KR100268463B1 - Recording capacity expanded harddisk drive - Google Patents

Abstract

PURPOSE: An HDD(Hard Disk Driver) having an increased recording capacity is provided to increase a recording capacity of a hard disk through converting a servo sector recorded in the hard disk. CONSTITUTION: After a servo sector-0 of a first type, an ID(Identification) area is arranged for recognizing data-0. Then, a servo sector-1 of a second type is allotted. After split data-1, ID-2, data-2, and ID-3, a servo sector-2 of the first type is allotted. After detecting a servo synchronization, a servo address mark is detected for generating a reference pulse. Then, a servo interrupt is generated after a specific time. Herein, the servo interrupt as a normal servo interrupt is generated in the servo sector of the first type having the servo address mark. At a stopped location of the servo sector of second type, a special servo interruption is generated. A servo gate signal is generated for including first and second type servo sectors. Moreover, a servo sampling signal is generated in a burst signal section of first and second type servo sectors.

Description

Hard disk drive with extended recording capacity

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of expanding a recording capacity of a hard disk drive (HDD), and more particularly, in a hard disk drive used as an auxiliary storage device of a computer, a servo repeatedly recorded in a predetermined period in a hard disk. The present invention relates to a hard disk drive having an increased recording capacity by extending the recording capacity of the hard disk drive by alternately deleting the gray code area used for track search among sectors and recording data information in the deleted gray code area.

The method of expanding the capacity of the hard disk drive can be realized by various techniques such as the recording density of the hard disk, the servo information, and the method of changing the read / write method. Among them, by using a method of changing servo information, it is intended to expand the user's information area in the capacity of a given hard disk, mainly by the technique of servo control.

Generally, a plurality of divided data sectors and servo sectors are provided on a hard disk, and predetermined servo information is recorded from the outside of the hard disk into the servo sector. In this case, the servo sector includes servo sync, servo address mark (SAM), index information, gray code, burst signals A, B, P, Q, and margin. It consists of a pad which is a section.

The servo synchronization is recorded at the point where the servo sector starts to match the synchronization of the system clock and the servo sector. In addition, the servo address mark has a unique form among the servo sectors, and when the servo address mark is detected, a microcontroller built in a personal computer generates a reference pulse to generate a signal necessary for servo control. Also, the index information is stored in order to generate one pulse in one rotation section. The gray code indicates a corresponding track number of the hard disk, and provides the central processing unit with the position of the target track to be read and recorded and the current position of the head mounted at the end of the actuator. On the other hand, the burst signals A, B, P, and Q are burst signals P, Q for performing track following so that the actuator can be located at the center of the target track of the designated hard disk in the servo control. And burst signals A and B for performing track seek to a target track on the hard disk. Of course, the burst signals A, B, P, and Q can all be used for fine adjustment after track tracking as the target track. The pad is a spare section for distinguishing the next data sector.

Therefore, according to the unique arrangement of the conventional servo sector, since the servo is controlled by using N servo sectors, as the hard disk drive becomes higher in capacity, the recording ratio of the data sector and the servo sector, that is, the servo sector additional information is increased. There is a problem that the user information area (data sector) is reduced.

Accordingly, an object of the present invention is to solve the above-described problem, and an object of the present invention is to change a recording state of a servo sector recorded on a hard disk, thereby to expand the recording capacity of the hard disk. In providing.

1 is a schematic block diagram of a hard disk drive with an expanded recording capacity according to the present invention.

2 is a diagram showing an arrangement state of a servo sector of a hard disk and a timing diagram thereof in a hard disk drive with an extended recording capacity according to the present invention.

3 is a diagram illustrating a magnetization state of a hard disk according to two types of servo sectors to which a hard disk drive having an extended recording capacity according to the present invention is applied.

4 is a view showing a servo sector arrangement state of a hard disk drive with an extended recording capacity according to the present invention.

<Explanation of symbols for main parts of drawing>

1: Hard disk assembly 2: Hard disk

3: head 4: central processing unit

5: Actuator 6: read / record channel

7: Servo synchronous generator 8: Servo address mark detector

9: reference pulse generator 10: main counter

11: analog / digital converter 12: next servo sector detection pulse generator

13: Servo gate timing generator 14: Automatic gain control holding signal timing generator

15: Servo Interrupt Timing Generator 16: Servo Sampling Timing Generator

A feature of the present invention for achieving the above object is a servo drive having a plurality of data sectors and a hard disc divided into servo sectors, wherein the servo synchronizer, servo address mark, index information, gray code information, and burst are used. A servo sector of a first type in which signals and pads are recorded, and a servo sector of a second type in which burst signals and pads are written; and a servo sector of the second type includes servo synchronizers, servo address marks, index information, and gray codes. It is to have a data sector sequentially divided so that separate information can be recorded as much as the recording capacity corresponding to the information.

In the aforementioned aspect of the invention, the servo address mark is detected after detecting the servo synchronization in the servo sector of the first type, and a reference pulse is generated at the time when the servo address mark is detected, and a predetermined time after the reference pulse is generated. It is preferable that a servo interrupt is generated after elapsed.

In addition, in the first type servo sector in which the servo address mark exists, a first servo interrupt is generated, and a second servo interrupt is generated at the point where the second type servo sector ends after the first servo interrupt occurs. It is preferable.

Best Mode for Carrying Out the Invention A preferred embodiment of a hard disk drive with an increased recording capacity according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram of a hard disk drive with an extended recording capacity according to the present invention.

As shown, when a track seek command for transferring the head 3 from the host computer to the target track of the hard disk 2 mounted in the hard disk assembler 1 is inputted, the central processing is performed. The device 4 outputs a drive control signal to the actuator 5 to transfer the actuator 5 to a point adjacent to the target track. Accordingly, the head 3 reads the information recorded in the servo sector of the hard disk 2, and the read servo information is transmitted to the read / write channel 6.

The read / write channel 6 receives the servo information from the head 3 and outputs it to the servo synchronizer 7 to synchronize the servo information with the system clock. The servo synchronous generator 7 detects only the servo synchronous signal among the servo information applied from the read / write channel 6 to synchronize the servo information with the system clock.

In addition, the servo synchronous generator 7 outputs servo information applied from the read / write channel 6 to the servo address mark detector 8, and the servo address mark detector 8 displays the servo address mark among the applied servo information. By detecting and outputting a predetermined control signal to the reference pulse generator 9 and the main counter 10 to drive the reference pulse generator 9 and the main counter 10, the reference pulse generator 9 is a servo address mark detector 8 A predetermined control signal is applied to generate a reference pulse of the corresponding servo sector. Accordingly, the operation of generating various signals required for servo control is started.

Meanwhile, the central processing unit 4 receives servo information from the read / write channel 6 from the analog / digital converter 11 and next servo sector (hereinafter, abbreviated as 'NSS') detection operation pulse. (start pulse) generator 12, servo gate timing generator 13, automatic gain control holQ signal (hereinafter abbreviated as 'AGCH') timing generator 14, servo Predetermined pulses corresponding to the N complex servo sectors recorded in the hard disk 2 that are rotated at a constant speed by applying values to a servo interrupt timing generator 15 and a servo sampling timing 16. Generate a signal.

The NSS detection operation pulse generator 12 generates a pulse if the value counted by the main counter 10 is equal to the value applied by the central processing unit 4 until the servo synchronization of the next-input servo sector. This output is again input to the servo address mark detector 8 so as to detect the next servo address mark.

The servo gate timing generator 13 generates a predetermined signal for protecting the servo sector area and generates a pulse when the count value of the main counter 10 is equal to the value applied by the central processing unit 4 to read / write. Transmit to channel 6.

The AGCH timing generator 14 generates a pulse if the count value of the main counter 10 is equal to the value applied by the central processing unit 4 within the pulse signal generated from the servo gate timing generator 13. The pulse signal generated as described above is transmitted to the read / write channel 6 so that automatic gain control is not performed in the logic 'high' period so that the amount of change in the signal read by the head 3 can be grasped.

The servo interrupt timing generator 15 generates a timing pulse using the servo gate timing generator 13 and generates a pulse when the counting value of the main counter 10 is equal to the value applied by the central processing unit 4. . When the servo interrupt signal generated from the servo interrupt timing generator 15 is detected, the CPU 4 checks various states related to the detection of the servo information recorded in the servo sector, and records the various types of data recorded on the hard disk 2. Information read / write performance is controlled.

The servo sampling timing generator 16 generates a signal for sampling the amount of position information for the head 3 to be located at the center of the track, and then outputs the generated sampling signal to the analog / digital converter 11.

The operation of the hard disk drive with the extended recording capacity according to the present invention having the above-described configuration will be described with reference to FIGS. 2 to 4 as follows.

In the section in which the pulse signal generated from the servo gate timing generator 13 is in a logic 'high' state, the read / write channel 6 reads and records the information recorded in the servo sector, and further, the AGCH timing generator 14 In the period when the AGCH signal of the logic is 'high', the amplitude (level) of the burst signal recorded in the servo sector is amplified to a predetermined size, and then the servo sampling timing generator 16 is disabled while the automatic gain control function is disabled. Check whether or not the servo sampling signal is output. When the servo sampling signal is read by the read / write channel 6, the read / write channel 6 converts the change value of each burst signal into voltage magnitude (level) during each sampling timing to convert the analog / digital converter 11 To transmit. The analog / digital converter 11 receiving the transmitted voltage magnitude data compares the value of each burst signal to control the track seek and track following.

The NSS detection operation pulse generator 12 generates a predetermined pulse signal before the next-type servo sector is read out. The NSS detection operation pulse generator 12, the servo gate timing generator 13, the AGCH timing generator 14, the servo interrupt timing generator 15, and the servo sampling timing generator 16 are servo sectors of the first and second types, respectively. Generate a timing pulse for each, and transmit each generated timing pulse to the central processing unit (4).

FIG. 2 is a timing diagram showing a servo sector arrangement state of a hard disk in a hard disk drive having an extended recording capacity according to the present invention.

As shown, the servo sector-0 represents a conventional form as shown in FIG. 3, that is, a first form (servo actuator, servo address mark, index, gray code, burst signal and pad). After Servo Sector-0, an identification area (ID-0) for recognizing Data-0 is assigned, and after Data-0 and ID-1 are sequentially assigned, Servosector-1, which is a servosector, is assigned. Then, data-1, ID-2, data-2, and ID-3, which have been split, are sequentially assigned, and then servosector-2, which is a servo sector of the first type, is allocated.

In the servo sector of the first type, after the servo synchronization for synchronizing with the system clock is detected in the digitized servo sector output from the read / write channel 6, the servo address mark existing only in the servo sector of the first type is detected. To generate a reference pulse. Thereafter, when a predetermined time elapses, a servo interrupt is generated. At this time, the servo interrupt is generated only in the servo sector of the first type in which the servo address mark exists, and the servo interrupt generated in this manner is called a normal servo interrupt.

In addition, after the general servo interrupt occurs, the main counter 10 continues the counting operation so that a special servo interrupt occurs at the point where the second type of servo sector ends.

The servo gate signal for protecting the servo sector area based on the reference pulse is generated to include the servo sectors of the first and second types, and the servo sector and the burst signals A, B, P, and Q are sampled to obtain analog / The digital converter 11 transmits the data. In addition, the servo sampling signal is similarly generated in the burst signal section of the servo sectors of the first and second types based on the reference pulse. Based on this reference pulse, an AGCH is generated and transmitted to the read / write channel 6. The AGCH reads only the servo sector area from the hard disk 2 and amplifies the amplitude of the servo sector at a constant magnification so that the head 3 is easily moved to the center of the target track during the track following the head 3. To be detected.

3 is a diagram illustrating a magnetization state of a hard disk according to two types of servo sectors to which a hard disk drive having an extended recording capacity according to the present invention is applied.

The servo sector of the first aspect is composed of servo synchronization, servo address mark, index information, gray code, burst signals A, B, P, Q, and pads. Here, the servo is constantly magnetized from the Nth track to the (N + 5) th track, and the servo address mark has only one pulse of two direct current (DC) regions, and thus index information. The pulses exist only in the first servo sector for N servo sectors. In addition, in the gray code, only one pulse of each track changes its magnetization form.

The burst signal A is present only on even tracks, and the burst signal B is only present on odd tracks. The burst signals P and Q are set such that the signal has half the value of the burst signals A and B at the center of each track.

The burst signals A, B, P, and Q recorded in the second type of servo sector are also present only in the even track, and the burst signal B is odd as in the first type of servo sector. Only existed on the track. The burst signals P and Q are set such that the signal has half the value of the burst signals A and B at the center of each track.

Finally, FIG. 4 is a diagram showing the arrangement of the servo sector of the hard disk drive with the extended recording capacity according to the present invention.

4 shows that there are N / 2 servo sectors of the first and second types in the hard disk 2, respectively.

That is, the track search is performed with the servo sector of the first type having N / 2 servo sectors, and various servo control signals are generated based on the servo sector of the first type. A burst sampling signal is generated using the burst signal recorded in the sector. In track following, when N number of burst signals recorded in the servo sectors of the first and second types are sampled and N servo interrupts are detected, the burst signal sampling values are digitized and output to the central processing unit 4.

Accordingly, as described above, in performing servo control using two types of servo sectors, the sum of the first type of servo synchronization, servo address mark, index information, and gray code information is performed based on the second type of servo sector. The recording capacity can be improved by the length multiplied by the total number of servo sectors, thereby realizing a high capacity hard disk drive.

As a result, as described above, according to the hard disk drive of which the recording capacity of the present invention is expanded, the servo sector of the first type in which the servo synchronization, the servo address mark, the index information, the gray code information, the burst signal, and the pad are recorded and By performing the servo control using the servo sector of the second type in which the burst signal and the pad are recorded, in the servo sector of the second type, the sum of the servo synchronization, the servo address mark, the index information, and the gray code information is added to the total length. Since the number of servo sectors multiplied by the data sector can be utilized, the recording capacity of the hard disk drive can be improved.

Claims (3)

A hard disk drive having a plurality of data sectors and a hard disk divided into servo sectors, the hard disk drive comprising: a first type servo sector in which servo synchronization, servo address marks, index information, gray code information, burst signals, and pads are recorded; And a servo sector of a second type in which a burst signal and a pad are recorded, wherein the second type of servo sector records additional information as much as recording capacity corresponding to the servo synchronizer, servo address mark, index information, and gray code information. Hard disk drive with extended recording capacity, characterized by having data sectors sequentially partitioned. The method according to claim 1, wherein in the servo sector of the first aspect, a servo address mark is detected after detecting servo synchronization, and a reference pulse is generated at the time when the servo address mark is detected, and a predetermined time after the reference pulse is generated. A servo drive with an extended recording capacity, wherein a servo interrupt occurs after the elapse of time. The first servo interrupt of the first type having a servo address mark is generated, and the second servo is terminated after the first servo interrupt occurs. Hard disk drive with extended recording capacity, characterized in that an interrupt is generated.