JP6036258B2 - Information processing apparatus and information processing program - Google Patents

Description

  The present invention relates to an information processing apparatus and an information processing program.

  In Patent Document 1, it is an object to provide a proxy-based transaction authentication system, and a vehicle having a response object has a proxy, and this proxy is received from a GPS satellite or other current position determination source. The proxy has a better function than the response object that can receive the current position determination signal, and the proxy receives the inquiry signal from the inquiry device and represents the position of the response object. The vehicle has an excellent function, and the vehicle is equipped with (i) one or more sensors for detecting a response object mounted on the vehicle and (ii) one or more sensors for detecting vehicle state information. Both sets of sensors provide information to the proxy, and the response object sensor is in the same way that the interrogator queries the location of these response objects. You can query each response object, and the state of the vehicle, the position of the vehicle and the and the weight moving direction thereof, the vehicle inner and outer temperature, humidity, may include a pressure is disclosed.

  Patent Document 2 discloses, with a simple configuration, a sound collection unit that acquires sound, an absolute position detection unit that detects an absolute position of the mobile terminal, a relative position detection unit that detects a relative position of the mobile terminal, An object of the present invention is to realize a portable terminal provided with voice recognition means for recognizing sound acquired by the sound collecting means as voice, the portable terminal executing data transmission / reception with a server, In the terminal, the sound collecting means for acquiring sound, the absolute position detecting means for detecting the absolute position of the portable terminal, the relative position detecting means for detecting the relative position of the portable terminal, and the sound collecting means It is disclosed that a voice recognition unit that recognizes a sound as a voice is provided.

JP 2010-088095 A JP 2010-183289 A

  An object of the present invention is to provide an information processing apparatus and an information processing program for outputting a floor in a building when outputting the location of a portable information processing apparatus.

The gist of the present invention for achieving the object lies in the inventions of the following items.
According to the first aspect of the present invention, the air pressure and the air temperature detected by the other detection device, the reception means for receiving the altitude of the other detection device, and the atmospheric pressure at the position where the portable information processing device exists are detected. Detection means, calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, temperature, altitude received by the reception means, and atmospheric pressure detected by the atmospheric pressure detection means, a floor, and the floor specifying means for specifying a floor corresponding to the height of the floor from the storage means for storing in association with the altitude calculated by the calculation means, and having an output means for outputting a floor specified by the specifying means The other detection device is a plurality of portable information processing devices, and determines an altitude of the information processing device based on a behavior type of a person who possesses the information processing device, and the receiving unit Is A plurality of atmospheric pressures, temperatures, and altitudes are received, and the calculation means is detected by the atmospheric pressure, temperature, altitude, and the atmospheric pressure detection means as statistical representative values of the plurality of atmospheric pressures, temperatures, and altitudes received by the receiving means. Based on the atmospheric pressure, the altitude at the time of detection by the atmospheric pressure detecting means is calculated, and the calculating means performs the information processing when an action of a person who possesses a portable information processing device does not apply to the type. It is an information processing apparatus characterized by not using the pressure, temperature and altitude received from the apparatus.
According to the second aspect of the present invention, the air pressure and the air temperature detected by the other detection device, the reception means for receiving the altitude of the other detection device, and the atmospheric pressure at the position where the portable information processing device exists are detected. Detection means, calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, temperature, altitude received by the reception means, and atmospheric pressure detected by the atmospheric pressure detection means, a floor, and the floor Specifying means for specifying a floor corresponding to the altitude calculated by the calculating means from storage means storing the height of the floor in correspondence; and output means for outputting the floor specified by the specifying means. The other detection device is a plurality of portable information processing devices, and determines the altitude of the information processing device based on the time detected by the schedule of the person carrying the information processing device, The attaching means receives a plurality of pressures, temperatures, and altitudes, and the calculating means receives the pressures, temperatures, altitudes, and the pressure detecting means as statistical representative values of the plurality of pressures, temperatures, and altitudes received by the receiving means. Based on the atmospheric pressure detected by the atmospheric pressure detection means calculates the altitude at the time of detection by the atmospheric pressure detection means, the calculation means, when the action of the person who possesses the portable information processing device does not fall on schedule, The information processing apparatus is characterized in that the atmospheric pressure, temperature, and altitude received from the information processing apparatus are not used.

According to a third aspect of the present invention, the receiving unit receives a time when the other detection device detects the atmospheric pressure and the temperature, and the calculating unit is within a predetermined range from a time when the atmospheric pressure detecting unit detects the atmospheric pressure. 3. The information processing apparatus according to claim 1, wherein the altitude is calculated using the atmospheric pressure and the temperature received by the receiving unit detected at a certain time.

According to the invention of claim 4 , the computer detects the atmospheric pressure and temperature detected by the other detection device, the reception means for receiving the altitude of the other detection device, and the atmospheric pressure at the position where the portable information processing device exists. Pressure detecting means for detecting, calculating means for calculating the altitude at the time point detected by the pressure detecting means based on the pressure, temperature, altitude received by the receiving means and the pressure detected by the pressure detecting means; Specifying means for specifying a floor corresponding to the altitude calculated by the calculating means from storage means for storing the floor and the height of the floor in association with each other; and output means for outputting the floor specified by the specifying means to function as the other sensing device is a portable plurality of information processing apparatuses, based on the type of behavior of the person in possession of the information processing apparatus, elevation of the information processing apparatus The receiving means receives a plurality of atmospheric pressures, temperatures and altitudes, and the calculating means receives the atmospheric pressures, temperatures and altitudes as statistical representative values of the plurality of atmospheric pressures, temperatures and altitudes received by the receiving means. Based on the atmospheric pressure detected by the atmospheric pressure detection means, the altitude at the time of detection by the atmospheric pressure detection means is calculated, and the calculation means does not apply the behavior of the person carrying the portable information processing device to the mold. If not, the information processing program is characterized by not using the pressure, temperature and altitude received from the information processing apparatus .
According to the fifth aspect of the present invention, the computer detects the atmospheric pressure and the temperature detected by the other detection device, the reception means for receiving the altitude of the other detection device, and the atmospheric pressure at the position where the portable information processing device exists. Pressure detecting means for detecting, calculating means for calculating the altitude at the time point detected by the pressure detecting means based on the pressure, temperature, altitude received by the receiving means and the pressure detected by the pressure detecting means; Specifying means for specifying a floor corresponding to the altitude calculated by the calculating means from storage means for storing the floor and the height of the floor in association with each other; and output means for outputting the floor specified by the specifying means The other detection device is a plurality of portable information processing devices, and the information processing device is based on the time detected by the person who owns the information processing device. The reception means receives a plurality of atmospheric pressures, temperatures, and elevations, and the calculation means receives the atmospheric pressure and temperature as a statistical representative value of the plurality of atmospheric pressures, temperatures, and elevations received by the reception means. And the altitude and the atmospheric pressure detected by the atmospheric pressure detecting means, the altitude at the time point detected by the atmospheric pressure detecting means is calculated, and the calculating means determines whether the behavior of the person carrying the portable information processing device is The information processing program is characterized by not using the atmospheric pressure, the temperature, and the altitude received from the information processing apparatus when the schedule does not apply.

According to the first and second information processing apparatuses, when the location of the portable information processing apparatus is output, the floor in the building can be output.

According to the information processing apparatus of the third aspect , the floor in the building can be specified more accurately as compared with the case where the present configuration is not provided.

According to the information processing program of claims 4 and 5 , in the case of outputting the location of the portable information processing apparatus, the floor in the building can be output.

It is a conceptual module block diagram about the structural example of this Embodiment. It is explanatory drawing which shows the system configuration example in the case of implement | achieving this Embodiment. It is explanatory drawing which shows the example of a data structure of a building information table. It is a flowchart which shows the process example by this Embodiment. It is a flowchart which shows the process example by this Embodiment. It is explanatory drawing which shows the example of a data structure of a measurement and specific result table. It is explanatory drawing which shows the process example which calculates the value used as a reference. It is explanatory drawing which shows the process example which calculates the value used as a reference. It is explanatory drawing which shows the process example which calculates the value used as a reference. It is explanatory drawing which shows the process example which calculates the value used as a reference. It is a block diagram which shows the hardware structural example of the computer which implement | achieves this Embodiment.

Hereinafter, an example of a preferred embodiment for realizing the present invention will be described with reference to the drawings.
FIG. 1 shows a conceptual module configuration diagram of a configuration example of the present embodiment.
The module generally refers to components such as software (computer program) and hardware that can be logically separated. Therefore, the module in the present embodiment indicates not only a module in a computer program but also a module in a hardware configuration. Therefore, the present embodiment is a computer program for causing these modules to function (a program for causing a computer to execute each procedure, a program for causing a computer to function as each means, and a function for each computer. This also serves as an explanation of the program and system and method for realizing the above. However, for the sake of explanation, the words “store”, “store”, and equivalents thereof are used. However, when the embodiment is a computer program, these words are stored in a storage device or stored in memory. It is the control to be stored in the device. Modules may correspond to functions one-to-one, but in mounting, one module may be configured by one program, or a plurality of modules may be configured by one program, and conversely, one module May be composed of a plurality of programs. The plurality of modules may be executed by one computer, or one module may be executed by a plurality of computers in a distributed or parallel environment. Note that one module may include other modules. Hereinafter, “connection” is used not only for physical connection but also for logical connection (data exchange, instruction, reference relationship between data, etc.). “Predetermined” means that the process is determined before the target process, and not only before the process according to this embodiment starts but also after the process according to this embodiment starts. In addition, if it is before the target processing, it is used in accordance with the situation / state at that time or with the intention to be decided according to the situation / state up to that point. When there are a plurality of “predetermined values”, they may be different values, or two or more values (of course, including all values) may be the same. In addition, the description having the meaning of “do B when it is A” is used in the meaning of “determine whether or not it is A and do B when it is judged as A”. However, the case where it is not necessary to determine whether or not A is excluded.
In addition, the system or device is configured by connecting a plurality of computers, hardware, devices, and the like by communication means such as a network (including one-to-one correspondence communication connection), etc., and one computer, hardware, device. The case where it implement | achieves by etc. is also included. “Apparatus” and “system” are used as synonymous terms. Of course, the “system” does not include a social “mechanism” (social system) that is an artificial arrangement.
In addition, when performing a plurality of processes in each module or in each module, the target information is read from the storage device for each process, and the processing result is written to the storage device after performing the processing. is there. Therefore, description of reading from the storage device before processing and writing to the storage device after processing may be omitted. Here, the storage device may include a hard disk, a RAM (Random Access Memory), an external storage medium, a storage device via a communication line, a register in a CPU (Central Processing Unit), and the like.

  The portable information processing apparatus 100 according to the present embodiment outputs a position where a portable information processing apparatus exists, and as shown in the example of FIG. 1, the atmospheric pressure detection module 110, the position detection module 120, and the reference The information acquisition module 130, the building information storage module 140, the height specifying module 150, and the output module 160 are included. The information processing apparatus 100 is portable and has a communication function. For example, a mobile phone (including a smartphone), a notebook PC (including a tablet PC) having a communication function, and the like. In addition, the information processing apparatus 100 only needs to include at least the atmospheric pressure detection module 110, and generally includes the position detection module 120. As described later with reference to the example of FIG. Any one or more of the information acquisition module 130, the building information storage module 140, the height specifying module 150, and the output module 160 may be constructed in another information processing apparatus. Note that detecting the position of the information processing apparatus 100 means detecting the position of the person carrying the information processing apparatus 100.

The atmospheric pressure detection module 110 is connected to the height specifying module 150. The atmospheric pressure detection module 110 detects the atmospheric pressure at the position where the portable information processing device 100 exists. It is a so-called barometric pressure sensor.
Note that the atmospheric pressure detection module 110 periodically detects atmospheric pressure.
The position detection module 120 is connected to the height specifying module 150. The position detection module 120 detects the position where the information processing apparatus 100 exists. For example, GPS, a position detection module of a base station (for example, 3G base station and WiFi base station) in a wireless communication network, and the like are applicable. Here, when the position detection module 120 detects the first time point, the processing by the height specifying module 150 may be performed. As the first time point, for example, there is a time point when the position cannot be detected by detecting the position of the GPS or the base station, or a time point when the accuracy of the position detection of the GPS or the base station becomes less than or less than a predetermined value. Specifically, this corresponds to a time point when the owner of the information processing apparatus 100 enters a building such as a building, which corresponds to a so-called out-of-GPS range. That is, the owner of the information processing apparatus 100 is on a floor (hereinafter also referred to as a floor) where the entrance (including the entrance and entrance) of the building is located. Therefore, the first time point is, as a specific example, a time point when entering the floor where the entrance is located in the building.
The GPS and base station position detection module outputs information indicating the accuracy of the detected position in addition to the position (latitude and longitude). Specifically, GPS has a horizontal accuracy degradation index. What is necessary is just to judge whether these values are less than or below a predetermined value as the accuracy of GPS and base station position detection.
Note that the position detection module 120 periodically detects the position.
Further, the position detection module 120 may detect the altitude (altitude above sea level) of the information processing apparatus 100. For example, GPS detects altitude in addition to latitude and longitude.

The reference information acquisition module 130 is connected to the height specifying module 150. The reference information acquisition module 130 receives the atmospheric pressure and temperature detected by other detection devices and the altitude at which the other detection devices are present. The “other detection device” corresponds to, for example, a portable information processing device 250 described later. That is, the “other detection device” is a device other than the portable information processing device 100, has an atmospheric pressure sensor and an air temperature sensor, and is generally located at a place different from the portable information processing device 100. The reference information acquisition module 130 acquires values detected by these sensors. Then, the altitude at the position where the “other detection device” exists is also acquired. The “elevation at a position where another detection device is present” will be described later with reference to FIG.
The reference information acquisition module 130 may receive a time when the “other detection device” detects the atmospheric pressure and the temperature.

The building information storage module 140 is connected to the height specifying module 150. The building information storage module 140 stores at least the correspondence between the floor in the building and the height of the floor, and indicates the name of the building, the position of the building, and the floor where the entrance of the building is located. Information may be stored. The “floor height” may be an altitude or a height in a building (for example, including a height between floors). For example, a building information table 300 is stored. FIG. 3 is an explanatory diagram illustrating a data structure example of the building information table 300. The building information table 300 includes a building ID column 310, a building name column 320, a building position column 330, an entrance column 340, a floor number column 350, a first floor height column 361, a second floor height column 362, and the like. The building ID column 310 stores information (ID: IDentification) that can uniquely identify the building in the present embodiment. The building name column 320 stores the name of the building. The building position column 330 stores the position of the building. The building position column 330 has an X column 332 and a Y column 334. The X column 332 stores latitude. The Y column 334 stores longitude. The entrance column 340 stores the floor on which the entrance of the building is located. When the entrance is on multiple floors, the multiple floors are stored. The floor column 350 stores the total number of floors of the building. The first floor height column 361 stores the height of the first floor in the building. The second floor height column 362 stores the height of the second floor in the building. Hereinafter, the height of each floor is memorized. Therefore, it is possible to calculate a floor having an elevation difference from the floor where the entrance is located.
The building information table 300 in the building information storage module 140 does not need to cover the entire map, and may have data on a place (a building at a predetermined place) to be estimated as “where”.

The height specifying module 150 is connected to the atmospheric pressure detection module 110, the position detection module 120, the reference information acquisition module 130, the building information storage module 140, and the output module 160. The height specifying module 150 calculates the altitude at the time point detected by the atmospheric pressure detection module 110 based on the atmospheric pressure, the temperature, the altitude, and the atmospheric pressure detected by the atmospheric pressure detection module 110 received by the reference information acquisition module 130. Then, the floor corresponding to the altitude calculated from the building information storage module 140 that stores the floor and the height of the floor in association with each other is specified. Of course, the altitude calculated by the height specifying module 150 is an altitude at a position where the portable information processing apparatus 100 in which the atmospheric pressure detecting module 110 is built. Specifically, the altitude obtained by substituting the atmospheric pressure detected by the atmospheric pressure detection module 110 into the equation using a predetermined equation with the atmospheric pressure, the air temperature, and the altitude received by the reference information acquisition module 130 as reference values. Is calculated.
The height identifying module 150 calculates the altitude using the atmospheric pressure and the temperature received by the reference information acquisition module 130 detected at a time within a predetermined range from the time when the atmospheric pressure detection module 110 detects the atmospheric pressure. It may be. For example, you may make it utilize what was detected within 30 seconds after the atmospheric pressure detection module 110 detected. Further, when there are a plurality within the range, the latest one may be used.

The calculation of the altitude performed by the height specifying module 150 will be described in detail. When the pressure detected by the terminal possessed by the user (portable information processing 100) is p _user , the height h _{user at} which the _user is present is expressed by equation (1).
h _user = 153.8 * (t0 + 273.2) * (1- (p _user /p0)^0.1902) (1)
At this time, t0 is the standard temperature and p0 is the standard pressure. p0 and t0 are atmospheric pressure and temperature at 0 m above sea level.
How to calculate standard temperature and standard pressure will be explained. The information (reference) acquired by the reference information acquisition module 130 is used.
The atmospheric pressure, the temperature, and the height above sea level output by the reference information acquisition module 130 (the height above sea level where “another detection device (for example, a portable information processing device 250 described later)” is placed is known. ) As p _ref , t _ref and h _ref respectively.
_{p0 = p ref * (1-0.0065 *} h ref / (t ref + 0.0065 * h ref +273.15)) ^ - 5.257 ... (2)
t0 = t _ref + 0.0065 * h _ref (3)
It becomes.
Here, the person who has the portable information processing apparatus 100 by substituting the expressions (2) and (3) into the expression (1) and substituting the atmospheric pressure p _user detected by the atmospheric pressure detection module 110. The altitude h _user can be calculated.

The output module 160 is connected to the height specifying module 150. The output module 160 outputs the floor specified by the height specifying module 150. For example, the information may be displayed on a display device such as a liquid crystal display included in the information processing apparatus 100, or the name and floor of the building are displayed together with the name of the owner of the information processing apparatus 100 in another information processing apparatus. You may do it. Note that the information processing apparatus 100 may notify the other information processing apparatus of the name of the owner of the information processing apparatus 100 and the like.
Further, the output module 160 stores information corresponding to the building and floor from the DB (database) that stores information about the building and floor (for example, the location of the conference room, toilet on the floor, and the building is a department store). , An advertisement for the sales floor on the floor, etc.) may be displayed.

FIG. 2 is an explanatory diagram illustrating an example of a system configuration when the present embodiment is realized. Note that the same parts as those of the portable information processing apparatus 100 shown in the example of FIG.
The portable information processing apparatus 200 includes an atmospheric pressure detection module 110, a position detection module 120, an output module 160, and a communication module 205. It is another structure aspect of the portable information processing apparatus 100 shown in the example of FIG. The portable information processing apparatus 100 has a configuration in which the portable information processing apparatus 200 and the position specifying processing device 220 are combined. The atmospheric pressure detection module 110 is connected to the communication module 205. The position detection module 120 is connected to the communication module 205. The output module 160 is connected to the communication module 205. The communication module 205 is connected to the atmospheric pressure detection module 110, the position detection module 120, and the output module 160, and via the communication line 290, the communication module 225 of the position specifying processing device 220 and the communication module of the portable information processing device 250. H.275.
The communication module 205 transmits the atmospheric pressure detected by the atmospheric pressure detection module 110 and the position detected by the position detection module 120 to the position specifying processing device 220 via the communication line 290. Then, the information (position, building name, floor, information on the position (position of the conference room, advertisement, etc.) described above) transmitted from the position specifying device 220 is received and output by the output module 160.

The position specifying processing device 220 includes a building information storage module 140, a height specifying module 150, a communication module 225, and an output module 230. It is another structure aspect of the portable information processing apparatus 100 shown in the example of FIG. The building information storage module 140 is connected to the height specifying module 150. The height specifying module 150 is connected to the building information storage module 140, the communication module 225, and the output module 230. The communication module 225 is connected to the height specifying module 150, and is connected to the communication module 205 of the portable information processing device 200 and the communication module 275 of the portable information processing device 250 via the communication line 290. The output module 230 is connected to the height specifying module 150.
The communication module 225 receives the atmospheric pressure, position, and detection time transmitted from the portable information processing device 200 via the communication line 290, and the atmospheric pressure, temperature, altitude, and detection time transmitted from the portable information processing device 250. The height identifying module 150 identifies the floor where the owner of the portable information processing apparatus 200 is located, and the output module 230 outputs the result. For example, a place where the portable information processing apparatus 200 is present may be displayed on a map. The communication module 225 may transmit the position of the owner of the portable information processing device 200 to the portable information processing device 200 or the portable information processing device 250 via the communication line 290.

The portable information processing apparatus 250 includes an atmospheric pressure detection module 255, a temperature detection module 260, a position detection module 265, a communication module 275, and an output module 280. There may be a plurality of portable information processing devices 250. The portable information processing device 250 is the “other detection device” described in the example of FIG. The atmospheric pressure detection module 255 is connected to the communication module 275. The temperature detection module 260 is connected to the communication module 275. The position detection module 265 is connected to the communication module 275. The communication module 275 is connected to the atmospheric pressure detection module 255, the temperature detection module 260, the position detection module 265, and the output module 280, and also via the communication line 290, the communication module 205 of the portable information processing apparatus 200, the position specifying process. The communication module 225 of the device 220 is connected. The output module 280 is connected to the communication module 275.
The atmospheric pressure detection module 255 detects the atmospheric pressure at the position where the portable information processing device 250 exists. It is a so-called barometric pressure sensor.
The temperature detection module 260 detects the temperature of the position where the portable information processing device 250 exists. This is a so-called temperature sensor.
The position detection module 265 detects the position where the portable information processing device 250 exists. For example, GPS, a position detection module of a base station (for example, 3G base station and WiFi base station) in a wireless communication network, and the like are applicable.
The communication module 275 performs a position specifying process on the atmospheric pressure detected by the atmospheric pressure detection module 255, the temperature detected by the temperature detection module 260, the altitude of the position where the portable information processing device 250 exists, and the detection time via the communication line 290. To device 220. Then, the position of the holder of the portable information processing device 200 is received from the position specifying processing device 220, and the output module 280 outputs the result. For example, a place where the portable information processing apparatus 200 is present may be displayed on a map.

FIG. 4 is a flowchart showing an example of processing according to this embodiment.
In step S402, the position detection module 120 acquires GPS information and base station position information, and the atmospheric pressure detection module 110 acquires atmospheric pressure information. Only one of the GPS information and the base station position information may be used.
In step S404, the position detection module 120 determines whether or not GPS information has been detected. If detected, the process proceeds to step S406. Otherwise, the process proceeds to step S408.
In step S406, the position detection module 120 determines a horizontal position (latitude, longitude) and an existing range (radius distance, etc.) from the GPS information.
In step S408, the position detection module 120 determines whether or not the position of the base station has been detected. If detected, the process proceeds to step S410. Otherwise, the process proceeds to step S412.
In step S410, the position detection module 120 determines the position in the horizontal direction and the existence range from the base station position information.
In step S412, the position detection module 120 determines the horizontal position and the existence range from the time-series data of GPS information and base station position information. As described above, the immediately preceding GPS information and base station position information may be used, or the horizontal position and existence range may be determined from time-series data.

In step S414, the position detection module 120 determines whether the position information has sufficient accuracy. If the position information has sufficient accuracy, the process proceeds to step S418. Otherwise, the process proceeds to step S416. Whether or not the accuracy is sufficient is determined by comparing the accuracy of the information acquired in step S402 with a predetermined value. For example, even when GPS information is detected, if the accuracy is not sufficient, the process proceeds to step S416. In the case from step S412, the process proceeds to step S416.
In step S416, the floor in the building is specified. Details will be described later using the flowchart shown in the example of FIG.
In step S418, the output module 160 outputs where the portable information processing apparatus 100 is. For example, the name and floor of the building are displayed on the display device.

FIG. 5 is an explanatory diagram showing a processing example according to the present embodiment.
In step S502, the reference information acquisition module 130 acquires atmospheric pressure information as a reference. In the example of FIG. 2, the atmospheric pressure detected by the atmospheric pressure detection module 255 of the portable information processing device 250.
In step S504, the reference information acquisition module 130 acquires temperature information serving as a reference. In the example of FIG. 2, the temperature is detected by the temperature detection module 260 of the portable information processing device 250.
In step S506, the height specifying module 150 calculates a standard atmospheric pressure. The above equation (2) is used.
In step S508, the height specifying module 150 calculates the standard temperature. The above equation (3) is used.
In step S510, the atmospheric pressure detection module 110 detects atmospheric pressure.
In step S512, the height specifying module 150 calculates the height (elevation). The results of steps S506, S508, and S510 are substituted into the above equation (1).

In step S514, the height specifying module 150 uses the data in the building information storage module 140 to specify the floor in the building. That is, the floor that matches the height calculated in step S512 is specified. Here, “matching” may be performed by comparing the height calculated in step S512 with the height of the first floor height column 361 and adopting the floor having the smallest difference. If the difference is not within a predetermined value, an error may be generated.
In step S516, the output module 160 outputs the position (floor) specified in step S514.

FIG. 6 is an explanatory diagram showing an example of the data structure of the measurement / specific result table 600. The measurement / identification result table 600 is data used by the height identification module 150. Note that the measurement / specific result table 600 is an actual experimental result. That is, the “other detection device (mobile information processing device 250)” serving as a reference was placed on the 15th floor, the user moved the mobile information processing device 100 to the third floor and the 10th floor, and measured the atmospheric pressure p. When the above-described processing is performed and the floor where the user is located is specified, the third floor and the tenth floor respectively. That is, this user who has the portable information processing apparatus 100 was on the third floor at 16:45:24, but moved to the 10th floor at 16:47:37. Thus, the data in the measurement floor column 644 and the data in the assumed floor column 654 match, indicating that the floor has been accurately identified.
The measurement floor column 644 is data used as an experiment and is not necessary in the present embodiment.

The measurement / specific result table 600 includes a time column 610, a reference column 620, a user column 640, and a calculation result column 650.
The reference column 620 includes a measurement data column 622 at 15F and a calculation column 624 from the 15F data.
The measurement data column 622 at 15F stores data received by the reference information acquisition module 130, and includes a measurement atmospheric pressure column 626, a height column 628, and a measured temperature column 630.
The calculation column 624 from 15F data stores the values calculated by the equations (2) and (3), and has a p0 column 632 and a t0 column 634.
The user column 640 includes a measurement atmospheric pressure column 642 and a measurement floor column 644. The measured atmospheric pressure column 642 stores the atmospheric pressure detected by the atmospheric pressure detection module 110.
The calculation result column 650 includes a height column 652 and an assumed floor column 654. The height column 652 stores the altitude calculated by the equation (1). The assumed floor column 654 stores a floor corresponding to the altitude.

In the present embodiment, data on atmospheric pressure and temperature from the portable information processing device 250 whose altitude is known is necessary. Six methods for specifying the altitude of the portable information processing device 250 and calculating the standard atmospheric pressure and the standard temperature will be described. It is assumed that the person who has portable information processing apparatus 200 is in the same building as the person who has portable information processing apparatus 250.
(1) Behavior pattern The daily behavior pattern of the portable information processing device 250 is grasped, the floor on which it is located is specified, and the altitude of the floor is used. That is, the altitude of the portable information processing device 250 is determined based on the behavior pattern of the user who owns the portable information processing device 250. If the floor can be specified and the atmospheric pressure and the temperature are acquired from the portable information processing device 250, the standard atmospheric pressure p0 and the standard temperature t0 can be calculated from the equations (2) and (3).
FIG. 7 is an explanatory diagram illustrating a processing example for calculating a reference value. The floor at each time is specified using a predetermined daily behavior pattern of the user who possesses the portable information processing device 250. For example, assume that an action pattern as shown in FIG. 7 is taken from past actions. In this case, a table A storing the correspondence between the time and the place, a table B storing the correspondence between the place and the floor, and a table C storing the correspondence between the floor and the altitude are prepared to detect the temperature and the atmospheric pressure. By extracting the location at the selected time from the table A, extracting the floor from the location from the table B, and extracting the elevation from the floor from the table C, the elevation of the portable information processing device 250 is specified, and the reference information acquisition module 130 hand over. For example, when atmospheric pressure or the like is detected at 13:32, the table A is used to be in a room, the table B is used to be on the 15th floor, and the table C is used to check the elevation of the 15th floor. Can be specified to be 77 m.

(2) Schedule The altitude of the portable information processing device 250 is determined based on the schedule of the user who owns the portable information processing device 250 and the detected time. In cooperation with the operation of a program called a scheduler, the floor where the portable information processing device 250 is located at that time of the day is specified. If the floor can be specified and the atmospheric pressure and the temperature are acquired from the portable information processing device 250, the standard atmospheric pressure p0 and the standard temperature t0 can be calculated from the equations (2) and (3).
FIG. 8 is an explanatory diagram illustrating an example of processing for calculating a reference value. As shown in the example of FIG. 8, the date and location (for example, being in the hall (4th floor) of a building from 15:00 to 17:00 on August 6, 2012) are acquired from the scheduler, and the temperature and pressure are detected. If the time is within that time zone, the altitude of the portable information processing device 250 is extracted by extracting the location from the table A, extracting the floor from the location from the table B, and extracting the altitude from the floor from the table C. Specify and pass to the reference information acquisition module 130. For example, if atmospheric pressure or the like is detected at 15:32, the scheduler is used to be in the hall, the table B is used to be on the fourth floor, the table C is used to determine the altitude of the fourth floor. It can be specified as 27 m. The scheduler may be built in the portable information processing device 250 or may be in another information processing device (for example, the position specifying processing device 220). When a scheduler in another information processing apparatus is used, a user who owns the portable information processing apparatus 250 may be searched from data managed by the scheduler.

(3) Statistical Representative Value FIG. 9 is an explanatory diagram illustrating a processing example for calculating a reference value.
As the same group member (15F work) 900, there is a user who possesses a portable information processing device 910, a portable information processing device 920, a portable information processing device 930, and a portable information processing device 940. A plurality of users whose working floor is known are extracted, and the atmospheric pressure value detected by the plurality of portable information processing devices 250 possessed by the plurality of users is used as the atmospheric pressure of the floor. For example, if the atmospheric pressure detected by three of the four portable information processing devices 250 is close, the average value of the atmospheric pressure detected by the three portable information processing devices 250 is obtained as reference information of the portable information processing device 100. Transmit to module 130. In addition, what is necessary is just to set it as the range of the height of the same floor as the range of "near atmospheric pressure". For example, when the floor is 4.5 m, it may be determined that the range of 0.54 hPa is on the same floor (1 m = 0.12 hPa). For “extraction of users whose work floor is known”, (1), (2), etc. may be used. That is, when there is a user who does not act according to the behavior pattern or schedule, The barometric pressure detected by the portable information processing apparatus 250 possessed is not used, and an error in the barometric pressure detected by the individual portable information processing apparatus 250 is also dealt with.
The reference information acquisition module 130 receives a plurality of atmospheric pressures, temperatures, and altitudes. Then, the height specifying module 150 is based on the air pressure, the air temperature, the altitude, and the air pressure detected by the air pressure detecting module 110 as statistical representative values of the air pressure, the air temperature, and the altitude received by the reference information acquisition module 130. The altitude at the time when the atmospheric pressure detection module 110 detects is calculated. As the statistical representative value, a mode value, a median value, or the like may be used in addition to the average value example.

(4) Behavior Recognition The altitude of the portable information processing device 250 is determined based on the result of recognizing the behavior of a user (either an individual or a plurality of people) who has the portable information processing device 250. The user is sitting on a chair, standing up, walking, in a meeting, etc., using an acceleration sensor or the like provided in the portable information processing apparatus 250, or an image, video, and voice acquisition means. It is possible to make a judgment using a value to be detected. This technique uses a known technique. For example, when there are people who are located within a predetermined range, a plurality of people are sitting on a chair, and one person is standing, it is determined that a meeting is in progress.
FIG. 10 is an explanatory diagram illustrating a processing example for calculating a reference value. If it is recognized that the action of the user who owns the portable information processing apparatus 1010, the portable information processing apparatus 1020, and the portable information processing apparatus 1030 is in a meeting, if the space available for the meeting is only on the 15th floor, Judge that In other words, the atmospheric pressure is detected at a certain time, and the action recognition result is “during meeting”, the conference room is on the 15th floor using the table B, and the altitude of the 15th floor is 77 m using the table C. It can be specified that there is.

(5) Desktop PC
When a fixed information processing apparatus (for example, a desktop PC) that is a fixed information processing apparatus is used by a user who has the portable information processing apparatus 250, the altitude at the position where the fixed information processing apparatus is installed is carried The altitude of the information processing apparatus 250 is determined. For example, when a user logs in to a desktop PC whose installation floor is known, the user is identified from the login information, and the atmospheric pressure and temperature detected by the portable information processing device 250 possessed by the user are used. More specifically, the table D stores the correspondence between the desktop PC (IP address) and the floor on which it is installed, and stores the correspondence between the user name and the portable information processing device 250 possessed by the user. Table E and the above-mentioned table C are used. For example, when it is determined that the user logs in to the desktop PC and uses a keyboard or the like, the portable information processing device 250 possessed by the user is specified using the table E, and the portable information processing device 250 is identified. When the air pressure or the like is detected, the floor is specified using the table D, and the altitude is specified using the table C.

(6) Entrance / exit management device When the user who has the portable information processing device 250 passes the entrance / exit management device, the altitude of the position where the entrance / exit management device is installed is set as the elevation of the portable information processing device 250. Determine. As an entrance / exit management device, for example, there is a device that manages opening and closing of a door by reading an IC card, authentication using a biometric technology, or the like. Prepare a table F that stores the correspondence between the entrance / exit management device and the altitude of the location where the entrance / exit management device is installed, identify the user who has passed the entrance / exit management device, and use the table E The portable information processing apparatus 250 possessed by the user is specified, the elevation of the entrance / exit management apparatus is extracted using the table F, and the elevation of the portable information processing apparatus 250 is obtained. For example, you may utilize when the entrance / exit management apparatus is installed for every floor. In addition, the atmospheric pressure detection module 255 of the portable information processing device 250 may detect atmospheric pressure or the like at the timing of passing through the entrance / exit management device.
After passing through the entrance / exit management device, the mobile information processing device 250 carries the mobile phone based on the change in atmospheric pressure detected by the atmospheric pressure detection module 255 and the altitude of the position where the entrance / exit management device is installed. The altitude of the information processing apparatus 250 is determined. For example, the atmospheric pressure detection module 255 is operated at the timing of passing through the entrance / exit management device, and the subsequent atmospheric pressure fluctuation is recorded. The floor can be identified by calculating the movement distance in the up-and-down direction from the fluctuation amount of the atmospheric pressure and calculating the number of floors moved up and down. In addition, by updating the specified floor information one by one, when the floor moves next time, the same movement distance is calculated and the floor is specified.
The “change in atmospheric pressure” is the difference between the atmospheric pressure A detected when passing the entrance / exit management device and the atmospheric pressure B detected at the current time. The altitude difference (elevation difference) is calculated from the difference in atmospheric pressure, and is added to or subtracted from the altitude at the position where the entrance / exit management device is installed to calculate the altitude of the portable information processing device. As to whether to perform addition or subtraction, if the difference obtained by subtracting the atmospheric pressure B from the atmospheric pressure A is negative (when moving to a lower floor), the difference is obtained by subtracting the atmospheric pressure B from the atmospheric pressure A. If it is positive (when moving to a higher floor), it is an addition.

  Note that the hardware configuration of a computer on which the program according to the present embodiment is executed is a general computer as illustrated in FIG. 11, and specifically, a portable information processing device 200, a portable information processing device 250. Are a mobile phone, a notebook PC, and a computer that can serve as a server as the position specifying processing device 220. That is, as a specific example, the CPU 1101 is used as a processing unit (calculation unit), and the RAM 1102, the ROM 1103, and the HD 1104 are used as storage devices. For example, a hard disk may be used as the HD 1104. Pressure detection module 110, position detection module 120, reference information acquisition module 130, height identification module 150, output module 160, output module 230, pressure detection module 255, temperature detection module 260, position detection module 265, output module 280, etc. A CPU 1101 that executes a program; a RAM 1102 that stores the program and data; a ROM 1103 that stores a program for starting the computer; an HD 1104 that is an auxiliary storage device; and detection results from various sensors; Alternatively, a reception device 1106 that accepts data based on user operations on a keyboard, mouse, touch panel, and the like, an output device 1105 such as a liquid crystal display, and a network interface Communication line interface 1107 for connecting to the wireless communication line such as Sukado And, and a bus 1108 for exchanging data by connecting them. A plurality of these computers may be connected to each other via a network.

Among the above-described embodiments, the computer program is a computer program that reads the computer program, which is software, in the hardware configuration system, and the software and hardware resources cooperate with each other. Is realized.
Note that the hardware configuration illustrated in FIG. 11 illustrates one configuration example, and the present embodiment is not limited to the configuration illustrated in FIG. 11, and is a configuration capable of executing the modules described in the present embodiment. I just need it. For example, some modules may be configured by dedicated hardware (for example, ASIC), and some modules may be in an external system and connected via a communication line. A plurality of systems shown in FIG. 5 may be connected to each other via communication lines so as to cooperate with each other.

  In the above-described embodiment, the portable information processing device 250 is exemplified as “another detection device”. However, the portable information processing device 250 is not portable and may be a fixed detection device. In that case, since the altitude of the “other detection device” does not change, it is not necessary to perform the processing described in FIG.

The program described above may be provided by being stored in a recording medium, or the program may be provided by communication means. In that case, for example, the above-described program may be regarded as an invention of a “computer-readable recording medium recording the program”.
The “computer-readable recording medium on which a program is recorded” refers to a computer-readable recording medium on which a program is recorded, which is used for program installation, execution, program distribution, and the like.
The recording medium is, for example, a digital versatile disc (DVD), which is a standard established by the DVD Forum, such as “DVD-R, DVD-RW, DVD-RAM,” and DVD + RW. Standard “DVD + R, DVD + RW, etc.”, compact disc (CD), read-only memory (CD-ROM), CD recordable (CD-R), CD rewritable (CD-RW), Blu-ray disc ( Blu-ray Disc (registered trademark), magneto-optical disk (MO), flexible disk (FD), magnetic tape, hard disk, read-only memory (ROM), electrically erasable and rewritable read-only memory (EEPROM (registered trademark)) )), Flash memory, Random access memory (RAM) SD (Secure Digital) memory card and the like.
The program or a part of the program may be recorded on the recording medium for storage or distribution. Also, by communication, for example, a local area network (LAN), a metropolitan area network (MAN), a wide area network (WAN), a wired network used for the Internet, an intranet, an extranet, etc., or wireless communication It may be transmitted using a transmission medium such as a network or a combination of these, or may be carried on a carrier wave.
Furthermore, the program may be a part of another program, or may be recorded on a recording medium together with a separate program. Moreover, it may be divided and recorded on a plurality of recording media. Further, it may be recorded in any manner as long as it can be restored, such as compression or encryption.

DESCRIPTION OF SYMBOLS 100 ... Portable information processing apparatus 110 ... Barometric pressure detection module 120 ... Position detection module 130 ... Reference information acquisition module 140 ... Building information storage module 150 ... Height identification module 160 ... Output module 200 ... Portable information processing apparatus 205 ... Communication module 220 ... Position identification processing device 225 ... communication module 230 ... output module 250 ... portable information processing device 255 ... barometric pressure detection module 260 ... temperature detection module 265 ... position detection module 275 ... communication module 280 ... output module 290 ... communication line

Claims (5)

Receiving means for receiving the atmospheric pressure and temperature detected by the other detection device and the altitude of the other detection device;
Barometric pressure detecting means for detecting barometric pressure at a position where a portable information processing device exists;
Calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, the temperature, the altitude received by the reception means, and the atmospheric pressure detected by the atmospheric pressure detection means;
A specifying means for specifying the floor corresponding to the altitude calculated by the calculating means from the storing means storing the floor and the height of the floor in association with each other;
Output means for outputting the floor specified by the specifying means ;
The other detection device is a plurality of portable information processing devices, and determines an altitude of the information processing device based on a behavior type of a person who possesses the information processing device,
The accepting means accepts a plurality of atmospheric pressures, temperatures and altitudes,
The calculating means includes a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means based on a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means. Calculate the altitude at the time of detection,
The calculation means does not use the atmospheric pressure, temperature and altitude received from the information processing device when the behavior of the person carrying the portable information processing device does not apply to the type apparatus. Receiving means for receiving the atmospheric pressure and temperature detected by the other detection device and the altitude of the other detection device;
Barometric pressure detecting means for detecting barometric pressure at a position where a portable information processing device exists;
Calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, the temperature, the altitude received by the reception means, and the atmospheric pressure detected by the atmospheric pressure detection means;
A specifying means for specifying the floor corresponding to the altitude calculated by the calculating means from the storing means storing the floor and the height of the floor in association with each other;
Output means for outputting the floor specified by the specifying means ;
The other detection device is a plurality of portable information processing devices, and determines the altitude of the information processing device based on the time of detection and the schedule of the person carrying the information processing device,
The accepting means accepts a plurality of atmospheric pressures, temperatures and altitudes,
The calculating means includes a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means based on a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means. Calculate the altitude at the time of detection,
The calculation means does not use the pressure, temperature and altitude received from the information processing apparatus when the action of the person who possesses the portable information processing apparatus does not fit in the schedule . The accepting means accepts the time when the other detecting device detects the atmospheric pressure and the temperature,
The calculating means calculates the altitude using the atmospheric pressure and the temperature received by the receiving means detected at a time within a predetermined range from the time when the atmospheric pressure detecting means detects the atmospheric pressure. The information processing apparatus according to claim 1 or 2 . Computer
Receiving means for receiving the atmospheric pressure and temperature detected by the other detection device and the altitude of the other detection device;
Barometric pressure detecting means for detecting barometric pressure at a position where a portable information processing device exists;
Calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, the temperature, the altitude received by the reception means, and the atmospheric pressure detected by the atmospheric pressure detection means;
A specifying means for specifying the floor corresponding to the altitude calculated by the calculating means from the storing means storing the floor and the height of the floor in association with each other;
Function as output means for outputting the floor specified by the specifying means ;
The other detection device is a plurality of portable information processing devices, and determines an altitude of the information processing device based on a behavior type of a person who possesses the information processing device,
The accepting means accepts a plurality of atmospheric pressures, temperatures and altitudes,
The calculating means includes a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means based on a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means. Calculate the altitude at the time of detection,
The calculation means does not use the pressure, temperature and altitude received from the information processing device when the behavior of the person who possesses the portable information processing device does not apply to the type
An information processing program characterized by that . Computer
Receiving means for receiving the atmospheric pressure and temperature detected by the other detection device and the altitude of the other detection device;
Barometric pressure detecting means for detecting barometric pressure at a position where a portable information processing device exists;
Calculation means for calculating the altitude at the time point detected by the atmospheric pressure detection means based on the atmospheric pressure, the temperature, the altitude received by the reception means, and the atmospheric pressure detected by the atmospheric pressure detection means;
A specifying means for specifying the floor corresponding to the altitude calculated by the calculating means from the storing means storing the floor and the height of the floor in association with each other;
Function as output means for outputting the floor specified by the specifying means ;
The other detection device is a plurality of portable information processing devices, and determines the altitude of the information processing device based on the time of detection and the schedule of the person carrying the information processing device,
The accepting means accepts a plurality of atmospheric pressures, temperatures and altitudes,
The calculating means includes a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means based on a plurality of pressures, temperatures, altitudes, and air pressures detected by the pressure detecting means. Calculate the altitude at the time of detection,
The calculation means does not use the atmospheric pressure, temperature, and altitude received from the information processing device when the behavior of the person carrying the portable information processing device does not fit in the schedule
An information processing program characterized by that .

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