the mode selection signal MS is converted, both floppy disk drive devices The rotation speeds of magnetic disks 1 and 2 change simultaneously. Therefore, every time data is written or read, a waiting time ΔT is required until the number of rotations of the magnetic disk reaches a normal value. As a result, the waiting time for data processing increases and copying efficiency decreases.

The present invention has been made based on the above circumstances, and its object is to transmit this mode selection signal to the signal input path to each floppy disk drive device for switching and setting the rotation speed. By inserting a temporary memory logic circuit, the rotational speed of each magnetic disk in multiple floppy disk drive devices can be controlled to different values at the same time, eliminating the waiting time caused by changing the rotational speed. It is an object of the present invention to provide a drive control method for a floppy disk drive device that can improve data copying efficiency between floppy disks having a rotational speed of 1.

Another object of the present invention is to provide a floppy disk drive device that makes it possible to control the rotational speed of a magnetic disk as described above.

[Means for Solving the Problems] The drive control method for a floppy disk drive device of the present invention includes a plurality of floppy disk drive devices in which the number of rotations of a magnetic disk is switched between two levels based on a mode selection signal from an external control unit. In the floppy disk drive device, a signal input terminal D is connected to the signal input path of the mode selection signal for each floppy disk drive device.
A mode selection signal is input to the trigger input terminal T.
A D-type flip-flop circuit is inserted into which the drive select signal sent from the external control unit is input, and the output signal of the output terminal Q is used as a new mode selection signal. A signal is sent out, and then a mode selection signal to the corresponding floppy disk drive device is sent out.

In another invention, the mode selection signal is input to the signal input terminal D, the drive select selection signal is input to the gate input terminal G, and the mode selection signal is input to the signal input path for each floppy disk drive device. A bi-table latch circuit that uses the output signal of the output terminal Q as a new mode selection signal is inserted, and a drive select signal is first sent to an arbitrary floppy disk drive, and during the sending period, the corresponding floppy disk drive is A mode selection signal corresponding to the device is sent out.

Yet another invention is a floppy disk drive device in which the above-mentioned bistable latch circuit is inserted in the signal input path for the mode selection signal.

[Function] In the drive control method of the floppy disk drive device configured as described above, in the D-type flip-flop, the Q output terminal receives an input to the D input terminal before the trigger is input to the T input terminal. The input timing of the drive select signal input to the T input terminal is
By slightly delaying the input timing of the mode selection signal input to the D input terminal, the output signal of the D-type flip-flop added to each floppy disk drive, that is, the mode selection signal input to the floppy disk drive The level can always be maintained constant. Furthermore, if a drive select signal is first sent to an arbitrary floppy disk drive device, and then a mode selection signal is sent to the corresponding floppy disk drive device, the level of this mode selection signal will be the same as the output signal of the corresponding D-type flip-flop. Become.

Further, in another invention, the bis table latch circuit outputs data at the D input terminal during a period when an H level signal is input to the G input terminal;
During a period when no signal is input to the input terminal, the data that was input to the D input terminal during the previous signal input period is output. Therefore, the switching timing of each drive select signal applied to the G input terminal of the vice-table latch circuit in each floppy disk drive device is distributed to both sides of the switching timing of the mode switching signal applied to the D input terminal. As a result, the level of the output signal of the bi-table latch circuit added to each floppy disk drive device, that is, the mode selection signal input to each floppy disk drive device, can always be maintained constant. Furthermore, if a drive select signal is first sent to a given floppy disk drive, and then a mode selection signal is sent to the corresponding floppy disk drive during this sending period, the level of this mode selection signal changes to that of the corresponding device. This becomes the output signal of the table latch circuit.

Furthermore, with another floppy disk drive device, by providing the above-mentioned bis-table latch circuit, even if the mode selection signal sent from the external control section changes midway, the magnetic disk of this device is The correspondingly set mode selection state (rotation speed) does not change.

[Example] An example of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the main parts of a floppy disk drive device related to the drive control method of the embodiment. Note that the overall block diagram including the host computer 3 as an external control section is the same as that in FIG. 5, so a description thereof will be omitted. The mode selection signal MS sent from the host computer 3 is input to the D input terminal of the D-type flip-flop (7474) 4, and the drive select signal also sent from the host computer 3 is input to the T input terminal of the flip-flop 4 via the inverter 5. A central processing unit (CPU) 6 receives input to the input terminal and controls the operation of this floppy disk drive device.
is input. The signal output from the Q output terminal of flip-flop 4 is input to CPU 6 as a new mode selection signal.

When the power of this device is turned on, the CPU 6 sends a motor-on signal to the SP motor drive circuit 8, which drives the spindle motor 7 that rotates the magnetic disk, to start the spindle motor 7. Further, when the CPU 6 receives an L level drive select signal, it sends a gate signal to the write/read circuit 10 of the magnetic head 9 to execute information writing/reading to/from the magnetic disk.

Further, the CPU 6 controls the speed of the SP motor through the SP motor speed switching circuit 11 according to the signal level of the mode selection signal input from the Q output terminal of the flip-flop 4.
Sends a speed control signal to the SP motor drive circuit 8.
At the same time, a current value switching signal is sent to the write/read circuit 10. In other words, the input mode selection signal
When MS is H level, the rotation speed of the magnetic disk is
It is set to 360 rpm, and in the case of L level, it is set to 300 rpm.

FIG. 2 is a time chart showing the operation of the same embodiment. That is, when the power to the floppy disk drives 1 and 2 shown in FIG. Start rotating.
When the power is turned on, each drive select signal 0, 1 output from the host computer 3 is at H level. Then, first from time t ₀ to time t ₂
The drive select signal 0 goes to L level until then, and the mode selection signal MS goes from time _t1 to time _t3 .
goes to L level and the other drive select signal 1 goes to L level from time _t2 to time _t4 , the Q output terminal of flip-flop 4 of floppy disk drive device 1 remains at H level, and the other drive select signal 1 goes to L level from time t2 to time t4. The Q output terminal of the flip-flop 4 of the disk drive device 2 is low at time _t1 .
Change to level. Therefore, the rotation speed of the floppy disk drive device 1 remains at 360 rpm, and the rotation speed of the floppy disk drive device 2 decreases to 300 rpm. This completes the selection and setting of the rotational speed for each floppy disk drive device 1, 2. Thereafter, the host computer 3 controls the switching timing of each drive select signal 0, 1 to always delay the switching timing of the mode selection signal MS by a minute time Δt. As a result, the signal level at the Q output terminal of each flip-flop 6 can be maintained constant regardless of the level change of the mode switching signal MS sent from the host computer 3, as shown in the figure. Therefore, the rotational speed of each floppy disk drive device 1, 2 is also maintained at the initially set rotational speed.

In this way, even if the level of the mode selection signal MS changes, the rotational speed of each floppy disk drive device 1, 2 does not change, so there is no need to provide the waiting time ΔT in the conventional method shown in FIG. As a result, the efficiency of data copying between floppy disks having different rotational speeds can be improved.

FIG. 3 is a block diagram showing a floppy disk drive device related to a drive control method and device according to another embodiment of the present invention. In this embodiment, the D-type flip-flop 4 of the embodiment of FIG.
It has been replaced with . That is, the mode selection signal MS is input to the D input terminal, and the drive select signal via the inverter 5 is input to the G input terminal.

FIG. 4 is a time chart showing the operation of the same embodiment. When the power is turned on, the time chart is the same as the time chart in FIG. First, from time _t0 to time _t1 , drive select signal 0 becomes L level, and from time _t3 to time t5, mode selection signal MS becomes L level, and the other drive select signal MS becomes L level from time t3 to time _t5 .
When the select signal 1 goes to L level from time _t2 to time _t4 , the floppy disk drive device 1
The Q output terminal of the vice table latch circuit 12 of the other floppy disk drive device 2 remains at the H level, and the Q output terminal of the vice table latch circuit 12 of the other floppy disk drive device 2 changes to the L level at time _t3 . . Therefore, similarly to the embodiment of FIG. 2, the rotational speed of the floppy disk drive device 1 remains at 360 rpm, and the rotational speed of the other floppy disk drive device 2 decreases to 300 rpm. This completes the selection and setting of the rotational speed for each floppy disk drive device 1, 2.

After that, when converting the level of each drive select signal DS, as shown in the figure, the period T _M during which the mode selection signal MS continues to be at the L level is the drive select signal DS.
Period T _A during which select signal 0 continues to be at H level
and drive select signal.
The host computer 3 controls so that the period T _B during which DS1 continues to be at L level is included in the period T _M during which the mode selection signal MS continues to be at L level.
As a result, similar to the embodiment shown in FIG. 2, the signal level of the Q output terminal of each vice table latch circuit 12 can be maintained constant regardless of the level change of the mode switching signal MS sent from the host computer 3. . Therefore, the rotational speed of each floppy disk drive device 1, 2 is also maintained at the initially set rotational speed. As a result, it is possible to obtain substantially the same effects as in the embodiments described above.

Furthermore, in this embodiment, as shown by the dotted line A in FIG. , the output signal of the vice-table latch circuit 12 of the floppy disk drive device 2 is also indicated by B in the figure.
It becomes H level as shown by , and the rotation speed can also be changed from 300 rpm to 360 rpm as shown by C in the figure. Therefore, it is possible to quickly respond to cases where it is necessary to change the rotational speed of the magnetic disk midway, and the range of applications is further expanded.

[Effects of the Invention] As explained above, according to the drive control method for a floppy disk drive device of the present invention, the signal input path to each floppy disk drive device for a mode selection signal for switching and setting the rotational speed of a magnetic disk is controlled. A logic circuit such as a flip-flop or a bi-table latch circuit is inserted to temporarily store this mode selection signal. Therefore, the rotational speed of the magnetic disks of multiple floppy disk drive devices can be controlled to different values at the same time.
Since the waiting time caused by changing the rotation speed can be eliminated, data copying efficiency between floppy disks having different rotation speeds can be improved.

Furthermore, a floppy disk drive device capable of controlling the rotational speed of a magnetic disk as described above could be obtained.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the main parts of a floppy disk drive device related to a drive control method for a floppy disk drive device according to an embodiment of the present invention, and FIG. 2 is a time chart showing the operation of the same embodiment. FIG. 3 is a block diagram showing the main parts of a floppy disk drive device and a drive control method for the floppy disk drive device according to another embodiment of the present invention, and FIG. 4 is a time diagram showing the operation of the same embodiment. FIG. 5 is a block diagram showing the entire drive control system for a floppy disk drive including a host computer, and FIG. 6 is a time chart showing a conventional drive control method for a floppy disk drive. 1, 2...Floppy disk drive device,
3...Host computer (external control unit), 4...
...Flip-flop, 5...Inverter, 6...
CPU, 7... spindle motor, 9... magnetic head, 12... vice table latch circuit,
DS...Drive select signal, MS...Mode selection signal.

Claims (1)

[Scope of Claims] 1. Executes writing and reading of information to and from a magnetic disk in response to a drive select signal inputted from an external control unit indicating that this device has been selected, and at the same time executes reading and writing of information to a magnetic disk. In a method for driving and controlling a plurality of floppy disk drive devices in which the rotational speed of the magnetic disk is switched between two stages using a mode selection MS signal, the mode selection signal is input to each of the floppy disk drive devices. On the other hand, the mode selection signal is input to the signal input terminal D, the drive select signal is input to the trigger input terminal T, and the output signal from the output terminal Q is passed through a D-type flip-flop circuit which uses the output signal as a new mode selection signal. 1. A drive control method for a floppy disk drive device, comprising: first sending a drive select signal to an arbitrary floppy disk drive device, and then sending a mode selection signal to the corresponding floppy disk drive device. 2 Write and read information to and from the magnetic disk using the drive select signal input from the external control unit indicating that this device has been selected, and at the same time execute the read/write information to the magnetic disk according to the mode selection MS signal sent from the external control unit. In the method for driving and controlling a plurality of floppy disk drive devices in which the rotational speed of the magnetic disk is switched between two stages, a signal input terminal is connected to a signal input path for the mode selection signal to each of the floppy disk drive devices. The mode selection signal is input to D, the drive select signal is input to the gate input terminal G, and a bistable latch circuit is inserted that uses the output signal of the output terminal Q as a new mode selection signal. A drive control method for a floppy disk drive device, characterized in that a drive select signal is sent to the floppy disk drive device, and a mode selection signal corresponding to the floppy disk drive device is sent during the sending period. 3 Write and read information to and from the magnetic disk in response to the drive select signal input from the external control unit indicating that this device has been selected, and also read and write information to the magnetic disk in accordance with the mode selection MS signal sent from the external control unit. In a floppy disk drive device in which the rotational speed of the magnetic disk is switched and set in two stages, the signal input terminal D is inserted into the signal input path of the mode selection signal.
The mode selection signal is inputted to the gate input terminal G, the drive select selection signal is inputted to the gate input terminal G, and the bis table latch circuit is configured to use the output signal of the output terminal Q as a new mode selection signal. floppy disk drive device.