CN115857806B - Integrated circuit system of multifunctional memory and control method thereof - Google Patents

Abstract

The invention provides an integrated circuit system of a multifunctional memory and a control method thereof. The integrated circuit system includes a plurality of memories and a memory controller; the storage control signal output end of the storage controller is connected with the storage signal input ends of the memories; the data storage signal input end of the storage controller is connected with the data information output end of the external data generating equipment or platform for data transmission. The control method comprises the steps that a storage controller screens out partial memories from a plurality of memories to perform initial operation; selecting and storing in a memory which is operated initially according to the data quantity corresponding to the data to be stored once; the memory controller sets the memory amplification start number and the standard memory value of the memory amplification start according to the memory data amount acquired from the external data generating device or platform in the unit time period and the total memory residual amount corresponding to the memory which is operated initially.

Description

Integrated circuit system of multifunctional memory and control method thereof

Technical Field

The invention provides an integrated circuit system of a multifunctional memory and a control method thereof, belonging to the technical field of integrated circuits.

Background

With the continuous development of software technology, various large-scale platform systems are gradually applied to various industries, and all large-scale service platforms are provided with memories for data storage. However, the memory has only a memory function, and the memory cannot be adjusted to increase the memory according to the change of the amount of data stored.

Disclosure of Invention

The invention provides an integrated circuit system of a multifunctional memory and a control method thereof, which are used for solving the problem that the existing memory only has a memory function and cannot carry out amplification adjustment of the memory according to the change condition of the stored data volume, and the adopted technical scheme is as follows:

an integrated circuit system of a multi-function memory, the integrated circuit system comprising a plurality of memories and a memory controller; the storage control signal output end of the storage controller is connected with the storage signal input ends of a plurality of storages; the data storage signal input end of the storage controller is connected with the data information output end of the external data generating equipment or platform for data transmission.

Further, the memory controller includes:

the screening module is used for controlling the storage controller to screen part of the memories from the memories for initial operation;

the storage control module is used for controlling the storage controller to selectively store the data to be stored sent by the external data generating equipment or the platform received in the unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored once; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage;

the setting module is used for controlling the storage controller to set the storage amplification starting quantity and the standard storage value of the storage amplification starting according to the storage data quantity acquired from the external data generating equipment or platform in the unit time period and the total storage residual quantity corresponding to the initially operated storage.

Further, the screening module includes:

the quantity setting module is used for setting the quantity of the initial started memories according to the preset initial starting constraint conditions of the memories by the memory controller; wherein, the initial starting constraint condition of the memory is as follows:

0.3N ₀ <N<0.5N ₀

wherein N is ₀ Representing the total number of memories; n represents the initial starting memoryNumber of pieces;

and the initial starting module is used for screening the memories with the number equal to the number of the memories from the memories according to the number of the memories to perform initial starting, and the other unselected memories are in a dormant running state.

Further, the setting module includes:

the information monitoring and acquiring module is used for monitoring the storage data amount acquired from the external data generating equipment or platform in each unit time period by the storage controller and extracting the residual storage amount of the memory which is started to perform initial operation currently at the end time of each unit time period;

the parameter setting module is used for obtaining standard storage values of the memory amplification starting according to the storage data quantity obtained from the external data generating equipment or platform in each unit time period and the residual storage quantity of the memory which is started to be operated initially and corresponds to the ending moment of the unit time period, combining the storage data quantity standard value setting model, and obtaining the amplification starting quantity of the memory by utilizing the amplification starting quantity model;

and the quantity adjusting module is used for monitoring the occupied storage quantity of the memories which are started to perform initial operation in real time by the storage controller, and starting the memories with the corresponding quantity in the memories in the dormant operation state according to the quantity of memory amplification starting when the occupied storage quantity reaches the standard storage value.

Further, the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w (W) ₀ Representing that the preset occupied memory capacity threshold value is reached, the memory capacity reaches W ₀ Starting the setting of the standard storage value, and W ₀ The range of the value of (C) is 0.58W _z -0.64W _z ；W _z Representing an initial start-up total amount of storage space; w (W) _max Representing the most recent occurrence in a historical unit time periodLarge data storage amount; n represents that the data storage amount reproduced in the history unit time period is at [0.78W ] _max ，W _max ]The number of unit time periods of the range; w (W) _y Represents the remaining memory space, when (1- (W) _y /W _max ) ^-1 When N is less than or equal to 0, making (1- (W) _y /W _max ) ^-1 N)＝0.28；

The amplification starting quantity model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; fmax represents the amplitude ratio value of maximum amplification in every two adjacent unit time periods in n unit time periods; w (W) _p Representing an average stored data amount per unit time period within n unit time periods; w (W) _d Representing the rated storage capacity corresponding to each memory; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

A control method of an integrated circuit system of a multifunctional memory, the control method comprising:

the storage controller screens partial memories from the memories to perform initial operation;

the storage controller selectively stores the data to be stored sent by the external data generating equipment or the platform received in a unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored for a single time; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage;

the memory controller sets the memory amplification start number and the standard memory value of the memory amplification start according to the memory data amount acquired from the external data generating device or platform in the unit time period and the total memory residual amount corresponding to the memory which is operated initially.

Further, the memory controller screens a partial number of the plurality of memories for initial operation, including:

the storage controller sets the quantity of the initial started memories according to preset initial starting constraint conditions of the memories; wherein, the initial starting constraint condition of the memory is as follows:

0.3N ₀ <N<0.5N ₀

wherein N is ₀ Representing the total number of memories; n represents the number of memory devices that are initially started;

and screening the memories with the same number as the memories from the memories according to the number of the memories to start initially, wherein other unselected memories are in a dormant running state.

Further, the memory controller sets the memory amplification start number and the standard memory value of the memory amplification start according to the memory data amount acquired from the external data generating device or platform in the unit time period and the total memory residual amount corresponding to the memory which is operated initially, and includes:

the storage controller monitors the storage data amount acquired from the external data generating equipment or platform in each unit time period, and extracts the residual storage amount of the memory which is started to perform initial operation currently at the end time of each unit time period;

according to the storage data amount obtained from the external data generating equipment or platform in each unit time period and the residual storage amount of the memory which is started to be operated initially and corresponds to the ending time of the unit time period, a standard storage value of memory amplification starting is obtained by combining a storage data amount standard value setting model, and the amplification starting quantity of the memory is obtained by utilizing an amplification starting quantity model;

and the storage controller monitors the occupied storage capacity of the storage which is started to perform initial operation in real time, and starts a corresponding number of memories in the dormant operation state according to the memory amplification starting number when the occupied storage capacity reaches the standard storage value.

Further, the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w (W) ₀ Representing that the preset occupied memory capacity threshold value is reached, the memory capacity reaches W ₀ Starting the setting of the standard storage value, and W ₀ The range of the value of (C) is 0.58W _z -0.64W _z ；W _z Representing an initial start-up total amount of storage space; w (W) _max Representing the maximum data storage amount occurring in the historical unit time period; n represents that the data storage amount reproduced in the history unit time period is at [0.78W ] _max ，W _max ]The number of unit time periods of the range; w (W) _y Represents the remaining memory space, when (1- (W) _y /W _max ) ^-1 When N is less than or equal to 0, making (1- (W) _y /W _max ) ^-1 N)＝0.28。

Further, the amplification start number model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; fmax represents the amplitude ratio value of maximum amplification in every two adjacent unit time periods in n unit time periods; w (W) _p Representing an average stored data amount per unit time period within n unit time periods; w (W) _d Representing each memory pairA nominal storage capacity to be used; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

The invention has the beneficial effects that:

the integrated circuit system of the multifunctional memory and the control method thereof can meet the storage operation work of mass data by arranging a plurality of memories. Meanwhile, the data storage capacity of the large platform operation system is increased along with the increase of time, so that the problem of resource waste is avoided, when the data storage capacity of the large platform system in the initial operation stage is smaller, only part of memories are started to complete data storage operation, meanwhile, the data storage capacity is monitored in real time through a storage controller, and the adjustment control of the increase of the memories is carried out through the data storage capacity, so that the storage capacity of the memories along with the increase of the stored data capacity is effectively improved, and the self-adaptive adjustment capacity and efficiency of the storage capacity are improved.

Drawings

FIG. 1 is a system block diagram of an integrated circuit system according to the present invention;

FIG. 2 is a flow chart of a method for controlling an integrated circuit system according to the present invention.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

The embodiment of the invention provides an integrated circuit system of a multifunctional memory, which is shown in figure 1 and comprises a plurality of memories and a memory controller; the storage control signal output end of the storage controller is connected with the storage signal input ends of a plurality of storages; the data storage signal input end of the storage controller is connected with the data information output end of the external data generating equipment or platform for data transmission.

Wherein the memory controller includes:

the screening module is used for controlling the storage controller to screen part of the memories from the memories for initial operation;

the storage control module is used for controlling the storage controller to selectively store the data to be stored sent by the external data generating equipment or the platform received in the unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored once; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage;

the setting module is used for controlling the storage controller to set the storage amplification starting quantity and the standard storage value of the storage amplification starting according to the storage data quantity acquired from the external data generating equipment or platform in the unit time period and the total storage residual quantity corresponding to the initially operated storage.

The working principle of the technical scheme is as follows: firstly, controlling a storage controller to screen part of memories from a plurality of memories through a screening module to perform initial operation; then, the storage control module is used for controlling the storage controller to selectively store the data to be stored sent by the external data generating equipment or the platform received in a unit time period in the initially operated storage according to the data quantity corresponding to the data to be stored for a single time; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage; then, the storage controller is controlled by the setting module to set the storage amplification starting number and the standard storage value of the storage amplification starting according to the storage data amount acquired from the external data generating device or platform in the unit time period and the total storage residual amount corresponding to the initially operated storage.

The technical scheme has the effects that: the integrated circuit system of the multifunctional memory provided by the embodiment can meet the storage operation work of mass data by arranging a plurality of memories. Meanwhile, the data storage capacity of the large platform operation system is increased along with the increase of time, so that the problem of resource waste is avoided, when the data storage capacity of the large platform system in the initial operation stage is smaller, only part of memories are started to complete data storage operation, meanwhile, the data storage capacity is monitored in real time through a storage controller, and the adjustment control of the increase of the memories is carried out through the data storage capacity, so that the storage capacity of the memories along with the increase of the stored data capacity is effectively improved, and the self-adaptive adjustment capacity and efficiency of the storage capacity are improved.

In one embodiment of the present invention, the screening module includes:

the quantity setting module is used for setting the quantity of the initial started memories according to the preset initial starting constraint conditions of the memories by the memory controller; wherein, the initial starting constraint condition of the memory is as follows:

0.3N ₀ <N<0.5N ₀

wherein N is ₀ Representing the total number of memories; n represents the number of memory devices that are initially started;

and the initial starting module is used for screening the memories with the number equal to the number of the memories from the memories according to the number of the memories to perform initial starting, and the other unselected memories are in a dormant running state.

The working principle of the technical scheme is as follows: firstly, controlling a storage controller to set the quantity of the initial started memories according to preset initial starting constraint conditions of the memories through a quantity setting module; and then, screening the memories with the same number as the memory number from the memories by using an initial starting module to perform initial starting, wherein other unselected memories are in a dormant running state.

The technical scheme has the effects that: because the data storage capacity of the large platform operation system is increased along with the increase of time, in order to avoid the problem of resource waste, when the data storage capacity of the large platform system in the initial operation stage is smaller, only part of memories are started to complete the data storage operation, and the condition of resource waste can be effectively reduced. Meanwhile, the setting of the total memory quantity is actually estimated by using the data storage quantity of the large-scale system platform, so that the numerical value setting of the total memory quantity indirectly reflects the overall prejudging condition of the overall data to be stored of the large-scale system platform, the reasonable distribution property between the initial memory quantity setting and the total memory quantity can be effectively improved through the setting of the initial starting memory quantity under the constraint condition, the problem that the operation load of a memory controller is increased due to the fact that the memory quantity is frequently increased due to the fact that the initial starting memory quantity setting is too small is prevented, meanwhile, the problem that the use of the storage space is insufficient when the data storage quantity of the large-scale platform system is small at the initial operation stage due to the fact that the memory quantity setting is too large can be prevented, but the initial starting memory is always in an operation state, so that energy consumption is increased, and the problem of energy waste is caused is solved.

In one embodiment of the present invention, the setting module includes:

the information monitoring and acquiring module is used for monitoring the storage data amount acquired from the external data generating equipment or platform in each unit time period by the storage controller and extracting the residual storage amount of the memory which is started to perform initial operation currently at the end time of each unit time period;

the parameter setting module is used for obtaining standard storage values of the memory amplification starting according to the storage data quantity obtained from the external data generating equipment or platform in each unit time period and the residual storage quantity of the memory which is started to be operated initially and corresponds to the ending moment of the unit time period, combining the storage data quantity standard value setting model, and obtaining the amplification starting quantity of the memory by utilizing the amplification starting quantity model;

and the quantity adjusting module is used for monitoring the occupied storage quantity of the memories which are started to perform initial operation in real time by the storage controller, and starting the memories with the corresponding quantity in the memories in the dormant operation state according to the quantity of memory amplification starting when the occupied storage quantity reaches the standard storage value.

Wherein the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w (W) ₀ Representing that the preset occupied memory capacity threshold value is reached, the memory capacity reaches W ₀ Starting the setting of the standard storage value, and W ₀ The range of the value of (C) is 0.58W _z -0.64W _z ；W _z Representing an initial start-up total amount of storage space; w (W) _max Representing the maximum data storage amount occurring in the historical unit time period; n represents that the data storage amount reproduced in the history unit time period is at [0.78W ] _max ，W _max ]The number of unit time periods of the range; w (W) _y Represents the remaining memory space, when (1- (W) _y /W _max ) ^-1 When N is less than or equal to 0, making (1- (W) _y /W _max ) ^-1 N)＝0.28；

The amplification starting quantity model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; f (F) _max The amplitude ratio value representing the maximum amplification of every two adjacent unit time periods in n unit time periods; w (W) _p Representing an average stored data amount per unit time period within n unit time periods; w (W) _d Representing the rated storage capacity corresponding to each memory; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

The working principle of the technical scheme is as follows: the operation process of the setting module comprises the following steps:

firstly, controlling the storage controller to monitor the storage data amount acquired from the external data generating equipment or platform in each unit time period through an information monitoring acquisition module, and extracting the residual storage amount of a storage which is started to operate initially at the end time of each unit time period; then, a parameter setting module is utilized to obtain standard storage values of the memory amplification starting according to the storage data quantity obtained from the external data generating equipment or platform in each unit time period and the residual storage quantity of the memory which is started to perform initial operation and corresponds to the ending moment of the unit time period, a storage data quantity standard value setting model is combined to obtain standard storage values of the memory amplification starting, and an amplification starting quantity model is utilized to obtain the amplification starting quantity of the memory; and finally, controlling the storage controller to monitor the occupied storage capacity of the storage which is started to perform initial operation in real time by adopting a quantity adjusting module, and starting a corresponding quantity of storage in the storage in a dormant operation state according to the quantity of storage amplification starting when the occupied storage capacity reaches the standard storage value.

The technical scheme has the effects that: the data storage quantity is monitored in real time through the storage controller, and the adjustment control of the memory increment is carried out through the data storage quantity, so that the storage capacity of the memory along with the increase of the storage data quantity is effectively improved, and the self-adaptive adjustment capacity and efficiency of the storage capacity are improved.

Meanwhile, the standard storage numerical value obtained through the storage data amount standard value setting model enables the standard storage numerical value to be set according to the actual condition of data storage, and the accuracy and the rationality of setting the standard storage numerical value can be effectively improved. Furthermore, timeliness of amplification execution is effectively improved, and the problems that the energy consumption is increased and energy waste is caused because the memory increment setting is performed in advance and the use of a storage space is insufficient due to the fact that the standard storage numerical value setting is too low and the memory is always in an operating state are solved. Meanwhile, timeliness that storage increment setting cannot be performed due to overhigh standard storage numerical value setting can be prevented, and then the occurrence rate of storage saturation of storage equipment is increased, so that the storage efficiency is reduced, and the problem of storage failure is improved. Meanwhile, increment setting can be carried out according to actual change conditions of data storage through the increment starting quantity of the memory, so that the rationality and accuracy of increment setting can be effectively improved, the problem that resource waste is caused by insufficient use of the memory due to overlarge increment setting is prevented, the problem that frequent increment of the memory is caused by overlarge increment setting and the operation load of a memory controller is increased can be avoided.

The embodiment of the invention provides a control method of an integrated circuit system of a multifunctional memory, as shown in fig. 2, the control method comprises the following steps:

s1, screening part of memories from a plurality of memories by a memory controller for initial operation;

s2, the storage controller selectively stores the data to be stored sent by the external data generating equipment or the platform received in the unit time period in the initially operated storage according to the data quantity corresponding to the data to be stored for a single time; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage;

and S3, the storage controller sets the number of the memory amplification starts and standard storage values of the memory amplification starts according to the storage data quantity acquired from the external data generating equipment or platform in the unit time period and the total storage residual quantity corresponding to the initially operated memory.

The working principle of the technical scheme is as follows: firstly, the storage controller screens partial memories from a plurality of memories to perform initial operation; then, the storage controller selectively stores the data to be stored sent by the external data generating equipment or the platform received in the unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored for a single time; wherein, the selection principle of the selection storage is as follows: when the data quantity corresponding to the single data to be stored exceeds a preset data quantity threshold, selecting a memory with the largest remaining storage space for priority storage; when the data quantity corresponding to the single data to be stored does not exceed a preset data quantity threshold, selecting other memories except the memory with the largest remaining storage space for random selection storage; finally, the memory controller sets the memory amplification starting number and the standard memory value of the memory amplification starting according to the memory data quantity acquired from the external data generating device or platform in the unit time period and the total memory residual quantity corresponding to the memory which is operated initially.

The technical scheme has the effects that: the control method of the integrated circuit system of the multifunctional memory can meet the requirement of mass data storage operation by arranging a plurality of memories. Meanwhile, the data storage capacity of the large platform operation system is increased along with the increase of time, so that the problem of resource waste is avoided, when the data storage capacity of the large platform system in the initial operation stage is smaller, only part of memories are started to complete data storage operation, meanwhile, the data storage capacity is monitored in real time through a storage controller, and the adjustment control of the increase of the memories is carried out through the data storage capacity, so that the storage capacity of the memories along with the increase of the stored data capacity is effectively improved, and the self-adaptive adjustment capacity and efficiency of the storage capacity are improved.

In one embodiment of the present invention, a memory controller screens a partial number of memories from a plurality of memories for initial operation, comprising:

s101, setting the number of the initial started memories by a memory controller according to a preset initial starting constraint condition of the memories; wherein, the initial starting constraint condition of the memory is as follows:

0.3N ₀ <N<0.5N ₀

wherein N is ₀ Representing the total number of memories; n represents the number of memory devices that are initially started;

s102, screening the memories with the same number as the memories from the memories according to the number of the memories, and starting the memories with the same number as the memories initially, wherein other unselected memories are in a dormant running state.

The working principle of the technical scheme is as follows: firstly, setting the quantity of the initial started memories by a memory controller according to preset initial starting constraint conditions of the memories; and then, screening the memories with the same number as the memories from the memories according to the number of the memories, and starting the memories initially, wherein other unselected memories are in a dormant running state.

The technical scheme has the effects that: because the data storage capacity of the large platform operation system is increased along with the increase of time, in order to avoid the problem of resource waste, when the data storage capacity of the large platform system in the initial operation stage is smaller, only part of memories are started to complete the data storage operation, and the condition of resource waste can be effectively reduced. Meanwhile, the setting of the total memory quantity is actually estimated by using the data storage quantity of the large-scale system platform, so that the numerical value setting of the total memory quantity indirectly reflects the overall prejudging condition of the overall data to be stored of the large-scale system platform, the reasonable distribution property between the initial memory quantity setting and the total memory quantity can be effectively improved through the setting of the initial starting memory quantity under the constraint condition, the problem that the operation load of a memory controller is increased due to the fact that the memory quantity is frequently increased due to the fact that the initial starting memory quantity setting is too small is prevented, meanwhile, the problem that the use of the storage space is insufficient when the data storage quantity of the large-scale platform system is small at the initial operation stage due to the fact that the memory quantity setting is too large can be prevented, but the initial starting memory is always in an operation state, so that energy consumption is increased, and the problem of energy waste is caused is solved.

According to one embodiment of the invention, the memory controller sets the memory amplification starting number and the standard memory value of the memory amplification starting according to the memory data amount acquired from the external data generating device or platform in a unit time period and the total memory residual amount corresponding to the memory which is operated initially, and the memory controller comprises:

s301, the storage controller monitors the storage data amount acquired from the external data generating equipment or platform in each unit time period, and extracts the residual storage amount of the storage which is started to perform initial operation currently at the end time of each unit time period;

s302, obtaining a standard storage value of the memory amplification starting according to the storage data quantity obtained from an external data generating device or platform in each unit time period and the residual storage quantity of a memory which is started to perform initial operation and corresponds to the end time of the unit time period, combining a storage data quantity standard value setting model, and obtaining the amplification starting quantity of the memory by utilizing an amplification starting quantity model;

s303, the storage controller monitors the occupied storage capacity of the storage which is started to perform initial operation in real time, and when the occupied storage capacity reaches the standard storage value, the storage is started to be in a corresponding number in the storage in the dormant operation state according to the storage amplification starting number.

Wherein the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w (W) ₀ Representing that the preset occupied memory capacity threshold value is reached, the memory capacity reaches W ₀ Starting the setting of the standard storage value, and W ₀ The range of the value of (C) is 0.58W _z -0.64W _z ；W _z Representing an initial start-up total amount of storage space; w (W) _max Representing the maximum data storage amount occurring in the historical unit time period; n represents that the data storage amount reproduced in the history unit time period is at [0.78W ] _max ，W _max ]The number of unit time periods of the range; w (W) _y Represents the remaining memory space, when (1- (W) _y /W _max ) ^-1 When N is less than or equal to 0, making (1- (W) _y /W _max ) ^-1 N)＝0.28。

The amplification starting quantity model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; f (F) _max The amplitude ratio value representing the maximum amplification of every two adjacent unit time periods in n unit time periods; w (W) _p Representing an average stored data amount per unit time period within n unit time periods; w (W) _d Representing the rated storage capacity corresponding to each memory; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

The working principle of the technical scheme is as follows: firstly, the storage controller monitors the storage data amount acquired from an external data generating device or platform in each unit time period, and extracts the residual storage amount of a memory which is started to perform initial operation currently at the end time of each unit time period; then, according to the storage data amount obtained from the external data generating equipment or platform in each unit time period and the residual storage amount of the memory which is started to be operated initially and corresponds to the end time of the unit time period, a standard storage value of memory amplification starting is obtained by combining a storage data amount standard value setting model, and the amplification starting quantity of the memory is obtained by utilizing an amplification starting quantity model; and finally, the storage controller monitors the occupied storage capacity of the storage which is started to perform initial operation in real time, and when the occupied storage capacity reaches the standard storage numerical value, the storage is started to be in a corresponding number in the storage in the dormant operation state according to the storage amplification starting number.

The technical scheme has the effects that: the data storage quantity is monitored in real time through the storage controller, and the adjustment control of the memory increment is carried out through the data storage quantity, so that the storage capacity of the memory along with the increase of the storage data quantity is effectively improved, and the self-adaptive adjustment capacity and efficiency of the storage capacity are improved.

Meanwhile, the standard storage numerical value obtained through the storage data amount standard value setting model enables the standard storage numerical value to be set according to the actual condition of data storage, and the accuracy and the rationality of setting the standard storage numerical value can be effectively improved. Furthermore, timeliness of amplification execution is effectively improved, and the problems that the energy consumption is increased and energy waste is caused because the memory increment setting is performed in advance and the use of a storage space is insufficient due to the fact that the standard storage numerical value setting is too low and the memory is always in an operating state are solved. Meanwhile, timeliness that storage increment setting cannot be performed due to overhigh standard storage numerical value setting can be prevented, and then the occurrence rate of storage saturation of storage equipment is increased, so that the storage efficiency is reduced, and the problem of storage failure is improved. Meanwhile, increment setting can be carried out according to actual change conditions of data storage through the increment starting quantity of the memory, so that the rationality and accuracy of increment setting can be effectively improved, the problem that resource waste is caused by insufficient use of the memory due to overlarge increment setting is prevented, the problem that frequent increment of the memory is caused by overlarge increment setting and the operation load of a memory controller is increased can be avoided.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (4)

1. An integrated circuit system for a multi-function memory, the integrated circuit system comprising a plurality of memories and a memory controller; the storage control signal output end of the storage controller is connected with the storage signal input ends of a plurality of storages; the data storage signal input end of the storage controller is connected with the data information output end of external data generating equipment or a platform for data transmission of the storage controller;

the memory controller includes:

the screening module is used for controlling the storage controller to screen part of the memories from the memories for initial operation;

the storage control module is used for controlling the storage controller to selectively store the data to be stored sent by the external data generating equipment or the platform received in the unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored once;

the setting module is used for controlling the storage controller to set the storage amplification starting quantity and the standard storage value of the storage amplification starting according to the storage data quantity acquired from the external data generating equipment or platform in the unit time period and the total storage residual quantity corresponding to the initially operated storage;

the setting module includes:

the information monitoring and acquiring module is used for monitoring the storage data amount acquired from the external data generating equipment or platform in each unit time period by the storage controller and extracting the residual storage amount of the memory which is started to perform initial operation currently at the end time of each unit time period;

the parameter setting module is used for obtaining standard storage values of the memory amplification starting according to the storage data quantity obtained from the external data generating equipment or platform in each unit time period and the residual storage quantity of the memory which is started to be operated initially and corresponds to the ending moment of the unit time period, combining the storage data quantity standard value setting model, and obtaining the amplification starting quantity of the memory by utilizing the amplification starting quantity model;

the quantity adjusting module is used for monitoring the occupied storage quantity of the memory which is started to perform initial operation in real time by the memory controller, and starting a corresponding quantity of memories in the dormant operation state according to the memory amplification starting quantity when the occupied storage quantity reaches the standard storage value;

the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w0 represents a preset occupied memory capacity threshold value, when the memory capacity reaches W0, the setting of the standard memory value is started, and the value range of W0 is 0.58Wz-0.64Wz; wz represents the total amount of memory initially started; wmax represents the maximum data storage amount that occurs in the history unit time period; n represents the number of unit time periods in which the reproduced data storage amount in the history unit time period is in the range of [0.78Wmax, wmax ]; wy represents the remaining memory space, when (1- (Wy/Wmax) -1N) +.0, let (1- (Wy/Wmax) -1N) =0.28;

the amplification starting quantity model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; fmax represents the amplitude ratio value of maximum amplification in every two adjacent unit time periods in n unit time periods; wp represents the average stored data amount per unit time period in n unit time periods; wd represents the rated storage capacity for each memory; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

2. The integrated circuit system of claim 1, wherein the screening module comprises:

the quantity setting module is used for setting the quantity of the initial started memories according to the preset initial starting constraint conditions of the memories by the memory controller; wherein, the initial starting constraint condition of the memory is as follows:

0.3N0<N<0.5N0

wherein N0 represents the total number of memories; n represents the number of memory devices that are initially started;

and the initial starting module is used for screening the memories with the number equal to the number of the memories from the memories according to the number of the memories to perform initial starting, and the other unselected memories are in a dormant running state.

3. A method for controlling an integrated circuit system of a multifunctional memory, the method comprising:

the storage controller screens partial memories from the memories to perform initial operation; the storage controller selectively stores the data to be stored sent by the external data generating equipment or the platform received in a unit time period in the initially operated memory according to the data quantity corresponding to the data to be stored for a single time;

the storage controller sets the number of the memory amplification starts and the standard storage value of the memory amplification starts according to the storage data quantity acquired from the external data generating equipment or platform in the unit time period and the total storage residual quantity corresponding to the initially operated memory;

the memory controller sets the memory amplification start number and the standard memory value of the memory amplification start according to the memory data amount acquired from the external data generating device or platform in the unit time period and the total memory residual amount corresponding to the memory which is operated initially, and the memory controller comprises:

the storage controller monitors the storage data amount acquired from the external data generating equipment or platform in each unit time period, and extracts the residual storage amount of the memory which is started to perform initial operation currently at the end time of each unit time period;

according to the storage data amount obtained from the external data generating equipment or platform in each unit time period and the residual storage amount of the memory which is started to be operated initially and corresponds to the ending time of the unit time period, a standard storage value of memory amplification starting is obtained by combining a storage data amount standard value setting model, and the amplification starting quantity of the memory is obtained by utilizing an amplification starting quantity model; the storage controller monitors the occupied storage capacity of the storage which is started to perform initial operation in real time, and when the occupied storage capacity reaches the standard storage value, the storage with the corresponding quantity is started in the storage in the dormant operation state according to the quantity of the storage amplification starting;

the stored data amount standard value setting model is as follows:

wherein W represents a standard storage value; w0 represents a preset occupied memory capacity threshold value, when the memory capacity reaches W0, the setting of the standard memory value is started, and the value range of W0 is 0.58Wz-0.64Wz; wz represents the total amount of memory initially started; wmax represents the maximum data storage amount that occurs in the history unit time period; n represents the number of unit time periods in which the reproduced data storage amount in the history unit time period is in the range of [0.78Wmax, wmax ]; wy represents the remaining memory space, when (1- (Wy/Wmax) -1N) +.0, let (1- (Wy/Wmax) -1N) =0.28;

the amplification starting quantity model is as follows:

wherein M represents the number of amplification starts of the memory; n represents the number of cycles per unit time that have elapsed between the last increase in memory, and if the memory increase is currently being performed for the first time, n represents the number of cycles per unit time that have elapsed between the initial start-up; fmax represents the amplitude ratio value of maximum amplification in every two adjacent unit time periods in n unit time periods; wp represents the average stored data amount per unit time period in n unit time periods; wd represents the rated storage capacity for each memory; alpha represents a constant coefficient, and the value range of alpha is 0.36-0.42.

4. A method of controlling an integrated circuit system according to claim 3, wherein the memory controller screens a partial number of the plurality of memories for initial operation, comprising:

the storage controller sets the quantity of the initial started memories according to preset initial starting constraint conditions of the memories; wherein, the initial starting constraint condition of the memory is as follows:

0.3N0<N<0.5N0

wherein N0 represents the total number of memories; n represents the number of memory devices that are initially started;

and screening the memories with the same number as the memories from the memories according to the number of the memories to start initially, wherein other unselected memories are in a dormant running state.