JPH03145828A - Software supplying system and its information center - Google Patents

Abstract

PURPOSE:To cope with a request for lots of users even when the scale of the software supplying system is reduced by distributing the processing of each request supplied from plural user terminal equipments nearly uniformly among the information centers of respective layers. CONSTITUTION:When a user gives a request of information software required for a lower layer information center 2a via a user terminal equipment 3a, the lower layer information center 2a retrieves whether or not the requested information software is stored in an information file and the requested information software is transferred from the information file in the lower layer information center 2a to the user terminal equipment 3a immediately. Moreover, when the requested information software is not stored in the information in the lower layer information center 2a, the request signal is fed to a high-order information center 1 via a communication center and the requested information software is transferred from the information file in the high-order information center 1.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention is a software program that individually provides information software such as music to each user terminal according to the type of request signal supplied from a large number of user terminals. It concerns the supply system.

(Problems to be solved by conventional technology and the invention) Conventionally, information software such as music is distributed and stored in several information centers, and the information software is provided in response to user requests in a single layer. system is being considered.

In general, in software supply systems, an important issue is how quickly and at low cost the information center can process a large number of requests provided by a large number of users, but in a single-layer software supply system, 1
Information software with different request frequencies coexisted within one information center, and it was necessary for the number of countries to process them quickly, and each information center required a large amount of information file capacity.

Therefore, in order to solve the above problems, the present invention prepares an information center with a multi-layered structure, stores the information software group with the highest request frequency in the information center at the lowest layer, and stores the information up to the next request frequency. Request processing (request It is an object of the present invention to provide a software supply system and its information centers that average out the load on reception, information software transfer, etc., and significantly reduce the total information file capacity of all information centers.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides software that outputs information software corresponding to individual request signals supplied from a plurality of user terminals to each of the user terminals. A supply system, in which the types of request signals supplied from the user terminal are ranked 1st to N1 in order of frequency.
a lower layer information center having an information file in which N types of information software are stored, and N2 types of information from 1st to N2th (N2>N1) in order of frequency of the request signal types; and an upper layer information center that has information files in which software is stored, and if the information software corresponding to the request signal is between the 1st place and the N1th place, the information software corresponding to the request signal. from the information file in the lower layer information center to the user terminal, and if the information software corresponding to the request signal is of the (Nl+1)th rank or lower, output the request signal to the upper layer information center. , a software supply system characterized in that information software corresponding to this request signal is transferred from an information file in the upper layer information center and output to the user terminal, or the software is supplied from a plurality of user terminals. A software supply system that outputs information software corresponding to individual request signals to each of the user terminals, wherein the first to N1st places are ranked in order of frequency of types of request signals supplied from the user terminals. a first information center that has information files in which N1 types of information software have been accumulated; N2 types of information software.

Similarly...the second... . The information file in the information center is output to the user terminal, and the information software corresponding to the request signal is the (Nl+1)th
If the request signal is lower than 1, the request signal is output to the second information center, and the information software corresponding to this request signal is transferred from the information file in the second information center and output to the user terminal. If the information software corresponding to the request signal is between the (Nn-++1)th and Nnth positions, the information software corresponding to the request signal is extracted from the information file in the nth information center. Output to the (n-1)th information center of the lower layer,
The information software corresponding to the request signal is the
+1) or lower, the request signal is output to the (n+1)th information center in the upper layer, and the information software corresponding to this request signal is sent to the (n+1)th information center in the upper layer.
) is transferred from an information file in an information center and output to the (n-1)th information center in the lower layer (where n≧2, !<N
l<N2<-<Nn-1<Nn-I+N'2,
Nn-+, Nn is a positive integer), and is further provided with an information file section used in the above-mentioned software supply system, in which a plurality of information software is stored, and a request signal is supplied with this information center. a request receiving unit that searches whether information software corresponding to the request signal is stored in the information file; and counting the number of times the request signal is supplied for each type of information software corresponding to the request signal every predetermined period. and a request counting section that calculates the request frequency for each type of information software, and a request frequency calculated by the request counting section that monitors the amount of information software accumulated in the information file section and before the accumulated amount overflows. The present invention provides an information center of a software supply system, characterized in that the information center is comprised of an erasure control section that sequentially erases information software with a small number of data from the information file section.

(Function) In a conventional single-layer software supply system, assuming that the required capacity of all the required information software is S bytes, each information center requires an information file capacity of S bytes, and it is difficult to accommodate a large number of users. Assuming that information centers are set up at various locations in order to quickly respond to request requests, the layer information file capacity of the software supply system will be KS bytes.

In contrast, the present invention described above stores all the necessary information software in one upper layer information center,
Consider a software supply system with a multi-layered structure of two or more layers in which some of the most frequently requested information software is stored in a lower-layer message center. The capacity of the information software stored in the upper layer information center is S bytes, which is the same as in the case of a single layer, and the capacity of the information software stored in the lower layer information center is T bytes (S>T). Assuming that the number of installations is the same as in the case of a single layer, the layer information file capacity of this two-layer software supply system is S
+ and -T bytes.

At this time, if the information file capacity T of the lower layer information center is set so that each request from the user is transferred to the upper layer information center at a rate of once, the average request processing amount of the upper and lower layer information centers is Then, if the information file capacity T of the lower layer information center is set to 1/C of the information file capacity S of the upper layer information center, the ratio between the two-layer software supply system and the single-layer software supply system is: It can be expressed by the following formula.

-T for S+ -3/C11 for S+ ==+ -3K - 3K C Then, considering the case where the number of lower layer information centers = 100 and the information file capacity ratio of upper and lower layer information centers C = 50, It can be seen that the total capacity of the two-layer software supply system can be significantly reduced to about 3% of the total capacity of the single-layer software supply system.

(Example) An embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing an example of the configuration of a two-layer software supply system in a multi-layer software supply system.

In FIG. 1, there are two lower layer information centers 2a and 2b below the upper layer information center 1 via communication lines, and the lower layer information center 2a.

2b for each user terminal, total of 4 user terminals 8!3
a to 3d are connected, and the majority of information software groups that are considered to have requests from users (for example, information software with request frequencies from 1st to N2nd) are stored in the information in the upper information center 1. The information software f¥ that is expected to be requested frequently by users among the information software group (for example, the request frequency is the first
It is assumed that the information software from the 1st to the 1st rank (Nl<N2; NN2 is a positive integer) are stored in the information files in the lower layer information centers 2a and 2b, respectively.

In such a two-layer software supply system, requests from users are sent to user terminals 6!3a (3b to 3d).
When the required information software is requested from the lower layer information center 2a (2b in the case of user terminals m3c and 3d) via the lower layer information center 2a (the same applies to Step 2a searches whether the requested information software is stored in the information file.

Then, if the requested information software is stored in the information file in the lower layer information center 2a (that is, if the information software corresponding to the request signal is between the 1st and N1th ranks), Lower layer information center 2 immediately
The requested information software is transferred from the information file in a to the user terminal 3a. In addition, if the requested information software is not stored in the information file in the lower layer information center 2a (that is, if the information software corresponding to the request signal is below the (Nl+1)th rank), the information software is stored in the upper layer information center 1. sends a request signal to the upper layer information center 1 via the communication line and transfers the request information), requests the requested information software to be transferred from the information file in the upper layer information center 1, and then It is stored in an information file within the layer information center 2a and is also output to the user terminal 113a.

By repeating these operations, the lower information center 2
The information software l~ stored in each of the information files a and 2b is added to the information software with a high request frequency, and at that time, by deleting the information software in order from the information software with a low request frequency, it is possible to prevent the information file from overflowing. Information software that is requested frequently can be stored in the lower-level information center 2a2b while preventing this.

Next, FIG. 2 shows an example of the configuration of an information center used in this multi-tiered software supply system.

This information center 4 is supplied with a request signal from an information file unit 7 storing a plurality of information software and a user terminal 81 or a lower information center via a request signal input terminal 5, and responds to this request signal. A request reception unit 6 searches whether the information software that has been sent is stored in the information file unit 7, and counts the number of times a request signal is supplied for each type of information software that corresponds to the request signal at predetermined intervals. A request counting unit 11 calculates the request frequency for each type of software, and monitors the amount of information software accumulated in the information file unit 7, and calculates the request frequency calculated by the request counting unit 11 before the accumulated amount overflows. It is comprised of an erasure control section 12 that sequentially erases small information software from the information file section 7.

Now, when a request signal from a user terminal or a lower information center is supplied to the request receiving unit 6 via the request signal input terminal 5, the request receiving unit 6 transfers the request content of the request signal to the request counting unit 11. At the same time, it is searched whether or not information software corresponding to the supplied request signal is stored in the information file section 7.

In addition, the request counting unit 11 counts the number of times the request signal is supplied from the request receiving unit 6 at predetermined time intervals for each type of information software, calculates the request frequency for each type of information software, and uses this as request frequency information. The data is supplied to the erasure control unit 12 as the data.

If the information software corresponding to the request signal from the request receiving section 6 is stored in the information file section 7, the information software requested from the information file section 7 is immediately sent to the user terminal via the information software output terminal 8. output to the machine or lower-level information center.

Furthermore, if the information software corresponding to the request signal is not stored in the information file section 7, the request signal is transferred to a higher level information center via the request signal output terminal 9.

A similar search is also performed at the higher-level information center to which the request signal is transferred, and the requested information software is supplied to this information center 4 via the information software input terminal 10.

In this information center 4, the information software supplied from the information software input terminal 10 is accumulated in the information file section 7, and the information software to be accumulated is sent to the user terminal I through the information software output terminal 8. Or output to a lower level information center.

By the way, if information software is supplied from a higher-level information center many times in this way, the information file section 7 will become full, and if left unattended, it will overflow.

Therefore, the erasure control section 12 always controls the information file section 7.
The number of information software (accumulated amount) in the information file section 7 is monitored, and if there is a risk of overflow, based on the request frequency information from the request counting section 11, the information file section is Among the 7 information software, the information software with the lowest request frequency is deleted in order.

By repeating this series of operations many times, the information file section 7 will always accumulate information software that is requested frequently.

Here, it is known from the aggregation results of music requests (popular songs) from broadcast stations that the frequency of music requests is expressed almost exponentially, so the frequency distribution of user requests for various information software is shown in Figure 3. Let's estimate the information file capacity assuming that it can be approximated by an exponential function as shown below.

The information software is music software, with a total of 10,000 songs (
(assuming that all songs have a constant length) is prepared, and the coefficient of the exponential distribution of the request frequency distribution is set as a=-0,0.
25 (data obtained from the aggregation results of popular song requests), and the two-layer software supply system shown in Figure 1 is modeled when there is one upper-layer information center and 100 lower-layer information centers. Let's compare this with a single-tier software supply system with 100 information centers.

In a two-layer software supply system as shown in Figure 1, 99% (on average) of steady-state requests are processed by the lower-layer information center, and the remaining 1% (on average) is sent to the upper-layer information center. If the information file capacity is allocated in such a way that the upper layer information center processes requests from 100 lower layer information centers, the request processing amount becomes almost the same as that of the lower layer information center.

Next, the information file capacity of the lower layer information center is calculated from the graph shown in FIG.

Note that X is the request rank, and K is the request rank that is first.
ε is the base of the natural logarithm.

Here, the request rank X is N1 (N+ is a positive integer)
Let Pl be the total number of requests up to that point, and P2 be the total number of requests whose request order
PI and P2 are each expressed by the following formula.

If the ratio of P2 to the total number of requests Pl+P2 is defined as a city, this city is expressed by the following formula.

2, -aN weight = Ki ε P, +P2 Therefore, if requests whose request order The percentage of cities is the city.

Then, the value of the request order N1 when the premium type to be transferred is given is as follows.

in multiple N = (where, In is the natural logarithm) From this, the coefficient a of the exponential distribution of the request frequency distribution = -
When the value is 0,025, the value of the request order N1 when the number of premium molds to be transferred is 1% or less is as follows.

N1≧i n fo, 01)/(-0,025) =1
84.2 (rank) And the request rank N at this time
If you accumulate information software up to i rank (184, 2nd rank) in the information file of the lower layer information center, the transfer rate will be 1%.
Since it can be as follows, if the capacity of the information file of the lower layer information center is R, then R≧N (184, 2), and each lower layer information center 2 can store music software of 185 songs. I understand that it is a good thing.

In addition, the capacity of the information files required by all the lower layer information centers at this time is 185xlOO=18500 (songs), and even if it is combined with the 10000 (songs) stored in the information file of the upper layer information center 1. 28500 (
It is good if there is enough capacity for songs.

On the other hand, considering a single-layer software supply system, each information center must store 10,000 (songs) in its information file, so the total capacity is 10,000.
xloo = 1 million (songs) is required, which requires a very large amount of capacity.

Although a two-layer software supply system has been described above, a software supply system can be constructed using the same concept even in the case of 311J layers or higher.

In other words, the lowest layer information center stores N1 types of information software from the 1st to the N1st in order of the frequency of request signal types, and the second information center connected immediately above this stores the information software. stores N2 types of information software in descending order of frequency of request signal types, from 1st to N2 (Nj<N2), and a third information center connected directly above it stores request signals. N from 1st to N3rd (N+ <N2 <N3) in order of frequency of signal types
By accumulating three types of information software, the nth
In the information center (n≧4; n is an integer), the request signal types are ranked 1st to N3rd in order of frequency (N+ <
N2 <N3 <...<Nn; N+N2
+N3, where Nn is a positive integer), it is sufficient to accumulate Nn types of information software.

If the information software corresponding to the request signal from the lower layer information center is between the (Nn-1+1)th and Nnth positions, the information software corresponding to the request signal is placed in the nth information center. output from the information file to the (n-1)th information center in the lower layer, and if the information software corresponding to the request signal is lower than (Nn+1), the information file is output to the (n+1)th information center in the upper layer. The request signal is output, and the information software corresponding to this request signal is transferred from the information file in the (n+1> information center of the upper layer) to the (n-1)th information center of the lower layer.
), it is possible to construct a multi-layered software supply system.

(Effects of the Invention) Since the software supply system of the present invention is a multi-layered software supply system, the processing of individual requests supplied from multiple user terminals can be almost equally distributed to the information centers of each layer. As a result, request processing can be leveled out, and the total capacity of information files in the information center can be significantly reduced, making it possible to handle the requests of many users even if the scale of the software supply system is reduced. There is.

Furthermore, since the information center of the present invention is configured to automatically accumulate information software that is frequently requested and delete information software that is less frequently requested, information software that is frequently requested is always stored in the lower layer information center. When replacing information software with new information software, just by replacing the information software in the top layer information center, the information is automatically accumulated in the lower layer information center, which has the effect of greatly reducing the effort required for maintenance. .

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of a software supply system according to the present invention, FIG. 2 is a block diagram showing an embodiment of an information center according to the present invention, and FIG. 3 is a graph showing a request frequency distribution. 1... Upper layer information center, 2a, 2b... Lower layer information center, 3a to 3d... User terminal, 4... Information center,
5... Request signal input terminal, 6... Request receiving section, 7... Information file section,
8... Information software output terminal, 9... Request signal output terminal, 10... Information software input terminal, 11... Request counting section, 12... Erasing control section. Patent Applicant: Japan Victor Co., Ltd. Representative Umiki
Kunio request signal information software N+

Claims (3)

[Claims] (1) A software supply system that outputs information software corresponding to individual request signals supplied from a plurality of user terminals to each of the user terminals, the types of request signals supplied from the user terminals a lower layer information center having an information file in which N_1 types of information software are stored, ranked 1st to N_1 in order of frequency of the request signals; and 1 to N_2 in order of frequency of the request signal types. It consists of an upper layer information center that has information files in which N_2 types of information software are stored up to (N_2>N_1), and the information software corresponding to the request signal is between the 1st place and the N_1st place. In this case, the information software corresponding to the request signal is output from the information file in the lower layer information center to the user terminal, and if the information software corresponding to the request signal is below the (N_1+1)th position, the information software corresponding to the request signal is output from the information file in the lower layer information center to the user terminal. A software supply system characterized in that the request signal is output to an upper layer information center, information software corresponding to the request signal is transferred from an information file in the upper layer information center, and output to the user terminal. . (2) A software supply system that outputs information software corresponding to individual request signals supplied from a plurality of user terminals to each of the user terminals, the types of request signals supplied from the user terminals a first information center having an information file in which N_1 types of information software are stored, ranked 1st to N_1 in order of frequency; and the frequency of types of request signals supplied from the first information center. N_2 from 1st place to N_2nd place in descending order of
Similarly, the types of request signals supplied from the lower layer information center are ranked first in order of frequency.
The second section has information files in which N_n types of information software from No. 1 to No. N_n are stored, respectively.
, an n-th information center, and if the information software corresponding to the request signal is between the 1st place and the N_1st place, the information software corresponding to the request signal is transferred to the first information center. The information file in the center is outputted to the user terminal, and if the information software corresponding to the request signal is below the (N_1+1)th place, the request signal is outputted to the second information center, and this request signal is outputted to the second information center. The information software corresponding to the request signal is transferred from the information file in the second information center and output to the user terminal, and the information software corresponding to the request signal is transferred from the information file in the second information center.
If the request signal is between _-_1+1) and N_n, the information software corresponding to the request signal is transferred from the information file in the n-th information center to the (n-1)th lower layer.
If the information software corresponding to the request signal is below the (N_n+1)th information center, the request signal is output to the (n+1)th information center in the upper layer, and the information software corresponding to the request signal is A software supply system, characterized in that information software is transferred from an information file in the (n+1)th information center in the upper layer and output to the (n-1)th information center in the lower layer;
However, n≧2, 1<N_1<N_2<...<N_n_
−_1<N_n, n, N_1, N_2, N_n_-_1
, N_n is a positive integer) (3) An information center used in the software supply system according to claim 1 or 2, comprising: an information file section storing a plurality of information software; and a request signal being supplied. a request reception unit that searches whether or not information software corresponding to the request signal is stored in the information file; a request counting unit that calculates the frequency of requests for each type of information software; and a request counting unit that monitors the amount of information software stored in the information file unit, and before the amount of accumulated information overflows, calculates the frequency of requests calculated by the request counting unit. An information center of a software supply system, comprising: an erasure control section that sequentially erases information software from the information file section.