JP7059569B2 - Server control methods, servers, and server control programs - Google Patents

Description

The present invention relates to a server control method, a server, and a server control program that can be connected to a storage unit and a user terminal.

There is known an information providing system in which a server holds the vacancy status of a plurality of stores and provides the user with information on the stores currently vacant in response to a search request from the user.

For example, Patent Document 1 describes that a search is performed based on vacant information input at a store, and a reservation is made at a store having vacancy.

Further, Patent Document 2 describes that when a search is performed based on the vacant information registered by the store terminal, a store in which the degree of the number of users exceeds the vacant number is less than or equal to the reference value is treated as available.

International Publication No. 01/063474 Japanese Unexamined Patent Publication No. 2014-071703

In the information provision system, when the vacant information of the store is determined based on the notification from the store side, and if it is predicted that there will be vacant seats after a predetermined time even if there are no vacant seats at the present time, You may be notified that it is free.

However, in that case, contrary to the prediction, the store may not be vacant, and a user who visits the store according to the vacancy information may not be able to enter the store. That is, the operator of the information providing system cannot appropriately guide the user to a vacant store.

The first control method of the server according to the present invention is
A method of controlling a server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating whether or not the store is vacant is stored for each of the plurality of stores.
The server
Receives a vacancy notification signal that includes store identification information that identifies each store and notifies that each store is vacant.
Upon receiving the availability notification signal, the status information of the store specified by the store identification information is set to the availability status for a predetermined time.
When a search request is received from a user terminal, the store whose status information is set to be vacant is extracted and transmitted to the user terminal.
In the above setting, the status information is set to the vacant state for a predetermined time only when the number of times the availability notification signal including the store identification information specifying each store is received does not exceed the upper limit number within a certain period. ,
It is characterized by that.

The second control method of the server according to the present invention is
A method of controlling a server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating whether or not the store is vacant is stored for each of the plurality of stores.
The server
Receives a vacancy notification signal that includes store identification information that identifies each store and notifies that each store is vacant.
Upon receiving the availability notification signal, the status information of the store specified by the store identification information is set to the availability status for a predetermined time.
When a search request is received from a user terminal, the store whose status information is set to be vacant is extracted and transmitted to the user terminal.
In the above setting, the state information is set to the vacant state for a predetermined time only when the total time set to the vacant state of the state information of each store does not exceed the upper limit time within a certain period.
It is characterized by that.

According to the control method of the present invention, the information providing system can be controlled so as to appropriately guide the user to a vacant store.

It is a schematic diagram which shows the outline of the information providing system including the server which concerns on 1st Embodiment of this invention. It is a schematic diagram which shows the hardware configuration of a server. It is a schematic diagram which shows the hardware configuration of a user terminal. It is a functional block diagram of a server. It is a figure which shows the example of the store state table stored in the storage part. It is a figure which shows the example of setting of the state information based on the availability notification. It is a figure which shows the example which the setting of the state information based on the availability notification is different. It is a figure which shows the example which the setting of the state information based on the availability notification is different. It is a figure which shows the example of the setting of the state information based on the availability notification and the cancellation notification. It is a schematic diagram which shows the example of the search request screen displayed on the user terminal. It is a schematic diagram which shows the example of the search result screen displayed on the user terminal. It is a figure explaining the example of the search request and the availability setting based on the geographical range. It is a figure explaining the example of the availability setting based on the availability notification signal and the cancellation notification signal in the store corresponding to a specific geographical range. It is a figure explaining the example of the ranking in the store list. It is a schematic diagram which shows the outline of the information providing system including the server which concerns on 2nd Embodiment of this invention. It is a schematic diagram which shows the hardware configuration of a server. It is a figure which shows the example of the store state table stored in the storage part which concerns on the 2nd Embodiment of this invention. It is a figure which shows the example of setting of the state information based on the vacancy state notification which concerns on the 2nd Embodiment of this invention. It is a figure which shows the example which different setting of the state information based on the vacancy state notification which concerns on the 2nd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, it should be understood that the technical scope of the invention is not limited to those embodiments.

First, the information providing system including the server according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 14. FIG. 1 is a schematic diagram showing an outline of an information providing system including a server according to the first embodiment of the present invention. In the information providing system 1, the server 2 is connected to the storage unit 3 and is connected to the user terminal 4 via the network 5. Further, the server 2 is connected to the switches 7 and 7'installed in the stores 6 and 6'via the network 5.

When the switch 7 of the store 6 (store A) and the switch 7'of the store 6'(store B) are operated, a notification signal notifying that the store is vacant is transmitted to the server 2. In the information providing system including the server according to the first embodiment of the present invention, the server 2 has a remaining number of times of 2 based on the number of notification signals received by the server 2 in a free state within a certain period of time. The store 6 (store A) is set to the vacant state, and the store 6'(store B) having 0 remaining times is not set to the vacant state.

The user terminal 4 requests the server 2 to search for a vacant store with the content shown on the search request screen 410, and displays the search result screen 420 based on the response of the server 2. The search result screen 420 includes the store 6 (store A) set in the vacant state, and does not include the store 6'(store B) not set in the vacant state. The configurations of the server 2 and the user terminal 4 will be described later with reference to FIGS. 2 and 3. The search request screen 410 and the search result screen 420 will be described later with reference to FIGS. 10 and 11 .

The storage unit 3 is a device capable of reading the written data. The storage unit 3 is composed of a non-volatile storage device such as a hard disk drive or a flash memory. The storage unit 3 may include a storage unit control means for controlling the non-volatile storage device in addition to the non-volatile storage device. The storage unit control means can be configured by executing a predetermined program on the processor, for example, in a computer provided with a processor, a memory, an input / output interface, a communication interface, and the like. Further, the storage unit 3 may be integrally configured with the server 2.

In the embodiment of the present invention, the storage unit 3 stores a store status table in which each store and status information indicating whether or not the store is vacant are associated with each of the plurality of stores. The store status table will be described later with reference to FIG.

The network 5 connects the server 2 and the user terminal 4 so as to be communicable. The network 5 is, for example, the Internet on which TCP / IP communication is performed, and devices communicating by the network 5 are connected by wire or wirelessly. The wireless connection may be, for example, a wireless LAN connection such as IEEE802.11ac, or a wireless WAN connection such as a 4G line.

The store 6 is a facility that can accept visiting customers until the capacity is reached and provide services, and may be, for example, a restaurant that provides food and drink services. The store 6 may include a store terminal (not shown) that is connected to the network 5 and can communicate with the server 2.

When the switch 7 is operated, a notification signal including store identification information that identifies each store 6 and notifying the state of the store 6 is transmitted to the server 2. The switch 7 is a device that outputs a predetermined signal according to the operation of the user. The switch 7 may be a device including an input unit for identifying the user's operation and a connection unit that can be directly connected to the network 5. Further, the connection unit may be a device connection interface such as USB (registered trademark) that connects to a store terminal such as a personal computer installed in the store. Further, the switch 7 causes an information processing device such as a personal computer or a smartphone connected to the network 5 to receive a predetermined signal in response to an input such as a predetermined operation on a GUI component displayed on the screen by executing a predetermined software. It can also be configured by operating to output. The operation for the switch 7 may be any operation as long as the input unit included in the switch 7 can be identified, such as pressing a push button switch, tapping a predetermined area of the touch panel, and gesturing a camera. The notification signal may be transmitted from the switch 7 connected to the network 5, or may be transmitted from the store terminal to which the switch 7 is connected.

The store identification information of each store included in the notification signal may be a store identifier unique to each store 6. Further, the store identification information may be a switch identifier unique to each switch 7. For example, the store identifier can be specified based on the switch identifier by referring to the switch store table that stores the switch identifier and the store identifier in association with each other, which is stored in the storage unit 3. In this way, by operating the switch 7, the notification signal applied to each store is transmitted.

When the switch 7 is operated, a notification signal (hereinafter, also referred to as “vacancy notification signal”) notifying that the store 6 is vacant is transmitted. Further, when the switch 7 is operated, a notification signal for canceling the availability notification signal (hereinafter, referred to as “cancellation notification signal”) may be transmitted. It is preferable that the operation of the switch 7 for transmitting the cancellation notification signal is different from the operation of the switch 7 for transmitting the availability notification signal. Specifically, when the operation of the switch 7 for transmitting the notification signal is the pressing of the push button switch, the cancellation notification signal is output according to the operation such as simultaneous pressing with the mode switching button, long pressing, and double clicking. It may be sent.

Further, a switch for transmitting a cancellation notification signal may be provided separately from the switch 7 for transmitting the availability notification signal. Further, when the switch 7 is configured by executing the predetermined software on the information processing apparatus, the cancellation notification signal is transmitted when a GUI component different from the GUI component for transmitting the free status notification signal is operated. May be. When a switch for transmitting a cancellation notification signal is provided, it is possible to identify the free status notification signal and the cancellation notification signal by having different status information (for example, one is true and the other is false). can. Further, when a switch for notifying the cancellation notification signal is provided separately from the switch 7 for notifying the availability notification signal, it is identified whether the notification signal is the availability information notification signal or the cancellation notification signal based on the switch identifier. May be good.

FIG. 2 is a schematic diagram showing the hardware configuration of the server 2. Referring to FIG. 2, the server 2 includes a processor 21, a main memory 22, a storage 23, and a communication interface 24. The server 2 expands the program stored in the storage 23 into the main memory 22 and executes it by the processor 21 to control the communication interface 24 to execute various processes.

The processor 21 is composed of, for example, a CPU. The main memory 22 is composed of a volatile storage device such as a DRAM. The storage 23 is composed of a non-volatile storage device such as a hard disk drive or a flash memory. The communication interface 24 is, for example, a USB interface or a LAN interface, and provides a connection with an external device.

FIG. 3 is a schematic diagram showing the hardware configuration of the user terminal 4. Referring to FIG. 3, the user terminal 4 includes a processor 41, a main memory 42, a storage 43, a communication interface 44, an input interface 45, and a display 46. The user terminal 4 expands the program stored in the storage 43 into the main memory 42, executes the processor 41, executes various processes by controlling the communication interface 44 and the input interface 45, and displays the process results on the display 46. Display on.

The processor 41 is composed of, for example, a CPU. The main memory 42 is composed of a volatile storage device such as a DRAM. The storage 43 is composed of a non-volatile storage device such as a hard disk drive or a flash memory. The communication interface 44 is, for example, a LAN interface or a WAN interface, and provides a connection with an external device. The input interface 45 is, for example, a touch panel arranged so as to be superimposed on the display 46, and accepts a user's operation. The display 46 is, for example, a liquid crystal display panel, and the processing result of the processor 41 is visually displayed by the user.

Specifically, the user terminal 4 can be configured by a personal computer, a smartphone, a tablet terminal, or the like, but the user terminal 4 is not limited thereto. For example, the chip embedded in the user's body can be operated as a user terminal by interacting with the user's body.

Next, the function of the server 2 will be described with reference to FIG. FIG. 4 is a functional block diagram of the server 2. Referring to FIG. 4, the server 2 includes a notification receiving unit 201, a state setting unit 202, a search receiving unit 203, and an extraction transmitting unit 204 as functional blocks.

The notification receiving unit 201 receives a vacancy status notification signal that includes store identification information that identifies each store and notifies that each store is vacant. The notification receiving unit 201 can be configured by operating the processor 21 by executing a predetermined program and controlling the communication interface 24.

Upon receiving the availability notification signal, the status setting unit 202 sets the status information of the store specified by the store identification information to the availability status for a predetermined time.

Further, the state setting unit 202 sets the state information to a vacant state for a predetermined time only when the number of times the notification signal to each store is received does not exceed the upper limit number within a certain period. In other words, if the number of times the notification signal for each store is received within a certain period exceeds the upper limit, the status information of that store is set to the empty state even if the notification signal for that store is received within that certain period. Not done.

By operating the status setting unit 202 in this way, the number of times to notify the availability is limited for each store.

The state setting unit 202 can be configured by operating the processor 21 by executing a predetermined program and controlling the communication interface 24.

The search receiving unit 203 receives a search request from the user terminal 4. The search receiving unit 203 can be configured by operating the processor 21 by executing a predetermined program and controlling the communication interface 24.

The extraction transmission unit 204 extracts a store whose status information is set to be vacant and transmits it to the user terminal 4. The extraction transmission unit 204 can be configured by operating the processor 21 by executing a predetermined program and controlling the communication interface 24.

By adopting the above-mentioned hardware configuration, state information from a plurality of stores can be centrally collected on the server 2, and efficient information processing becomes possible.

Next, the store status table stored in the storage unit 3 will be described with reference to FIG. FIG. 5 is a diagram showing an example of a store status table stored in the storage unit 3. As shown in FIG. 5, in the store status table, the identifier of each store and the status information indicating whether or not the store is vacant are associated with each of the plurality of stores.

Specifically, in FIG. 5, for store A, the identifier "1111" is associated with the status information "vacant status", for store B, the identifier "2222" and the status information "" are associated, and for store C. , The identifier "3333" and the state information "free state" are associated with each other.

The identifier is information for uniquely identifying the store to which the status information is notified by the notification signal. The identifier included in the received notification signal allows the server 2 to identify which store status information the notification signal notifies.

The status information is information indicating whether or not the store is vacant. In the example of FIG. 5, the character string "vacant state" is stored in the state information of the store that is in the vacant state, and the state information of the store that is not in the vacant state is blank. However, the information stored in the status information is not limited to this, for example, a logical value of "true" is stored in the status information of a store that is vacant, and a "false" logical value is stored in the status information of a store that is not vacant. It suffices if it is possible to distinguish between a store that is in a state and a store that is not in a vacant state. In the present specification, setting the state information of a certain store to a state indicating that it is in a vacant state is referred to as "setting to a vacant state". The setting of the free state will be described in detail separately with reference to FIGS. 6-8.

Further, in the store status table, as shown in FIG. 5, the location “region P” and the free time “30 minutes” and the remaining number of times “2” are for store A, and the location “region P” and vacant for store B. The time "" and the remaining number of times "0" may be associated with the location "region P", the free time "15 minutes", and the remaining number of times "1" for the store C.

The location is information indicating the location of the store. As illustrated in FIG. 5, the geographical range including the location of the store may be specified, or the location information may specify the location of the store by latitude, longitude, or the like.

The free time is information indicating the time until the store currently set to the free state is no longer free. As illustrated in FIG. 5, the time until the free time disappears may be stored as the free time, and the time when the free information disappears (for example, "20:30") may be stored as the free time.

Further, although the free time of a store that is not a vacant store is blank in the example of FIG. 5, the free time (for example, "19:00") at the time of the previous vacant state may be stored.

The remaining number of times is the remaining number of times that the state information of each store can be set to an empty state. The remaining number of times is within a certain period (for example, 12 hours) separately stored from the upper limit value (for example, 3 times) indicating the upper limit of the number of times that the state information is set to the vacant state when the notification signal for each store is received. It can be obtained by reducing the number of times the notification signal is received for the store in. In the example of FIG. 5, the difference obtained by subtracting the number of times the notification signal is received from the upper limit is stored as the remaining number of times, but the number of times the notification signal is received within a certain period is stored as the remaining number of times, and if necessary. It may be reduced from the upper limit.

FIG. 6 is a diagram showing an example of setting status information based on the availability notification. FIG. 6A shows a state in which the server 2 has received the notification signal for the store A. The server 2 has not received the notification signal for the store A within a certain period (for example, 12 hours) up to the present. Since the number of times the notification signal is received does not exceed the upper limit number (for example, 3), the server 2 sets the state information of the store A to a vacant state for a predetermined time (for example, 30 minutes) and decrements the remaining number of times of the store A by 1. ..

FIG. 6B shows a state in which the server 2 receives the notification signal applied to the store B. The server 2 has received the notification signal for the store B three times within a certain period up to the present. Since the fourth reception this time exceeds the upper limit number 3 in this example, the server 2 does not set the state information of the store A to the empty state.

FIG. 7 is a diagram showing different examples of setting the status information based on the availability notification, and the server 2 sets the status information of each store to the free status according to the remaining number of times that the status information can be set to the free status. Change the time.

FIG. 7A shows a state in which the server 2 has received the notification signal for the store A. Since the server 2 has not received the notification signal for the store A within a certain period up to the present and does not exceed the upper limit number 3 in this example, the state information of the store A is set to the vacant state for a predetermined time. .. By receiving the notification signal this time, the remaining number of times that can be set in the free state is reduced by 1 from 3 to 2.

FIG. 7B shows a state in which the server 2 receives the notification signal applied to the store B. The server 2 has received the notification signal for the store B twice within a certain period up to the present, and since the upper limit is 3 in this example, the remaining number of times is 1. Since the third reception this time does not exceed the upper limit number 3 in this example, the server 2 sets the state information of the store B to an empty state. By receiving the notification signal this time, the remaining number of times that can be set in the free state is reduced by 1 from 1 to 0.

In the example of FIG. 7, the remaining number of times that can be set in the vacant state of the store A is 2, and the remaining number of times of the store B is 0. The server 2 may change the predetermined time to be set in the free state according to the remaining number of times. In the example of FIG. 7, the store A having 2 remaining times is set to be vacant for 30 minutes, and the store B having 0 remaining times is set to be vacant for 45 minutes. The change of the predetermined time according to the remaining number of times is not limited to this, and for example, the store A having 2 remaining times may be set to be vacant for 45 minutes, and the store B having 0 remaining times may be set to be vacant for 30 minutes. ..

FIG. 8 is a diagram showing different examples of setting the status information based on the free status notification, and the server 2 changes the predetermined time to be set in the free status according to the time zone in which the notification signal is received.

FIG. 8 shows a state in which the server 2 receives the availability notification signal for the store A. The server 2 receives the notification signal for the store A at 18:00 and 20:00. In this example, when the notification signal is received in the time zone from 17:00 to 19:00, the store is set to be vacant for 45 minutes, and 45 for the notification signal received at 18:00. It is set to a free state for 30 minutes, and is set to a free state for 30 minutes for the notification signal received at 20:00. In this way, the server 2 sets the predetermined time for setting the free state for the notification signal received in the predetermined time zone to be free, rather than the predetermined time for setting the free state for the notification signal received in the other time zone. Make it longer or shorter.

FIG. 9 is a diagram showing an example of setting status information based on the availability notification and the cancellation notification.

FIG. 9A shows a state in which the server 2 receives the availability notification signal for the store A after receiving the availability notification signal and the cancellation notification signal for the store A. At this time, the server 2 changes the predetermined time to be set to the free state based on the later received free status notification signal from the predetermined time to be set to the free state based on the free status notification signal before the cancel notification signal. In the example of FIG. 9A, the server 2 sets the time for the server 2 to set the free status based on the free status notification signal received later to the free status based on the free status notification signal before the cancellation notification signal. It is set to 15 minutes, which is shorter than 30 minutes, which is the time to do.

FIG. 9B shows a state in which the server 2 receives the availability notification signal for the store A after receiving the availability notification signal and the cancellation notification signal for the store A a plurality of times. At this time, the server 2 sets the average time from receiving the availability notification signal to receiving the cancellation notification signal for canceling the availability set based on the availability notification signal to the predetermined time required for the store A. Set.

Specifically, in the example of FIG. 9B, the time from the reception of the first availability notification signal to the reception of the first cancellation notification signal for canceling the signal is t1. Further, the time from the reception of the second availability notification signal to the reception of the second cancellation notification signal for canceling the signal is t2. The server 2 sets the average of these times (t1 + t2) / 2 to the predetermined time required for the store A. When setting the vacant state based on the vacant state notification signal received last, the state information of the store A is set to the vacant state during (t1 + t2) / 2.

By doing so, it is possible to control the state information according to the rotation status of the seats in each store. If the vacant state is set and the occupancy is full, the customer who comes to the store after seeing the search result that the vacant state is set will be kept waiting, which is not preferable. By controlling the status information according to the rotation status of the seats in each store in this way, the appropriate length based on the past performance of each store can be obtained without the need for the store to manually notify the cancellation while grasping the status inside the store. The free state will end with.

FIG. 10 is a schematic diagram showing an example of a search request screen displayed on the user terminal 4. Referring to FIG. 10, the user terminal 4 displays a search request screen 410 including a search request instruction button 411.

When the user operates the search request instruction button 411, the user terminal 4 transmits a search request based on the selected search conditions to the server 2.

In the present specification, the "button" includes the GUI in general. The search request instruction button 411 does not have to be a physical button, nor does it need to have an appearance corresponding to the pressing of the physical button in the selected state.

Therefore, the search request instruction button 411 can be configured by the GUI, and can be operated by tapping or the like on a predetermined area of the touch panel superimposed on the display 46.

FIG. 11 is a schematic diagram showing an example of the search result screen 420 displayed on the user terminal 4. Referring to FIG. 11 , the user terminal 4 displays a search result screen 420 including a store list 421 that displays a list of the extracted stores. The store list 421 includes information 422 of each store.

It is preferable that the store information 422 includes information that can be used as a reference for determining a store to be visited by the user from the stores displayed in the store list 421. In the example of FIG. 11, the link to the store map and the characteristics of the store are displayed as the store information 422, but the present invention is not limited to this.

FIG. 12 is a diagram illustrating an example of a search request and availability setting based on a geographical range. Referring to FIG. 12, the user terminal 4 transmits a search request specifying the area P as the geographical range. The server 2 extracts the store B corresponding to the area P from the stores B, F, and G whose status information is set to be vacant, and transmits the search result to the user terminal 4.

It suffices if the geographical range specified in the search request is associated with the location associated with each store in the store status table. In the example of the store status table shown in FIG. 5 and the search request shown in FIG. 12, they are associated with each other by matching the area name "region P". In addition, for the store table to which the location information that identifies the location of the store by latitude and longitude is associated as the location of the store, the geographical range is set to latitude, for example, "within 200 m from the current position of the user terminal 4". And may be specified by longitude or the like. Further, the user terminal 4 can specify the geographical range by the area name in the search request, and the server 2 can convert the designated area name into the range specification by latitude and longitude using a predetermined database. ..

The server 2 may transmit the state information of another store at a location where the distance from the location of one store is within a predetermined distance to the one store. In the example of FIG. 12, the server 2 transmits the state information of other stores B, C, and D in the same area P to the store A. The person in charge at the store can refer to the status information of the neighboring stores transmitted in this way and decide when to notify the availability of the store.

When the server 2 receives the notification signal including the identifier of the store corresponding to the specific geographical range, the server 2 may change the predetermined time for setting the store corresponding to the specific geographical range to the vacant state. In the example of FIG. 12, when the notification signal including the identifier of the store A corresponding to the area P corresponding to the specific geographical range is received, the predetermined time set to the vacant state is changed from 30 minutes, and the store A is vacant for 45 minutes. Set to. On the other hand, when the notification signal including the identifier of the store E that does not correspond to the specific geographical range is received, the store E is set to the vacant state for 30 minutes without changing the predetermined time. The change of the predetermined time is not limited to this example, and the predetermined time may be shortened for the store corresponding to a specific geographical range.

FIG. 13 is a diagram illustrating an example of availability setting based on a availability notification signal and a cancellation notification signal in a store corresponding to a specific geographical range. Referring to FIG. 13, the store A, the store B, the store C and the store D correspond to a specific geographical range, for example, in the area P. The server 2 has received a cancellation notification signal from a predetermined number or more of stores corresponding to a specific geographical range, notifying a request to cancel the setting of making the status information of the store that has received the availability notification signal available. In this case, the average time from receiving the availability notification signal to receiving the cancellation notification signal in each store is set as a predetermined time required for the store corresponding to a specific geographical range.

Specifically, the server 2 receives the availability notification signal for the store A, and receives the cancellation notification signal after the time ta. Similarly, for the store B and the store C, the times from the reception of the availability notification signal to the reception of the cancellation notification signal are tb and tc, respectively. That is, the availability notification signal and the corresponding cancellation notification signal are received from the three stores A, B, and C corresponding to the area P. Here, assuming that the predetermined number is 3, since the reception is performed from the predetermined number or more stores, the average time from the reception of the availability notification signal at each store to the reception of the cancellation notification signal, that is, (ta + tb + tk). / 3 is set as the predetermined time required for the store corresponding to the area P. Therefore, the time set as the vacant state based on the vacant state notification signal applied to the store D is (ta + tb + tc) / 3.

By doing so, it is possible to set the time for leaving the vacant state by reflecting the congestion situation (for example, after the event is over) due to the circumstances peculiar to the area.

When a plurality of stores whose status information is set to be vacant are extracted on the server 2, it is preferable to send a list of stores in which a plurality of stores are ranked according to a predetermined standard to the user terminal 4. FIG. 14 is a diagram illustrating an example of ranking in the store list.

FIG. 14A shows an example of ranking when a plurality of stores having different free time are extracted as search results. The store A is set to be vacant for 30 minutes based on the notification signal 5 minutes ago, and the vacant time is 25 minutes when the search request is received from the user terminal 4. The store B is set to be vacant for 30 minutes based on the notification signal 15 minutes before, and the vacant time is 15 minutes when the search request is received from the user terminal 4. In the example of FIG. 14A, since the store A and the store B are set to be vacant when the search request is received, they are extracted in response to the search request.

The server 2 may determine the order in which the extracted plurality of stores are displayed in the store list according to the free time indicating the time until the status information set in the free state disappears. In the example of FIG. 14A, the extracted free time of the store A and the store B is 25 minutes and 15 minutes, respectively. According to the free time, in the example of FIG. 14A, the store B having the shorter free time is ranked higher and the store A having the longer free time is ranked lower in the order displayed in the store list. The determination of the order according to the remaining time is not limited to this, and for example, a store having a longer free time may be determined to be displayed at the top.

FIG. 14B shows an example of setting and ranking the availability of stores having different times of receiving notification signals in a predetermined period. The notification signal of the store A is received once in a predetermined period. The notification signal of the store B is received three times in a predetermined period.

The more times the server 2 receives the notification signal of a specific store in a predetermined period, the shorter the predetermined time for setting the specific store to the vacant state is shortened, and the specific store is displayed in the store list. You may raise the ranking. In the example of FIG. 14B, the time for setting the store B, which receives the notification signal more frequently in a predetermined period, to be vacant is 45 minutes, which is longer than the time for setting the store A, which is less, to be vacant. do. Further, the display order of the store B having a larger number of times the notification signal has been received in a predetermined period is set higher than that of the store A having a smaller number of times.

As described above, when the server 2 executes a predetermined program to control the server 2, the number of times the availability notification is notified is limited for each store. Therefore, the information providing system 1 appropriately keeps the user in the availability state. You can lead to the store.

Next, the information providing system including the server according to the second embodiment of the present invention will be described with reference to FIGS. 15 to 19. FIG. 15 is a schematic diagram showing an outline of an information providing system including a server according to a second embodiment of the present invention. In the description of the second embodiment, the same reference numerals are given to the parts common to the first embodiment, and detailed description thereof will be omitted.

FIG. 15 is a schematic diagram showing an outline of an information providing system including a server according to the first embodiment of the present invention. The information providing system 20 according to the second embodiment and the information providing system according to the first embodiment have the same configuration, and refer to the state information of each store set based on the notification signal related to the store 6. Similarly, the server 21 responds to the vacant store search request from the user terminal 4. However, only when the total of the times when the status information of each store is set to the vacant state does not exceed the upper limit time by the server 21, the state of the store is based on the vacancy notification signal applied to the store 6. It differs from the first embodiment in that it controls to set the information in an empty state. Hereinafter, the configuration and operation related to this difference will be described.

FIG. 16 is a functional block diagram of the server 21 according to the second embodiment. Referring to FIG. 16, the server 21 includes a notification receiving unit 201, a state setting unit 212, a search receiving unit 203, and an extraction transmitting unit 204 as functional blocks. Since the notification receiving unit 201, the search receiving unit 203, and the extraction transmitting unit 204 are the same as the functional blocks provided in the server 2 according to the first embodiment, the description thereof will be omitted.

Upon receiving the notification signal, the state setting unit 212 sets the state information of the store corresponding to the identifier included in the notification signal to the vacant state for a predetermined time.

Further, the state setting unit 212 sets the state information to the vacant state for a predetermined time only when the total of the times when the state information of each store is set to the vacant state does not exceed the upper limit time within a certain period. In other words, if the time set to the vacant state based on the notification signal applied to each store exceeds the upper limit time within a certain period, even if the notification signal is received from that store within that certain period, the state information of that store will be displayed. Not set to free.

By operating the state setting unit 212 in this way, the time set to the vacant state is limited for each store.

Next, with reference to FIG. 17, the store state table stored in the storage unit 3 in the second embodiment of the present invention will be described. FIG. 17 is a diagram showing an example of a store state table stored in the storage unit 3 in the second embodiment of the present invention. As shown in FIG. 17, in the store status table, the identifier of each store and the status information indicating whether or not the store is vacant are associated with each of the plurality of stores.

In the store status table in the second embodiment, instead of the remaining number of times that the status information of each store can be set to the vacant state, the remaining time that can set the status information of each store to the vacant state is associated. , Different from the store status table in the first embodiment.

In the example of FIG. 17, as the remaining time, "90 minutes" is associated with store A, "0 minutes" is associated with store B, and "60 minutes" is associated with store C. The remaining number of times is from the upper limit time (for example, 90 minutes) indicating the upper limit of the total time when the state information is set to the free state according to the notification signal received within a certain period (for example, 12 hours) separately stored. It can be calculated by subtracting the total time set for vacancy for stores within a certain period. In the example of FIG. 17, as the remaining number of times, the difference obtained by subtracting the number of times of receiving the notification signal from the upper limit value is stored, but the total of the time set in the vacant state within a certain period is stored as the remaining number of times, and it is necessary. It may be reduced from the upper limit time accordingly.

FIG. 18 is a diagram showing an example of setting status information based on the availability notification. FIG. 18A shows a state in which the server 2 has received the notification signal for the store A. The server 2 has not received the notification signal for the store A within a certain period (for example, 12 hours) up to the present, and is not set to the vacant state. Since the total of the times set in the vacant state does not exceed the upper limit time (for example, 90 minutes), the server 2 sets the state information of the store A in the vacant state for a predetermined time (for example, 30 minutes).

FIG. 18B shows a state in which the server 2 receives the notification signal applied to the store B. The server 2 receives the notification signal applied to the store B three times within a certain period up to the present, and sets each to a free state for 30 minutes. Since the total time set in the vacant state exceeds 90 minutes, which is the upper limit time in this example, and the remaining time is 0, the server 2 does not set the state information of the store A in the vacant state.

FIG. 19 is a diagram showing a different example of setting the status information based on the availability notification according to the second embodiment of the present invention, and the server 21 has a remaining time during which the status information of each store can be set to the availability. Depending on the situation, change the predetermined time to be set in the free state.

FIG. 19 shows a state in which the server 2 receives the notification signal applied to the store A. The server 2 has received the notification signal for the store A three times within a certain period up to the present. At the time of receiving the first notification signal, the remaining time is 90 minutes, which is the upper limit time. The store is set to be vacant for 30 minutes based on the first notification signal. At the time of receiving the second notification signal, the remaining time is 60 minutes, which is obtained by subtracting 30 minutes from the upper limit time. The store is set to be vacant for 30 minutes based on the second notification signal.

At the time of receiving the third notification signal, the remaining time is 30 minutes, which is obtained by subtracting 30 minutes from the previous remaining time. In this example, when the remaining time is 30 minutes or less, the predetermined time required for the store is changed, and the store A is set to be vacant for 15 minutes. The change of the predetermined time for setting each store in the vacant state is not limited to this according to the remaining time in which each store can be set in the vacant state.

Further, the control based on the store location, the control based on the cancellation notification signal, and the control for determining the display order in the store list described in the first embodiment can be similarly applied in the second embodiment.

As described above, when the server 21 executes a predetermined program to control the server 21, the time that can be set in the vacant state is limited for each store. Therefore, the information providing system 20 appropriately vacates the user. Can be guided to the store.

In the present specification, as an embodiment of the present invention that solves the problem of appropriately guiding a user to a vacant store, the first embodiment in which the number of times of notifying the vacant state is limited for each store and the vacant state are set. The second embodiment that limits the possible time for each store has been described. However, the present invention is not limited to this embodiment.

1, 20 Information provision system 2, 21 Server 3 Storage unit 4 User terminal 5 Network 6, 6'Store 7, 7'Switch 410 Search request screen 411 Search request instruction button 420 Search result screen 421 Store list 422 Store information

Claims (15)

A method of controlling a server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
The server
Receives a availability notification signal that includes store identification information that identifies each store and notifies the availability of each store.
Set the status information associated with the store where the availability notification signal was received,
When a search request for a vacant store is received from the user terminal, the store for which the state information is set is extracted within a predetermined time and transmitted to the user terminal.
In the above setting, the status information is set only when the number of times the availability notification signal including the store identification information that identifies each store is received does not exceed the upper limit number within a certain period.
A server control method characterized by that. The control method according to claim 1, wherein in the above setting, the predetermined time required for the store is changed according to the remaining number of times that the state information of each store can be set. A method of controlling a server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
The server
Receives a availability notification signal that includes store identification information that identifies each store and notifies the availability of each store.
Set the status information associated with the store where the availability notification signal was received,
When a search request for a vacant store is received from the user terminal, the store for which the state information is set is extracted within a predetermined time and transmitted to the user terminal.
In the above setting, the state information is set only when the total time for which the state information of each store is set does not exceed the upper limit time within a certain period.
A server control method characterized by that. The control method according to claim 3, wherein in the above setting, the predetermined time required for the store is changed according to the remaining time in which the state information of each store can be set. In the above setting, when the availability notification signal is received for the store corresponding to the specific geographical range, when the availability notification signal for the store corresponding to the specific geographical range is equal to or more than a predetermined number, or. When the time when the availability notification signal is received is included in the predetermined time zone set in the specific geographical range, the predetermined time for the store corresponding to the availability notification signal is changed. The control method according to any one of 1 to 4. Further, based on the store status table, other stores associated with the location where the distance from the location of one store is within a predetermined distance are extracted, and the status information of the other stores is used as the status information of the one store. The control method according to claim 5, which is transmitted to. In the above setting, when a cancellation notification signal for notifying a request to cancel the setting of the status information of the store that has received the availability notification signal is received from a predetermined number or more stores corresponding to the specific geographical range. 5. The average time from receiving the availability notification signal to receiving the cancellation notification signal in each store is set as the predetermined time for the store corresponding to the specific geographical range. Or the control method according to 6. In the transmission, the list information for displaying the store list displaying the extracted plurality of the stores is transmitted to the user terminal, and the list information is transmitted to the user terminal.
One of claims 1 to 7, which determines the order in which the extracted plurality of stores are displayed in the store list according to the free time indicating the time until the set state information is changed. The control method according to one item. In the transmission, the more times the availability notification signal of the specific store is received in the predetermined period, the shorter the predetermined time required for the specific store, and the specific store in the store list The control method according to claim 8, wherein the displayed order is increased. In the above setting, when the vacancy notification signal is received from the store after receiving the cancellation notification signal for notifying the request to cancel the setting of the status information of the store that has received the vacancy notification signal, the store receives the vacancy notification signal. The control method according to any one of claims 1 to 9, wherein the predetermined time is changed. In the above setting, when the vacancy status notification signal related to the store and the cancellation notification signal for canceling the setting of the status information based on the vacancy status notification signal are received a plurality of times, the vacancy status notification signal is received. The control method according to claim 10, wherein the average time from the time until the cancellation notification signal for canceling the vacant state set based on the vacancy notification signal is received is set to the predetermined time for the store. A server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
A notification receiving unit that includes store identification information that identifies each store and receives a vacancy notification signal that notifies the vacancy status of each store.
A status setting unit that sets the status information associated with the store for which the availability notification signal is received, and a status setting unit.
A search receiver that receives search requests for vacant stores from user terminals, and
It is provided with an extraction transmission unit that extracts a store in which the state information is set within a predetermined time and transmits it to the user terminal.
The state setting unit sets the state information only when the number of times the vacant state notification signal including the store identification information specifying each store is received does not exceed the upper limit number within a certain period.
A server that features that. A server that can be connected to a storage unit and a user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
A notification receiving unit that includes store identification information that identifies each store and receives a vacancy notification signal that notifies the vacancy status of each store.
A status setting unit that sets the status information associated with the store for which the availability notification signal is received, and a status setting unit.
A search receiver that receives search requests for vacant stores from user terminals, and
It is provided with an extraction transmission unit that extracts a store in which the state information is set within a predetermined time and transmits it to the user terminal.
The state setting unit sets the state information only when the total time for which the state information of each store is set does not exceed the upper limit time within a certain period.
A server that features that. A server control program that can connect to the storage unit and user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
To the server
Receives a availability notification signal that includes store identification information that identifies each store and notifies the availability of each store.
Set the status information associated with the store where the availability notification signal was received,
Receive a search request for a vacant store from the user terminal,
The store in which the state information is set is extracted within a predetermined time, and the store is executed to be transmitted to the user terminal.
In the above setting, the status information is set only when the number of times the availability notification signal including the store identification information that identifies each store is received does not exceed the upper limit number within a certain period.
A control program characterized by that. A server control program that can connect to the storage unit and user terminal.
In the storage unit, a store status table in which each store is associated with status information indicating the availability of the store is stored for each of the plurality of stores.
To the server
Receives a availability notification signal that includes store identification information that identifies each store and notifies the availability of each store.
Set the status information associated with the store where the availability notification signal was received,
Receive a search request for a vacant store from the user terminal,
The store in which the state information is set is extracted within a predetermined time, and the store is executed to be transmitted to the user terminal.
In the above setting, the state information is set only when the total time for which the state information of each store is set does not exceed the upper limit time within a certain period.
A control program characterized by that.

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