KR20050043098A - A low power data storage system and a method thereof - Google Patents

Abstract

According to the present invention, the power consumed to store data by constantly determining the size of data recorded on a predetermined storage medium, allowing the storage medium to transition to an initial state after completion of the storage processing of the determined data, and excluding an idle operation of the storage medium. The present invention relates to a low power data storage system and a data storage method capable of minimizing the number of times. A data storage system according to an embodiment of the present invention includes: data input means for receiving data generated by a predetermined signal processing; Data taking means for taking in and accumulating data in the buffer module, and recording control means for extracting the data having a predetermined size from the buffer module and recording the data in a storage medium in accordance with a storage instruction, wherein the recording control means includes: When predetermined data accumulates in the buffer module, data recording is performed. Less, and the above extraction to complete the recording of the data immediately after the storage medium is characterized in that control to transition to the initial state.

According to the present invention, a storage for vaguely waiting for a storage command by accumulating data received by the data input means in a predetermined temporary storage device and controlling the operation of the storage medium based on the size of the accumulated data or the time required for accumulation. There is an advantage to provide a low power data storage system and a data storage method that can achieve low power by completely excluding the idle operation of the medium.

Description

LOW POWER DATA STORAGE SYSTEM AND A METHOD THEREOF

The present invention relates to a low power data storage system and a data storage method, and more particularly, to constantly determine the size of data recorded on a predetermined storage medium, and to transfer the storage medium to an initial state after completion of the storage process of the determined data. The present invention relates to a low power data storage system and a data storage method capable of minimizing power consumption for storing data by eliminating idle operation of the storage medium.

With the advent of various portable terminal means, strict power management of the terminal means has been recognized more important in that it can fully utilize the functions of the portable terminal means by efficiently using limited power. As part of such power management, various terminal means including a portable terminal means adopt a method that can be equipped with power-saving components in hardware, and can minimize the power supply by recognition of data input wait in software. In particular, a data transmission function or a data reading function that consumes a lot of power in each terminal means has a significant power use reduction effect through, for example, disk drive scheduling due to the steady accumulation of technology in the prior art.

On the other hand, the data storage function, which consumes a lot of power, has not yet emerged a special solution for improving the power usage. However, at the same time as the completion of the data storage process, power supply control is provided to minimize the power to the storage medium. There will be. For example, the most recently used power supply control technique automatically switches a storage medium to a stand-by mode when a data storage / fetch request does not occur in the storage medium for a predetermined time. When idle operation continues for a certain period of time, a method of controlling a storage medium to operate in a standby mode after a transition has been introduced.

However, when the storage medium is in the standby mode, in order to store the predetermined data, the storage medium must first be operated through a start transition. For example, when the storage medium is a hard disk, driving of a platter at the start transition is required. And focusing, tracking, and the like of the head may be performed simultaneously, which may act as a factor causing trouble in maximizing storage processing performance.

In addition, when the storage medium is idle, it is not possible to determine at what time the generated data is input to the storage medium, so that the storage medium needs to be maintained in a continuous recording standby state. As a result, in a power-rich environment, such as a typical desktop computer or server, the storage medium has a non-periodic cycle and a continuous power supply (power equivalent to a recording mode) is supplied to the storage medium to record the input data. It has been a cause of generating.

In addition, the power supply control method of controlling the idle holding time of the storage medium to control the operation of the storage medium has a disadvantage in that its effectiveness is not large when the generation period of the input data is short. Therefore, the data storage command generation time and the recording mode start / end point of the storage medium are accurately calculated in consideration of the size of the data to be stored, the recording speed and the characteristics of the storage medium, and the operation of the storage medium is performed based on the calculated information. There is an urgent need for the emergence of a breakthrough low power data storage system and data storage method capable of eliminating idle operation of storage media and preventing unnecessary power consumption by controlling performance.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and accumulates data received by a data input means in a predetermined temporary storage device, and operates the storage medium based on the size of the accumulated data or the time required for accumulation. It is an object of the present invention to provide a low-power data storage system and a data storage method capable of achieving low power by completely eliminating idle operation of a storage medium vaguely waiting for a storage command.

It is also an object of the present invention to determine the recording data S and the recording time Tw based on the performance characteristics of the operation of the storage medium and the storage speed of the data, and to quantify the size of the data to be stored and processed in one continuous recording mode. The present invention provides a low power data storage system and a data storage method capable of performing a stable storage process and accurately determining a time point of generation of a storage command and an operation holding time of a storage medium.

In addition, another object of the present invention is to determine the buffer size B based on the recording data S, to facilitate the design and management of the buffer, and to store the low-power data capable of accurately measuring the time of occurrence of the storage command and each operation holding time. The present invention provides a system and a method for storing data.

In addition, the present invention by arranging a plurality of buffers that serve as a buffer between the data generated synchronously or asynchronously and the storage medium operating synchronously to ensure a smooth processing of the continuous input data, and record data of a certain size It is another object of the present invention to provide a low power data storage system and a data storage method which allow stable storage processing by allowing data of S to be accumulated.

Data storage system according to an embodiment of the present invention for achieving the above object, the data input means for receiving the data generated by the predetermined signal processing, and the data for taking the accumulated data into the buffer module to accumulate And recording control means for extracting the data having a predetermined size from the buffer module and recording the data in the storage medium according to the taking-in means and the storage instruction, wherein the recording control means records the data when the predetermined data is accumulated in the buffer module. And immediately after the recording of the extracted data is completed, the storage medium is controlled to transition to an initial state.

In addition, as a technical implementation method for achieving the above object, the method for storing the data of the present invention according to one aspect, the step of receiving data generated by a predetermined signal processing, and the input data into the buffer module And extracting the data from the buffer module and recording the data in a storage medium according to a storage instruction generated when a waiting time To time elapses from the time of taking the data. In the step of accumulating and storing data in the buffer module, the size of the data to be stored and processed for a predetermined write time Tw is determined as write data S, and the data corresponding to the determined write data S is accumulated in the buffer module. Controlling to include;

The recording time Tw is,

,

or

It is characterized by setting to satisfy.

In addition, the method of storing the data of the present invention according to another aspect of the present invention comprises the steps of receiving data generated by a predetermined signal processing, taking the accumulated data into the buffer module and accumulating the buffer module; And extracting the data from the buffer module and writing the data to a storage medium according to a storage command generated when the size of the accumulated data reaches m. In the step, the predetermined buffer size B is determined as the recording data S which is the size of the data processed in the recording mode of the storage medium, and the data corresponding to the determined recording data S is accumulated in the buffer module. And the buffer size B,

,

or It is characterized by setting to satisfy.

Hereinafter, a low power data storage system and a data storage method according to the present invention will be described with reference to the accompanying drawings.

1 is a view for explaining a schematic operation of a low power data storage system according to the present invention.

The low power data storage system 100 is an apparatus for receiving data generated by a predetermined signal processing and controlling the input data to be recorded and stored in a series of storage media 110 at a lower power than in the prior art. It is included in the terminal means to perform the storage process for the data. Such a terminal means is provided with a processor means for performing a predetermined operation and having a communication means for performing communication, for example, a personal computer (PC) having a data storage function, a notebook computer, a mobile communication terminal (mobile phone, Cellular phones, PDAs, etc.), home appliances, and the like.

The data includes arbitrary information, and the information is transmitted to the storage medium 110 that is in charge of recording and storing the information. For example, the data may include audio data, image / video data, information data such as a document or a program, and the like. Such data may be generated by signal processing of a data generation related application program driven by a predetermined data generation terminal means (for example, a microphone, a camera, a personal computer, etc.), and in particular, a data generation related application program. May convert the generated data into an optimal signal form (eg, a digital signal) so that the information is transmitted or stored in the storage medium 110 without loss or distortion.

The storage medium 110 is a device for recording / storing the generated data, for example, magnetic media such as hard disks, floppy disks, and magnetic tapes mainly used in personal computers, and optical recording such as CD-ROMs and DVDs. Optical media, magneto-optical media such as floptical disks, and ROM, RAM, flash memory, and the like. The low power data storage system 100 of the present invention can be applied to any storage medium for recording and storing arbitrary data. In the following embodiment of the present invention, the storage medium is illustrated as a magnetic disk or an optical disk for convenience of description. Will be explained. However, this is only a limitation of the description object and is not a limitation of the technical idea, and it will be reasonable that the application example of the storage medium other than the magnetic disk or the optical disk is also the technical idea of the present invention which can be easily inferred by the present invention. A detailed configuration of the low power data storage system 100 of the present invention will be described with reference to FIG. 2.

2 is a block diagram showing a low power data storage system according to a preferred embodiment of the present invention.

The low power data storage system 200 of the present invention includes a data input means 210, a data acquisition means 220, a write control means 230, and a buffer module 240.

First, the data input unit 210 is for receiving data generated by predetermined signal processing, for example, receiving data such as a modem, a LAN card, or a wireless access card, which is connected to a wired / wireless data transmission network to receive data generated remotely. There may be a data collection device for collecting data generated by the device or an application program driven by the terminal means at the same time as the generation. Data input to the data input means 210 is imported into the buffer module 240 so that a storage process to the storage medium 110 is performed according to a predetermined storage command.

The data taking means 220 takes the input data into the predetermined buffer module 240 and plays a role of accumulating the accumulated data in the buffer module 240. In addition, the data taking means 220 determines the predetermined size of the data to be stored and processed as the recording data S during the recording mode operation of the storage medium 110, and the detailed description of the recording data S will be described later. It plays a role of controlling the data of the determined write data S to be taken into the buffer module 240.

The recording control means 230 is a device that performs signal processing in a reverse direction to the above-described data taking means 220, and generates a storage command at a predetermined time point according to the size of data stored in the buffer module 240, and generates the generated storage command. It extracts data from the buffer module 240 by the command. In this case, a speed at which data is extracted from the buffer module 240 may be determined by a storage speed R of the storage medium 110, and the storage speed R may be determined according to data recording capability according to production properties of each storage medium 110. Differences can occur. In particular, the recording control means 230 controls the storage medium 110 to transition to the initial state immediately after the extracted data is recorded on the storage medium 110. That is, under the control of the recording control means 230, the storage medium 110 immediately transitions to the standby mode without an idle step after the operation of the recording mode. Accordingly, the data storage system 100 of the present invention does not require the power consumed to maintain the idle phase of the existing storage medium 110, it is possible to significantly reduce the power consumption. Hereinafter, each operation step performed in the storage medium 110 will be described in detail with reference to FIG. 3A.

3A is a diagram for explaining an operation step of a storage medium performed by the control of the recording control means according to the present invention.

As shown in FIG. 3A, the recording control means 230 controls the storage medium 110 to sequentially operate the standby step 310 and the recording step 330 to store data in the storage medium 110. In particular, unnecessary power consumption of the storage medium 110 is prevented by excluding an idle step of continuously waiting for data to be stored in a state where high power is applied. On the other hand, the start step 320 refers to the transition from the standby step 310 to the recording step 330, and the end step 340 refers to the transition from the recording step 330 to the standby step 310.

Here, the storage command may record predetermined data accumulated in each buffer module 240 in the actual storage medium 110 according to a data storage function activated for storing and storing data generated by a data generation related application program. It can mean a command for.

First, the standby step 310 is a process of maintaining the storage medium 110 in an initial state, that is, standby mode (Standby mode), the basic medium is applied, the storage medium 110 in a section waiting for the next storage command It may mean an operation (see To section of FIG. 3A).

The start step 320 is a process in which the storage medium 110 in its initial state is transferred to a recording mode in which data can be recorded according to a predetermined storage command. For example, the storage medium 110 is a hard disk which is a kind of magnetic disk. In this case, the storage medium 110 in the start step 320 spins up the platter in the stationary state and performs operations such as focus and tracking. That is, the start step 320 is a process of applying a predetermined level of power to the storage medium 110 according to a storage command and transitioning to the recording step 330 capable of recording data. This may mean a section in which data recording is impossible due to the formation of an unstable power curve (see Ts section in FIG. 3A).

The recording step 330 is a process of storing data stored in the buffer module 240 in the storage medium 110 according to a predetermined criterion, that is, allowing the storage medium 100 to operate in a write mode. to be. The start point of the recording step 330 is, for example, recording control at a state where the storage medium 110 in the initial state of the standby step 310 can store data, that is, the point where the unstable power application interval ends. The means 200 identify and determine the identified point as the beginning of the recording mode. Accordingly, the recording step 330 may refer to the operation of the storage medium 110 in a section in which the application of power is stable (see Tw section in FIG. 3A). Hereinafter, the present invention will be described with reference to FIG. 3B. The power consumption form of the recording mode will be described in detail.

3B is a diagram showing an example of the type of power consumed in the recording mode of the present invention.

As shown in FIG. 3B, the storage command is generated at S1, which is a time at which data is stored in the buffer module 240, for example, data that satisfies the recording data S is made. When the storage command is generated at S1, the recording control means 230 stores the storage medium 110 in operation at the start step 310, for example, to store data at a parked position of the disk head of the hard disk. Focusing and tracking to the predetermined position of the medium 110 is controlled to perform a series of processes, such as driving a stationary disk platter at a normal speed, the unstable application of the S1 ~ S2 section of Figure 3b due to the nature of the transition step Indicates the power form. When the power applied after the predetermined time is stabilized, the driving speed of the disk platter is also stabilized accordingly, so that data can be written to the storage medium 110, and the stabilized power form in the period S2 to S3 of FIG. It becomes visible.

In addition, the recording control means 200 generates a predetermined end command (or stop of generating the storage command) at the time S3 to end the recording mode operation of the storage medium 110 at the time when the storing processing of the extracted data is completed. The end command is a signal for transitioning the storage medium 110 from the write mode operation state to the standby state. In the case of a hard disk, when the end command occurs, the disc head is parked to an initial position, and the disc platter is slowed down. To rotate or stop.

The termination step 340 is a process in which the storage medium 110 transitions to an initial state after completion of the storage processing of the extracted data, and an unstable time delay in which the applied power is reduced according to the termination of the above-described recording mode operation. It may mean an operation of the storage medium 110 in a delay section (see Tf section in FIG. 3A). At this time, the platter of the hard disk is spun down and slowly stopped, and the disk head moves to the parking position.

The buffer module 240 may be configured by the data acquisition means 220 and the recording control means 230 according to the difference in data processing speed, processing unit, processing time, etc. between the data acquisition means 220 and the recording control means 230 described above. It acts as a buffer against data flow mismatch. In particular, the buffer module 240 accumulates data that is input unspecified, and when a predetermined storage command occurs, the data stored in the buffer module 240 is extracted at a time, thereby storing the storage medium 110 for storage. It is possible to increase the efficiency of the drive time and the power consumed for data storage. 4A and 4B, data accumulation and extraction in the buffer module 240 will be described.

4A is a diagram illustrating an example of data input with parallax, and FIG. 4B is a diagram illustrating an example of data accumulated in the buffer module 240 of the present invention.

As the data input into the buffer by the predetermined data storage function, the input period is unspecified or the size of each data is inputted as shown in FIG. 4A due to differences in device performance of the terminal means generating the data, differences in the data generation environment, and the like. Can be different. If the data having such an unspecified period is stored in the storage medium 110 every time it is input to a predetermined recording system, for example, the storage medium 110 is maintained in the recording step 330 or during the recording step 330. In the section without inputting the actual data, a method of revolving the storage medium 110 may be considered, and these processing methods have much room for improvement in terms of power consumption. In addition, even in the size of the data to be stored in the recording step 330, the size of the input data is stored as it is, so that the size of the data to be recorded in each recording mode operation is not constant, which prevents stable storage processing. Can act as an element. That is, as shown in FIG. 4A, in order to store and process four pieces of data, the storage medium 110 is applied to the storage medium 110 after the predetermined storage command is generated, and thus the storage medium 110 must maintain idle even in a section in which there is no data input. The power to be maintained is as much as P1.

The buffer module 240 of the present invention used to solve such an inefficient storage processing method accumulates data input at an unspecified period by a size corresponding to the recording data S according to a selected condition, as shown in FIG. The stored data is collectively transferred to the storage medium 110 according to a storage command generated at the time when data accumulation of the data S is made to be stored. In FIG. 4B, the data taking means 220 takes four data into the buffer module 240, for example, when the total amount of accumulated four data is sufficiently large (e.g., satisfies the recording data S), The recording control means 230 extracts four data from the buffer module 240 by a continuous series of storage commands and stores them in the storage medium 110 in a batch. The batch storage command refers to performing storage processing on data by continuously executing a storage command generated without additional standby mode operation or idle mode after the storage medium 110 has transitioned to the recording mode after the startup transition. it means. Accordingly, in FIG. 4B, less power of P2 is applied to the storage medium 110 than P1 of FIG. 4A to enable low power data storage. Accordingly, the low power data storage system 200 using the buffer module 240 of the present invention can suppress unnecessary waste of power by minimizing the unnecessary idle of the storage medium 110 in the storage processing for a series of data. At the same time, the storage medium 110 may store data having a predetermined size (recording data S) accumulated according to a predetermined condition, thereby stably providing a constant storage bandwidth as needed.

In addition, the buffer module 240 guarantees a constant size of the total data (recording data S) to be stored through the continuous recording mode operation in relation to the recording mode operation of the storage medium 110, thereby generating a storage point of time, That is, it is possible to accurately determine the operation point (S2 in FIG. 3B) and the recording mode holding time at which the storage medium 110 switches from the start step 320 to the recording step 330. For this purpose, proper setting of the write data S, which is the size of the data to be accumulated in the buffer module 240, is very important. If the write data S is too large, it takes a long time until the data is accumulated, and thus the input / output delay time. (I / O Latency) becomes long, resulting in a decrease in input / output performance. On the other hand, if the recording data S is too small, excessive time or power may be consumed in the operation transition due to frequent switching of the recording mode / standby mode.

In addition, the buffer module 240 is a temporary storage space allocated to a predetermined storage device for storing data, and means a continuous or discontinuous address space capable of storing at least data of the recording data S. FIG. An example of the configuration of the buffer module 240 may include a configuration in which one or more unit buffers having a predetermined buffer size B are included, and data of the predetermined write data S is accumulated in the unit buffer. The reason why the buffer module 240 is configured as one or more unit buffers is to write data temporarily to the buffer module 240 in order to maintain data consistency, and to read and store data from the buffer module 240. This is because the operation of storing the medium 110 cannot be performed simultaneously on the storage device having the same storage area. That is, a method of configuring the buffer module 240 as one or more unit buffers may be selected in order to continuously process and store data. The data taking means 220 accumulates the data input to the buffer module 240, and the recording control means 230 stores the storage medium when sufficient data (e.g., the write data S or more) is accumulated in the buffer module 240. Control 110 to control the storage process. In addition, when the storage process is completed, the recording control means 230 controls the storage medium 110 to operate in the standby mode, and through the repetition of the recording mode / standby mode operation of the storage medium 110 as a whole. The storage medium 110 is prevented from unnecessary idle. The buffer size B may preferably be greater than or equal to the write data S, and the following is a description of the predetermined criteria for determining the write data S.

The predetermined criterion for determining the recording data S, which is the size of the data to be stored and processed when the recording mode of the storage medium 110 is executed, may include a recording time Tw and a buffer size B of the unit buffer. This will be described with reference to FIG. 3A and FIGS. 5A and 5B to be described later.

As described above, an object of the present invention is to control the operation of the storage medium 110 in consideration of a situation in which data to be stored in the storage medium 110 is blown into the buffer module 240, thereby maximizing the efficiency of power consumption. will be. The operation of the storage medium 110 is to repeat the standby step 310, the start step 320, the recording step 330, the end step 340, and the standby step 310 to the end step 340 The cycle of is defined as the operation cycle T. At this time, the role of the recording control means 230 is to control each operation of the storage medium 110 to minimize the power consumption during the storage process, the operation of the storage medium 110 in the recording control means 230 In the scheme, if the data to be recorded during the data recording time is stored in the buffer module 240 based on the time at which data is recorded in the storage medium 110, the storage medium 110 in the standby mode may be started (step 320). There may be a way to control to operate as. In addition, in another operation control method, when the size of the predetermined data is accumulated in the buffer module 240 based on the size of the data accumulated in the buffer module 240, the storage medium 110 may be operated in the start step 320. When the accumulated data is extracted from the buffer module 240, the recording step 330 of the storage medium 110 may be terminated. Implementation of specific control schemes may use, for example, interrupts, polling, system calls, and the like. The control method based on time and the control method based on the size of accumulated data can be established on the premise that the data acquisition is at a constant speed, that is, the size of the data to be taken per unit time is almost constant.

Determination of the recording time Tw

First, an example of determining the recording data S based on the recording time Tw will be described.

FIG. 5A is a diagram illustrating an example of the buffer module 500 according to the present invention. As shown in FIG. 5A, a blowing speed of data taken into the buffer module 500 is referred to as r and extracted from the buffer module 500. And a storage rate recorded in the predetermined storage medium 110 is assumed to be R. FIG. In a preferred embodiment, the buffer module 500 should have a storage speed R greater than the blow rate r, in order to prevent an overcapacity of the buffer module 500 that may occur when the storage speed R is slow. If the blowing speed r is greater than the storage speed R while the continuous data is being taken in, the buffer module 500 continues to accumulate the data to be taken in, and eventually the capacity exceeding capacity becomes impossible. Will occur. Such overcapacity may degrade processing power, for example, to perform signal processing of data, such as a microprocessor (CPU), which may cause problems such as inability to continuously generate data or loss of generated data.

The parameters involved in determining the recording time Tw may be determined in consideration of the startup time Ts, the finish time Tf, the storage speed R, and the power consumption of each operation of the storage medium 110. 3A and 5A, the recording time Tw is calculated below.

As shown in FIG. 5A, when the generated data is blown into the buffer module 240 at a constant blowing speed r, the relational expression as shown in Equation 1 is expressed between the data size taken into the buffer module 500 and the extracted data size. This can be established.

Here, Td is a time period directly related to the data storage process, and may be defined as 'starting time Ts + recording time Tw + finish time Tf' in the operation cycle T of the recording control unit 230 excluding the waiting time To. have. Equation 1 may mean "the size of the data extracted from the buffer module 500 for the storage process based on the buffer module 500 is greater than or equal to the size of the data to be processed." The size of data extracted during Td is greater than or equal to the size of data taken in during Td "(T> Td). Such a condition may be derived from the characteristic (blow rate r> storage rate R) of the buffer module 240 so that the capacity of the buffer module 240 is not exceeded as described above.

The recording time Tw of the expression (2) is determined by arranging the above expression (1) with respect to the recording time Tw.

That is, the recording time Tw calculated in Equation 2 means a time for which the recording mode operation is maintained, and for example, the recording data corresponding to the recording time Tw in consideration of the taking-up speed r and the storage rate R in the data taking-in means 220. S can be determined.

On the other hand, if any one of the recording times Tw satisfying Equation 2 is Tw ^* , the operation cycle T of each operation of the storage medium 110 satisfies 'T = Ts + Tw ^* + Tf + To'. Accordingly, a relational expression such as Equation 3 can be derived.

Equation 3 is calculated under the precondition (Tw ^* R = Tr) that the size of the data to be processed and the extracted data is the same during one operation cycle period T. By arranging for Tw ^* , the waiting time To of Equation 4 can be determined.

Therefore, the inventors of the present invention store the recording control means 230 such that a predetermined storage command is generated after the waiting time To has elapsed from the time of taking in the buffer module 500 of the data, and the recording mode is maintained for the recording time Tw. It can be designed to control the medium 110. That is, in FIG. 3A, the start time Ts and the finish time Tf have fixed values according to the manufacturing properties of the storage medium 110, and the recording time Tw and the waiting time To can be calculated based on Equations 2 and 4 below. It becomes possible. Accordingly, the data taking-in means 220 determines the write data S corresponding to 'R × Tw' under the condition 'Tw > 0', and the blow-in process so that the data of the determined write data S is accumulated in the buffer module 500. Done. Further, the low power data storage system 200 controls the data taking means 220 to take data into the buffer module 500 during the waiting time To, and the write control means 230 buffers the accumulated data for the writing time Tw. By controlling the data to be extracted from the module 500 (taken data size = extracted data size), the low power data storage of the present invention can be enabled even when the buffer module 500 is configured as one unit buffer.

Therefore, the present invention can optimize the operation control of the storage medium 110 for data recording according to the accurate calculation of the recording time Tw and the waiting time To, and the storage processing by performing the recording mode operation maintained for the recording time Tw. It is possible to obtain the effect of allowing the predetermined size data (recording data S) to be extracted from the buffer module 500. In addition, the present invention faithfully performs the purpose of the present invention to achieve low power by excluding the idle of the storage medium 110 that waits for the next storage command by accurately predicting the time of generation of the storage command according to the calculation of the waiting time To. You can get the advantage.

Determination of Buffer Size B

Meanwhile, according to another embodiment of the present invention, the write data S may be determined based on not only the write time Tw but also the capacity of the buffer module 240, preferably the buffer size B of the unit buffer included in the buffer module 240. Can be.

Here, the buffer size B may mean the physical capacity of the unit buffer, or may mean the size (recording data S) of data to be stored and processed while the recording mode operation of the storage medium 110 is maintained. That is, in the present embodiment, the recording control means 230 controls the storage medium 110 to operate in the recording mode when the size of the data accumulated in the buffer module 240 reaches a predetermined threshold, so that the buffer module 240 is controlled. ) And extracts the data stored in the buffer module, so that the recording mode operation of the storage medium 110 is terminated when the size of the data remaining in the buffer module 230 falls below the threshold. At this time, the size of the data to be stored and stored in the storage medium 110 in one recording mode operation is defined as the recording data S. As a specific method of implementing the method, when the buffer size B of the unit buffer is determined as the recording data S, and when data accumulation is completed in a predetermined unit buffer, the newly input data is blown into another unit buffer and the new buffer is processed. There may be a method of extracting data to the storage medium 110 and storing the data. Preferably, setting the buffer size B to the maximum capacity of the unit buffer makes it easier to determine the recording data S, but taking into account that a slight difference in the maximum capacity may occur due to the difference in production properties for each unit buffer. Determine appropriately below the maximum dose.

5B is a diagram illustrating a change in data size accumulated in a buffer module including one or more unit buffers according to the present invention.

As shown in FIG. 5B, the buffer module 500 includes, for example, three first unit buffers to third unit buffers 510, 520, and 530, and stores the buffer sizes B of the unit buffers 510, 520, and 530 in the storage medium 110. The recording data S to be stored is determined. In the present embodiment, when the data to be imported into the buffer module 500 starts to be imported into the first unit buffer 510, when the size of data accumulated in the first unit buffer 510 reaches the write data S Consideration is given to the blowing based on the blowing order (first unit buffer-> second unit buffer-> third unit buffer-> ...) which causes accumulation in the second unit buffer 520.

In FIG. 5B, each unit buffer 510, 520, 530 includes virtual accumulated data search lines m and m ^* , for example, the size of data accumulated in each unit buffer 510, 520, 530 reaches m (m1, m2, m3). Recording control means 230 generates a storage command and controls the storage medium 110 to perform a startup transition. On the other hand, when the size of data accumulated in each unit buffer 510, 520, 530 reaches m ^* (m1 ^* , m2 ^* , m3 ^* ), the recording control means 230 issues an end command (or a storage command) of the recording mode operation. And control the storage medium 110 to perform the end transition.

The accumulated data search lines m and m ^* can be set in consideration of the blowing speed r, the storage speed R, the startup time Ts, the finish time Tf, the buffer size B, and the like. For example, the recording control means 230 includes a buffer module ( M may be set in consideration of the injection speed r of the data taken into the unit buffer 510.520.530 of the 240 and m ^* may be set in consideration of the storage speed R from which the data is extracted from the buffer module 240. Accordingly, the storage command is generated when the size of data accumulated in the unit buffers 510, 520, and 530 of the buffer module 240 reaches m, and when the m ^* is reached, the recording mode of the storage medium 110 ends. By doing so, it is possible to accurately grasp the execution time of each operation of the storage medium 110 and obtain an effect of controlling the operation of the storage medium 110 based on this. Hereinafter, data accumulation in the unit buffers 510, 520, and 530 and the operation of the storage medium 110 will be described with reference to FIG. 5B.

In FIG. 5B, the data acquisition means 220 injects data into the first unit buffer 510 at an injection speed r in the blowing order. When the data is taken in and the size of the data accumulated in the first unit buffer 510 reaches m1, the recording control means 230 generates a storage command and the storage medium 110 starts the operation step 320. Control to operate as. At this time, m1 is set in consideration of the buffer size B, the startup time Ts, the blowing speed r, and the like. For example, the size of data accumulated in the first unit buffer 510 during 'To + Ts' in FIG. 5B is the buffer size B. M1 can be appropriately set to reach (recording data S). In the present embodiment, m (m1, m2, m3) has been described as an example of setting before the accumulation is completely completed in consideration of the time to complete the data accumulation to the buffer size B, this is an example of description, for example Of course, there can be various setting methods, such as a method of setting m (m1, m2, m3) at a predetermined point of the second unit buffer 520, which is a unit buffer having an order of blowing. Based on these various setting methods, a slight difference may occur in the degree of change in the data size accumulated as shown in FIG. 5B, and this can be also inferred from the embodiment of the present invention.

Subsequently, in FIG. 5B, when the storage medium 110 performs the start step 320 and the accumulation of the first unit buffer 510 is completed after a predetermined time (for example, the startup time Ts), the storage medium 110 is stored with respect to the accumulated data. The recording mode operation of the storage medium 110 is enabled. At the same time, the data acquisition means 220 terminates the data acquisition of the first unit buffer 510 and starts the data acquisition of the second unit buffer 520 according to the acquisition order. The recording control means 230 judges the data accumulated in the first unit buffer 510 as the recording data S and starts the extraction process at the storage rate R. FIG. Accordingly, the total data accumulated in the buffer module 240 is reduced at the speed of 'R-r', and the recording control means 230 maintains the recording mode operation of the storage medium 110 for Tw. As described above, while the accumulated data of the first unit buffer 510 is extracted, the second unit buffer 520 accumulates data, and the size of the data accumulated in the second unit buffer 520 is increased. When m2 ^* is reached, the recording control means 230 ends the recording mode operation of the storage medium 110. m2 ^* is set in consideration of the accumulated data reduction rate Rr of the buffer module 240 and the buffer size B, and for example, the first unit buffer 510 based on the blowing rate R of the data into the second unit buffer 520. Can be set in consideration of the size of the data accumulated in the second unit buffer 520 at the time when all the data (data determined by the recording data S) are extracted. That is, it may be preferable to set m ^* (m1 ^* , m2 ^* , m3 ^* ) in consideration of the time point at which the data to be extracted and processed by the preceding storage command is extracted from the predetermined unit buffers 510, 520, and 530. At this time, as shown in Figure 5b, it can be seen that the slope of the data reduction rate (Rr) is more steeper than the slope of the blowing rate r, and accordingly the characteristics of the buffer module 240 (take rate r <storage rate R) It can be seen that the conditions are faithfully guaranteed. Thereafter, the storage medium 110 transitions to the standby mode after a predetermined end time Tf (not shown) has elapsed, and the recording control means 230 determines that the size of the accumulated data in the second buffer unit 520 is m2. It determines whether it arrives and waits for the next save command.

Accordingly, the buffer module 240 of the present invention may include a plurality of unit buffers 510, 520, and 530 to perform continuous data import processing, and determine the write data S as the buffer size B of the unit buffers 510, 520, and 530. An effect that can facilitate the design and data management of the present invention can be obtained.

The formula for calculating the buffer size B described below is derived.

As shown in FIG. 5A, when the blowing speed into the buffer module 240 is r and the storage speed is R, the buffer size B satisfies Equation 5. FIG.

Equation 5 means that "the buffer size B of the unit buffers 510, 520, 530 is greater than or equal to the size of data extracted through the continuous write mode operation in the buffer module 240", and more specifically, the "write time Tw". While there is always data to be recorded. ”, Which means that there is no idle of the storage medium 110. Preferably, when it is assumed that the left and right sides of Equation 5 are the same, the inventors of the present invention can determine the maximum capacity of the unit buffers 510, 520, and 530 as the write data S, thereby determining the write data S, and the storage medium. The calculation of the recording time Tw, the waiting time To, etc. of 110 can be made easy, and the recording control means 230 of this invention can be designed more conveniently. The calculation of the recording time Tw in Equation 5 is based on Equation 2, and the detailed description is replaced with the above.

Accordingly, the low power data storage system 200 of the present invention imports data into the unit buffers 510, 520, and 530 of the buffer module 240 according to a predetermined blowing order, and includes one unit buffer included in the buffer module 500. For example, when the size of data stored in the first unit buffer 510 exceeds the buffer size B, the data may be introduced into the next unit buffer (eg, the second unit buffer 520). At this time, as the size of data accumulated in the first unit buffer 510 reaches the buffer size B, data extraction from the first unit buffer 510 is performed. As a result, by ensuring continuous intake of data, it is possible to suppress an overcapacity phenomenon that impedes the generation of data and to determine a certain amount of recording data S, so that stable storage processing can be achieved.

Hereinafter, the power saving effect of the low power data storage method according to the present invention will be described with reference to FIGS. 6A and 6B.

As described above, in a method of storing and storing data in the storage medium 110, a method of recording data by transitioning to a recording mode every time data is input while idlely operating the storage medium 110 (hereinafter, referred to as a first storage method). 6A) and a method of recording data while periodically performing the operation steps (standby, start, write, and end) of the storage medium 110 (hereinafter, referred to as a second storage method). FIG. 6B ). For example, if the write data S (ie, buffer size B) is not large enough, the operation buffer period T of the storage medium 110 may occur at very short intervals by the unit buffer completing data accumulation in a short time, and thus the storage medium. The power required to transition the operation of 110 (eg, startup transition or finish transition) may be increased inefficiently. Therefore, the recording data S should be set in consideration of the taking-up speed r of the data, the storage speed R, the durations Ts, Tw, Tf, To and the associated power consumption required to perform each operation of the storage medium 110.

FIG. 6A is a diagram illustrating a power consumption form when storing data according to the prior art, and FIG. 6B is a diagram illustrating a power consumption form when storing data according to the present embodiment.

6A and 6B, it is assumed that the capacity of the unit buffer is the buffer size B, and the size of the data taken into the unit buffer and the size of the data extracted from the unit buffer after a predetermined accumulation time are the same as the buffer size B. . That is, referring to FIG. 5A, it is assumed that data corresponding to the buffer size B is accumulated in the unit buffer during the waiting time To, and the accumulated data is extracted from the unit buffer during the predetermined write time Tw ^* .

Accordingly, the one-time operation cycle T of the storage medium 110 may be represented by Equation 6 (Tw ^* is defined as a predetermined recording time that satisfies Equation 2).

In addition, when the size B of the data extracted from the unit buffer is indicated with respect to the storage rate R of the storage medium 110, it may be expressed as Equation (7).

In addition, when the magnitude | size B of the data blown into a unit buffer is shown with respect to the blowing rate r, it can be defined as B = T * r. When the equations 6 and 7 are substituted into the relational expression regarding the size B of the data to be taken in,

B = (Ts + Tf + To + Tw ^* ) r

<=> B / r = (Ts + Tf + To + (B / R))

Through the operation of, a relational expression such as Equation 8 regarding the waiting time To may be derived.

Meanwhile, in the first storage method of FIG. 6B, when the operation of the storage medium 110 is performed, power consumption W may be defined as shown in Equation 9 below. Here, Po means power consumption in the standby stage of the storage medium 110, Ws means power consumption in the start stage, Wf means power consumption in the termination stage, and Pw means power consumption in the recording stage.

In addition, in the second storage method of FIG. 6A, the power amount W ′ consumed when each operation of the storage medium 110 is performed may be defined as in Equation 10. FIG.

In order to prove the low power effect of the present invention, the equations (9) and (10) defined above can be compared to obtain a relational expression (the amount of power of the first storage method W <the amount of power W` of the second storage method).

ToPo + Ws + Wf + Tw ^* Pw <(To + Ts + Tw ^* + Tf)

<=> [B (1 / r)-(1 / R))-(Ts + Tf)] Po + Ws + Wf <[B · ((1 / r)-(1 / R))] Pw

<=> Ws + Wf-(Ts + Tf) Po <[B · ((1 / r)-(1 / R))] · (Pw-Po)

By arranging such a relationship with the buffer size B, Equation 11 can be obtained. Accordingly, the buffer size B of the optimal unit buffer for saving power consumption is defined.

When a buffer size B that can be used in accordance with a predetermined storage device is predetermined (for example, a hard disk manufactured to a regular specification, etc.), the storage system designated by the buffer size B consumes a power amount according to the size of the input data. It can be said that it is desirable to selectively adopt a storage method with a minimum of. For example, the selection of the storage method may be induced through Equation 12, which is a comparative relationship between Equation 9 (first storage method) and Equation 10 (second storage method).

In other words, when the comparison relation of Equation 12 is established (when the size of data accumulated in the buffer module 240 is large enough), the storage medium 110 includes a first storage method, that is, an operation in which an idle operation is excluded. Can be controlled to perform circularly. On the other hand, if Equation 12 does not hold (when the size of the data accumulated in the buffer module 240 is not large enough), the storage medium 110 is used as a recording operation and a revolving operation. While performing the repetitive operation, the storage medium 110 may be controlled to perform an operation of storing data.

In addition, with reference to Equation 11, a relational expression for the recording time Tw with respect to power consumption can be calculated.

In other words, by substituting 'B = Tw · R' in equation (11) and arranging it in terms of Tw, a relational expression as in equation (13) can be obtained. Accordingly, the recording time Tw is related to power in addition to the relational expression relating to the time described above. It can be expressed as a relational expression.

Therefore, the low power data storage system 200 according to the present embodiment can completely eliminate the idle of the storage medium 110 that consumes unnecessary power by accurately recognizing the recording mode operation time and the holding time of the storage medium 110. In addition, by providing a predetermined size of data to be stored and processed with a predetermined storage command, an advantage of ensuring stable storage processing may be obtained.

In addition, unlike the prior art, the capacity of the buffer module 240 is designed to satisfy the above Equation 11 when designing the computer system, or to selectively execute the data storage system according to the present invention only when the Equation 11 is satisfied. Or allocating a temporary buffer to satisfy Equation (11).

In addition, the present invention facilitates operations such as determining the capacity of the buffer module 240, designing the unit buffer, and allocating different accumulation capacities of the unit buffers through accurate determination of the duration of each operation of the storage medium 110. You can get the effect that you can support.

The work flow of the low power data storage system 200 according to the present invention having such a configuration will be described in detail.

The low-power data storage method of the present invention can be roughly divided into determining the recording time Tw and the buffer size B according to a criterion for determining the recording data S stored and stored in the recording mode operation of the storage medium 110, respectively. The low power data storage method is performed by the low power data storage system 200 described above.

First, a low power data storage method by selecting the recording time Tw will be described with reference to FIG.

7 is a flowchart illustrating a low power data storage method according to a preferred embodiment of the present invention in detail.

First, the low power data storage system 200 determines the size of data to be stored and processed during the recording time Tw as the recording data S (S710). This step S730 is a process of determining the size of the data accumulated in the buffer module 240. For example, when the buffer module 240 includes one or more unit buffers having a predetermined capacity, the data taking means 220 ) Stores and stores only the size of data to be stored and processed during the recording time Tw in each unit buffer. This recording time Tw can be derived by the above equations (1) and (2),

,

or Calculate to satisfy.

Next, the low power data storage system 200 receives the data generated by the predetermined signal processing (S720). This step (S720) is a process of receiving data generated by a predetermined data generation-related application in the low power data storage system 200, the application program is a remote data communication means (e.g., content providing server, voice / Image information providing device) or a data generating terminal (eg, camera, microphone).

Subsequently, the low power data storage system 200 imports the input data into the buffer module 240 by, for example, the data taking means 220 (S730). The step S730 is a process of accumulating and accumulating data of the determined recording data S in the buffer module 240 according to a predetermined criterion, and storing the data in the unit buffer included in the buffer module 240 according to a predetermined blowing order. Accumulate data sequentially.

After the waiting time To elapses, the low power data storage system 200 determines whether the data accumulated in the buffer module 240 reaches the write data S (S740). This step S740 is a process of determining whether data of sufficient size (more than write data S) has accumulated in the buffer module 240.

When the data accumulated in the predetermined unit buffer reaches the write data S in step S740 (Yes direction in step S740), the low power data storage system 200 generates a storage command for extracting the accumulated data. (S750). This step 750 is a process of generating a storage command after the To time has elapsed from the time of taking data into the buffer module 240, and the extracted data is stored and processed through the recording mode operation of the storage medium 110. In addition, the step S750 may be a process of determining the size of the data accumulated in the buffer module 240 as the write data S to be stored and processed to be extracted by the write control means 230 during the waiting time To. The waiting time To may be derived based on Equations 3 and 4 from Tw ^* satisfying the above-described relation,

It can be calculated to satisfy.

After the data extraction process from the buffer module 240 is completed, the low power data storage system 200 determines whether there is data input to the low power data storage system 200 (S760). This step (S760) is a process of determining whether there is data that has not performed the storage processing for the data generated by a predetermined data generation-related application program, if there is input data, the low power data storage system of the present invention 200 returns to step S730 to perform a data import process to the buffer module 240.

In addition, when the data accumulated in the predetermined unit buffer in step S740 does not reach the write data S (No direction in step S740), the low power data storage system 200 generates a predetermined forced storage command and generates a storage medium ( In operation S770, the storage process for the accumulated data of the buffer module 240 is performed. In operation S770, when the size of data accumulated in the buffer module 240 does not reach the write data S during the waiting time To, the step S770 is a process for performing storage processing on the accumulated accumulated data. The low-power data storage system 200 of the present invention can perform the extraction processing of the residual data smaller than the recording data S, which cannot be extracted from the buffer module 240, so that the flexible data extraction processing can be performed.

Therefore, according to the low-power data storage method of the present invention, as the data stored during the waiting time To is stored for the recording time Tw, the timing of occurrence of the storage command and the holding time of each operation of the storage medium 110 are accurately determined. The effect of completely eliminating idle of the storage medium 110 that is unnecessary power consumption can be obtained.

Hereinafter, a low power data storage method by determining the buffer size B of the present invention will be described with reference to FIG.

8 is a flowchart illustrating a low power data storage method according to another embodiment of the present invention in detail.

First, the low power data storage system 200 determines the buffer size B as the write data S which is the size of the data processed by the recording mode operation of the storage medium 110, and the determined write data S to the buffer module 240. Control to accumulate the data corresponding to (S810). This step (S810) is a process of determining the recording data S based on the unit buffer of the buffer module 240, accumulating the data of the buffer size B in one unit buffer, and when the accumulation of the corresponding unit buffer is completed in order The taking-in processing of the data taking-in means 220 is performed with the unit buffer of.

This buffer size B can be derived based on Equation 5 and Equation 2,

,

or,

It can be calculated to satisfy.

That is, the buffer size B may be the size of the data to be stored and processed when the recording mode operation of the storage medium 110 is performed, and the data taking means 220 causes the data of the buffer size B to be accumulated in each unit buffer. The constant recording data S is determined.

Next, the low power data storage system 200 receives the data generated by the predetermined signal processing (S820). The input data is blown into the buffer module 240 (S830). Since the steps S820 and S830 correspond to the above-described steps S710 and S720 of FIG. 7, a detailed description thereof will be omitted. However, in step S830, the processing of taking in the data of the data taking means 220 is performed according to a predetermined taking order, and the size of data accumulated in one unit buffer is limited to the buffer size B.

Subsequently, the low power data storage system 200 determines whether the size of data stored in the unit buffer of the buffer module 240 reaches m (m1, m2, m3) after a predetermined time (S840). This step S840 is a process of determining whether the storage medium 110 has accumulated enough data in the buffer module 240, that is, data of sufficient size to be stored and processed in the recording mode operation.

When the size of the data accumulated in the predetermined unit buffer reaches m (m1, m2, m3) in step S840 (Yes direction in step S840), the low power data storage system 200 extracts the accumulated data. A storage command for generating is generated (S850). In step 850, the storage command is generated based on the calculated buffer size B in consideration of the time when the size of the data accumulated in the specific unit buffer reaches the buffer size B, that is, the write data S. The process of allowing data to be extracted from the unit buffer that has reached the detailed description is replaced with the above-described description of FIG. 5B. However, the setting of m, which is the generation time of the storage command and m ^* , which is the end of the recording mode, in FIG. You can change it flexibly.

After the data extraction process from the buffer module 240 is completed, the low power data storage system 200 determines whether there is data input to the low power data storage system 200 (S860), and if there is data In operation S830, the low power data storage system 200 feeds back the data into the buffer module 240.

In addition, when the size of data accumulated in the predetermined unit buffer in step S840 does not reach m (m1, m2, m3) (No direction in step S840), the low power data storage system 200 generates a predetermined forced storage command. In operation S870, the storage medium 110 performs a storage process on the accumulated data of the buffer module 240.

Accordingly, in the low power data storage method of the present invention, the idle time of the storage medium 110 vaguely waiting for the data storage command by accurately measuring the time of generation of the storage command and the retention time of the recording mode on the basis of the accumulated unit buffer. The effect of realizing the data storage by low power can be obtained by excluding.

Embodiments of the invention include a computer readable medium containing program instructions for performing various computer-implemented operations. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. The media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical recording media such as CD-ROMs, DVDs, magnetic-optical media such as floppy disks, and ROM, RAM, flash memory, and the like. Hardware devices specifically configured to store and execute the same program instructions are included. The medium may be a transmission medium such as an optical or metal wire, a waveguide, or the like including a carrier wave for transmitting a signal specifying a program command, a data structure, or the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like.

9 is an internal block diagram of a general purpose computer device that may be employed to perform a low power data storage method in accordance with the present invention.

Computer device 900 includes one or more processors 910 coupled with a main memory device including random access memory (RAM) 920 and read only memory (ROM) 930. The processor 910 is also called a central processing unit (CPU). As is well known in the art, the ROM 930 serves to transfer data and instructions to the CPU unidirectionally, and the RAM 920 typically transfers data and instructions bidirectionally. Used to. RAM 920 and ROM 930 may include any suitable form of computer readable media. Mass storage 940 is bidirectionally coupled to processor 910 to provide additional data storage capability and may be any of the computer readable recording media described above. The mass storage device 940 is used to store programs, data, and the like, and is a secondary memory device such as a hard disk which is generally slower than the main memory device. Certain mass storage devices such as CD ROM 960 may be used. The processor 910 may include one or more input / output interfaces, such as video monitors, trackballs, mice, keyboards, microphones, touchscreen displays, card readers, magnetic or paper tape readers, voice or handwriting readers, joysticks, or other known computer input / output devices. 950. Finally, the processor 910 may be connected to a wired or wireless communication network through the network interface 970. Through this network connection, the procedure of the method described above can be performed. The apparatus and tools described above are well known to those skilled in the computer hardware and software arts.

The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention.

While specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims below, but also by the equivalents of the claims.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

As can be seen from the above description, according to the present invention, the data received by the data input means is accumulated in a predetermined temporary storage device, and the operation of the storage medium is based on the size of the accumulated data or the time required for the accumulation. It is possible to provide a low power data storage system and a data storage method capable of achieving low power by completely eliminating idle operation of a storage medium vaguely waiting for a storage command by controlling.

Further, according to the present invention, stable storage is determined by determining the recording data S and the recording time Tw based on the operational performance characteristics of the storage medium and the storage speed of the data, and quantifying the size of the data to be stored and processed in one continuous recording mode. It is possible to provide a low power data storage system and a data storage method capable of performing the processing and accurately determining the timing of occurrence of a storage command and each operation holding time of the storage medium.

Further, according to the present invention, the buffer size B is determined based on the recording data S, thereby making the design and management of the buffer easier, and the low-power data storage system capable of accurately measuring the time of generation of the storage command and the holding time of each operation. And a data storage method.

In addition, according to the present invention, by arranging a plurality of buffers that serve as a buffer between the data generated synchronously or asynchronously and the storage medium operating synchronously to ensure a smooth processing of incoming data continuously, It is possible to provide a low power data storage system and a data storage method which allow stable storage processing by accumulating data of the recording data S.

1 is a view for explaining a schematic operation of a low power data storage system according to the present invention.

2 is a block diagram showing a low power data storage system according to a preferred embodiment of the present invention.

3 is a view for explaining the performance of each operation of the storage medium performed by the control of the recording control means according to the present invention.

4A is a diagram illustrating an example of data inputted with parallax, and FIG. 4B is a diagram illustrating an example of data accumulated in a buffer module of the present invention.

5A is a diagram illustrating an example of a buffer module according to the present invention.

5B is a diagram illustrating a change in data size accumulated in a buffer module including one or more unit buffers according to the present invention.

FIG. 6A is a diagram illustrating a power consumption form when storing data according to the prior art, and FIG. 6B is a diagram illustrating a power consumption form when storing data according to the present embodiment.

7 is a flowchart illustrating a low power data storage method according to a preferred embodiment of the present invention in detail.

8 is a flowchart illustrating a low power data storage method according to another embodiment of the present invention in detail.

9 is an internal block diagram of a general purpose computer device that may be employed to perform a low power data storage method in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

200: low power data storage system 210: data input means

220: data taking means 230: recording control means

240: buffer module

Claims (12)

In a data storage system, Data input means for receiving data generated by predetermined signal processing; Data taking means for taking in and storing the input data into a buffer module; And Recording control means for extracting said data of a predetermined size from said buffer module and recording it in a storage medium in accordance with a storage command Including; The recording control means starts recording the data when predetermined data is accumulated in the buffer module, and controls the storage medium to be transferred to an initial state immediately after the recording of the extracted data is completed. Data storage system. The recording control means according to claim 1, wherein The storage medium, Transitioning to a recording mode according to the storage command; A recording step of performing a recording mode for recording data extracted from the buffer module; Completing recording of the data and transitioning to an initial state; And A standby step of performing a standby mode maintaining the initial state and waiting for the next storage command; Low power data storage system, characterized in that for controlling to be performed sequentially. The method of claim 1, The buffer module includes one or more unit buffers having a predetermined buffer size B, The data acquisition means stores the data corresponding to predetermined write data S in the unit buffer based on a predetermined criterion, wherein the write data S means the size of data to be stored and processed in the recording mode of the storage medium. Low power data storage system, characterized in that the control. The method of claim 3, The selected criterion is the recording time Tw of the storage medium, The data taking means determines the size of the data to be stored and processed during the recording time Tw as the recording data S, The recording time Tw is, Low power data storage system, characterized in that the setting to satisfy. The method of claim 4, wherein The recording time Tw is, Low power data storage system, characterized in that to set to more satisfy. Po is power consumption in the standby mode, Ws is the power consumption in the transition to the recording mode, Wf is the power consumption in the transition to the initial state, Pw means power consumption in the recording mode box- The method of claim 5, The storage command is generated after the waiting time To elapses from the time when the data is input into the buffer module. The waiting time To is, And Tw ^* is a predetermined recording time that satisfies the recording time Tw. And the write control means controls to store and store the data accumulated in the unit buffer during the set waiting time To for the write time Tw ^* . The method of claim 3, The predetermined criterion is the buffer size B of the unit buffer, The data importing means determines the buffer size B as the recording data S, The buffer size B is , Low power data storage system, characterized in that the setting to satisfy. The method of claim 7, wherein The buffer size B is Low power data storage system, characterized in that to set to more satisfy. The method of claim 7, wherein The storage command occurs when the size of the data accumulated in the buffer module reaches m, and continues until the size of the data reaches m ^* , The write control means may take into consideration at least one of a taking-up speed r, a storage rate R, a startup time Ts, an end time Tf, and power consumption in performing the operation, of the data taken into the unit buffer of the buffer module, m. And m ^* , the low power data storage system. In a method of storing data, Receiving data generated by predetermined signal processing; Injecting and storing the input data into a buffer module; And Extracting the data from the buffer module and writing the data to a storage medium according to a storage command generated when a waiting time To time elapses from the time of taking the data; Including; The step of accumulating the input data into a buffer module, Determining the size of the data to be stored and stored for a predetermined write time Tw as write data S, and controlling the data corresponding to the determined write data S to be accumulated in the buffer module. Including, The recording time Tw is, , or Low power data storage method characterized in that the setting to satisfy. In a method of storing data, Receiving data generated by predetermined signal processing; Injecting and storing the input data into a buffer module; And Extracting the data from the buffer module and writing the data to a storage medium according to a storage command generated when the size of data accumulated in the buffer module reaches m Including; The step of accumulating the input data into a buffer module, Determining a predetermined buffer size B as recording data S which is a size of data to be stored and processed in the recording mode of the storage medium, and controlling the data corresponding to the determined recording data S to be accumulated in the buffer module; Including, The buffer size B is , or Low power data storage method characterized in that the setting to satisfy. A computer-readable recording medium having recorded thereon a program for executing the method of claim 10 or 11.