JP2002202856A - Data storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To overcome the problem that a data transfer speed can not be in creased when a USB-FDD is used as a bus-powered device. SOLUTION: In addition to a USB interface connector 17, and USB-FDD 10 is provided with a power connector 18. When the USB-FDD 10 is used as an internal device of a personal computer 2, the power connector 18 is engaged with a power connector 49 on the side of the personal computer 2 and it is used as a self-powered device. When voltage is applied to a terminal 48 of the power connector 49, the USB-FDD operates as the self-powered device and is controlled so as to have a high data transfer speed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a data storage device such as a USB-FDD.

[0002]

2. Description of the Related Art A floppy (registered trademark) disk device, that is, a USB-FDD, which conforms to a USB interface for easy connection with a host device, has already been used. As shown in FIG. 1, the USB-FDD 1 is used in the first mode in which the USB-FDD 1 is connected to the USB terminal 3 of the notebook computer 2 via the USB interface cable 4, and is detachably built in the personal computer 2. There is a second form to be performed. If the USB-FDD 1 that can be built-in can be used not only in the built-in format but also through the USB interface cable 4, the range of use can be advantageously expanded.

[0003]

SUMMARY OF THE INVENTION By the way, USB-F
When the power of DD1 is supplied using a power terminal for a bus-powered device included in the USB interface terminal, the maximum current is limited to 500 mA, and the USB-F
DD1 makes it difficult to record and reproduce data at high speed.

Accordingly, an object of the present invention is to provide a data storage device which can be used in the first and second modes and can obtain the first and second data transfer rates.

[0005]

SUMMARY OF THE INVENTION In order to solve the above problems and achieve the above object, the present invention can connect a host device to a first mode and also connect to a second mode. A data storage device, comprising: an interface terminal including a first power supply terminal and a signal terminal for connection to the host device in the first mode; and a power supply from the first power supply terminal. A second power supply terminal which can supply a large amount of power and is provided separately from the interface terminal; data transfer speed switching means for switching a data transfer speed in the data storage device; Detecting the presence or absence of a voltage at the power supply terminal, and when a signal indicating that there is no voltage at the second power supply terminal is obtained, the data transfer speed switching means is switched to the first transfer speed. And when a signal indicating that a voltage is present at the second power supply terminal is obtained, the data transfer rate switching means is switched to a second transfer rate higher than the first transfer rate. And a switching control means for controlling so as to obtain the data storage device.

According to a second aspect of the present invention, the data storage device performs data conversion using a recording medium disk, and the data transfer speed switching means controls the data conversion speed of the disk. It is desirable to be able to switch. Further, as set forth in claim 3, the interface terminal is a USB interface terminal,
Further, when a signal indicating that there is no voltage at the second power supply terminal is obtained, the host device is notified that the device is a bus-powered device, and a signal indicating that a voltage is present at the second power supply terminal is output. It is desirable to have means for notifying the host device that the device is a self-powered device when it is obtained.

[0007]

According to the present invention, when a voltage is supplied to the second power supply terminal, the data transfer speed is automatically switched to a high speed based on this detection. Therefore, the data transfer speed can be easily switched.

[0008]

Next, an embodiment of the present invention will be described with reference to FIGS.

FIG. 2 shows a USB-FDD1 as a data storage device which can take the two forms of use shown in FIG.
Indicates 0. The USB-FDD 10 includes a motor 12 for rotating a recording medium disk 11, a control drive circuit 13 for the motor, a magnetic head 14 as a signal converter, and a feeder for moving the head 14 in the radial direction of the disk 11. (Not shown), recording / reproducing circuit 15, control circuit 1
6, USB connector 17, power connector 18, voltage detection line 19 as voltage detection means, power switch 2
Has zero.

The head 14 includes a recording / reproducing coil 21 and an erasing coil 22. The head 14 contacts the recording medium magnetic disk 11 to record and reproduce data by a known method.

The recording / reproducing circuit 15 includes a reproducing circuit 23, a recording circuit 24, and an erasing circuit 25. The reproduction circuit 23 connected to the recording / reproduction coil 21 of the head 14 includes a reproduction amplification circuit 26, a waveform shaping circuit 27 including a filter and the like, and a time domain filter or TDF 28. The reproduction amplifier circuit 26 includes an operational amplifier 29 and first, second, third, fourth, fifth, and sixth resistors R1, R2, R3, R
4, R5 and R6, and gain changeover switches 30 and 31. When the switches 30 and 31 are off, the reproduction signal is amplified by the first gain, and when the switches 30 and 31 are on, the reproduction signal is reproduced by the second gain. Amplify the signal.

The recording circuit 24 includes a current source circuit 32 and first and second transistors 33 and 34 for selectively connecting the current source circuit 32 to the coil 21. Transistors 33 and 34
Turns on / off in response to a recording pulse to supply a recording current to the coil 21. The current source circuit 24 is a circuit capable of switching a recording current value.

The erasing circuit 25 comprises an erasing current source circuit 35 and a transistor 36 which connects the erasing current source circuit 35 to the coil 22 at the time of erasing. The erase current source circuit 35 is a circuit that can switch the erase current value.

The control circuit 16 executes various controls of the FDD, and includes a clock generator 37 for controlling the spindle motor 12 and a self-powered notifying means 38. Although not shown in FIG. 2, a seek control circuit, a recording data supply circuit, a reproduction data transmission circuit, and the like are also included.

The UBS interface connector 17 comprises:
It has four interface terminals including a first power supply terminal 39, a positive signal terminal 40, a negative signal terminal 41, and a ground terminal 42. The interface connector 17 on the FDD side is connected to the F2 of the personal computer 2 schematically shown in FIG.
It can be connected to the DD built-in connector 43 and can be connected to the connector 3 of the personal computer 2 using the USB cable 4 shown in FIG. FDD of personal computer 2
The built-in connector 43 is a terminal 3 of the FDD connector 17.
Terminals 44, 45, 4 to which 9, 40, 41, 42 are connected
6, 47. When using in built-in form,
Since there is no need to supply power to the first power supply terminal 39,
The terminal 44 on the personal computer side can be omitted. FDD10
The power supply connector 18 on the side has a second power supply terminal 48 for supplying a power supply voltage of +5 V for driving the self-powered device. The power supply connector 18 is disposed adjacent to the USB interface connector 17 and is connected to the FD.
When the D10 is used in a built-in mode, it is connected to the power supply connector 49 of the personal computer. When the D10 is used as a non-built-in self-powered device, it is connected to a power supply (not shown) for a self-powered device. It is not used when the FDD 10 is connected to the personal computer 2 using only The second power supply terminal 48 is connected to the first power supply terminal 3.
It has a power capacity larger than 9 and can drive the FDD 10 to the second data transfer rate.

The first power supply terminal 39 of the interface connector 17 is connected to the changeover switch 20 as power supply selection means, the positive signal terminal 40 and the negative signal terminal 41 are connected to the control circuit 16, and the ground. The terminal 42 is connected to the ground.

The changeover switch 20 has a first power supply terminal 39.
And a second contact b connected to the second power supply terminal 48, and outputs the voltage of the first or second power supply terminal 39 or 48 from the output terminal C. . The output terminal C of the power switch 20 is connected to the motor control drive circuit 1
3, the head 14, and the recording / reproducing circuit 15 are connected to respective power supply terminals. Therefore, the output terminal C functions as an input terminal of the power supply circuit of the FDD. The changeover switch 2 shown in FIG.
0 has a drive coil 50 connected to the power supply voltage detection line 19, and the second
Is turned on, and when there is no voltage, the first contact a is turned on.

The voltage detection line 19 is connected to the second power supply terminal 48.
Is connected, and a resistor R is connected between the second power supply terminal 48 and the ground. The voltage detection line 19 functions as switching control means. That is, the voltage detection line 19
When there is a power supply voltage, this voltage is used as a control signal for setting a relatively high second data transfer rate. The voltage detection line 19 is connected to the control circuit 16, the changeover switch 20, the reproducing circuit 23, the recording circuit 24, and the erasing circuit 25, respectively. Voltage detection line 1
When there is a voltage at 9, the FDD 10 is driven as a self-powered device capable of high-speed data transfer. That is,
When the voltage on the voltage detection line 19 is higher than a predetermined value,
The clock generator 3 responds to the voltage of the voltage detection line 19.
7, the rotation frequency of the motor 12 increases. When a voltage is present on the voltage detection line 19, the self-power notifying means 38 built in the control circuit 16 creates a signal indicating the self-powered device and sends it to the host device via the signal terminals 40 and 41. And a reproduction circuit 2 so that data can be transferred at a second transfer rate higher than the first transfer rate.
3 switches 32, 31, waveform shaping circuit 27, TDF2
8. Current source circuit 32 of recording circuit 24 and erasing circuit 25
Of the current source circuit 35 is controlled.

This embodiment has the following effects. (1) When the USB-FDD 10 is used as a built-in drive of the personal computer 2 and the personal computer 2 supplies a voltage for a self-powered device to the second power supply terminal 48, it responds to the voltage of the voltage detection line 19. The changeover switch 20 supplies the voltage of the second power supply terminal 48 as the power supply voltage of each part of the FDD 10, controls the head 14, the recording / reproducing circuit 15, and the control circuit 16 to the second data transfer state, and A self-powered device is notified to a personal computer as a host device. Therefore, when the FDD 10 is used in a self-powered mode, data transfer, that is, data recording or reproduction can be performed at high speed. (2) Since the presence or absence of the voltage on the power supply voltage detection line 19 is used for the control of the changeover switch 20 and the changeover control of the data transfer speed, the changeover control circuit is simplified. (3) Since the FDD 10 can be used in both a bus power device form and a self-powered device form, the use range is widened.

[0020]

[Modifications] The present invention is not limited to the above-described embodiment, and for example, the following modifications are possible. (1) As shown in FIG.
A plurality of taps 51, 52, 53, 54 are provided in one, and taps 51 to 54 can be selected by changeover switches 55, 56 and connected to recording / reproducing signal lines 57, 58. The switches 55 and 56 are switched by the voltage of the power supply voltage detection line 19. For example, when there is no voltage on the line 19, the contacts a of the switches 55 and 56 are turned on to connect the taps 51 and 52 to the lines 57 and 58.
When there is a voltage on the line 19, the contacts b of the switches 55 and 56 are turned on to connect the taps 53 and 54 to the lines 57 and 58. (2) As shown in FIG. 4, the changeover switch 20 of FIG. 2 can be replaced with a switch circuit 20a composed of, for example, first and second semiconductor switches Q1, Q2 composed of transistors. Control circuit 61 of first semiconductor switch Q1
Is formed to turn on the first semiconductor switch Q1 when there is no voltage on the voltage detection line 19. The control circuit 62 of the second semiconductor switch Q2 is connected to the voltage detection line 19
Is formed to be turned on when a voltage is present. In addition,
A backflow preventing diode can be connected in series to the switches Q1 and Q2. If no voltage is supplied to the first power supply terminal 39 when a voltage is supplied to the second power supply terminal 48, the first switch Q1 can be omitted. (3) The changeover switch 20 is replaced with a switch circuit 20b composed of first and second backflow preventing diodes D1 and D2 in FIG.
Can be replaced by In the case of FIG. 5, the host-side device is configured so that the voltage is not simultaneously supplied to the first and second power supply terminals 39 and 48. The first power supply terminal 3
If backflow prevention to the side 9 is unnecessary, the diode D1 can be omitted. (4) Although the voltage of the second power supply terminal 48 is directly used for switching control of the data transfer speed, the second power supply terminal 48
To the second power supply terminal 48
And outputs the same as the control signal. (5) The present invention can be applied not only to the USB-FDD but also to a similar data storage device.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a relationship between a personal computer and a USB-FDD.

FIG. 2 is a circuit diagram showing a part of a USB-FDD and a personal computer according to the embodiment of the present invention.

FIG. 3 is a circuit diagram showing a recording / reproducing coil according to a modification.

FIG. 4 is a circuit diagram showing a power supply changeover switch circuit of a modified example.

FIG. 5 is a circuit diagram showing another power supply changeover switch circuit of a modified example.

[Explanation of symbols]

 2 Personal computer 11 Disk 12 Spindle motor 14 Head 17 UBS connector 18 Power supply connector 19 Power supply voltage detection line 20 Power supply switch 39 First power supply terminal 48 Second power supply terminal

Claims (3)

[Claims] 1. A data storage device that can be connected to a host device in a first mode and can also be connected to a second mode, wherein the data storage device is connected to the host device in the first mode. The first to do
An interface terminal including a power supply terminal and a signal terminal, and a second power supply terminal capable of supplying a larger power than the power supply from the first power supply terminal and provided separately from the interface terminal A data transfer rate switching means for switching a data transfer rate in the data storage device; and a signal for detecting the presence or absence of a voltage at the second power supply terminal and indicating that there is no voltage at the second power supply terminal. When the data transfer rate is obtained, the data transfer rate switching means is controlled to obtain the first transfer rate. When a signal indicating that a voltage is present at the second power supply terminal is obtained, the data transfer rate switching means is controlled. A switching control means for controlling the switching means to obtain a second transfer rate higher than the first transfer rate. 2. The data storage device performs data conversion by using a recording medium disk, and the data transfer speed switching means switches the data conversion speed of the disk. The data storage device according to claim 1, wherein 3. The interface terminal is a USB interface terminal. Further, when a signal indicating that there is no voltage at the second power supply terminal is obtained, the interface terminal notifies the host device that the device is a bus-powered device, When a signal indicating that a voltage is present at the second power supply terminal is obtained,
3. The data storage device according to claim 1, further comprising means for notifying the host device that the device is a self-powered device.