WO2005094110A1 - 通信装置、誘導方法、誘導処理用プログラム、及び記録媒体 - Google Patents
通信装置、誘導方法、誘導処理用プログラム、及び記録媒体 Download PDFInfo
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- WO2005094110A1 WO2005094110A1 PCT/JP2005/005150 JP2005005150W WO2005094110A1 WO 2005094110 A1 WO2005094110 A1 WO 2005094110A1 JP 2005005150 W JP2005005150 W JP 2005005150W WO 2005094110 A1 WO2005094110 A1 WO 2005094110A1
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- electric field
- field intensity
- information
- communication device
- radio wave
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Classifications
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W4/00—Services specially adapted for wireless communication networks; Facilities therefor
- H04W4/02—Services making use of location information
- H04W4/024—Guidance services
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C21/00—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00
- G01C21/26—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00 specially adapted for navigation in a road network
- G01C21/28—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00 specially adapted for navigation in a road network with correlation of data from several navigational instruments
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- G—PHYSICS
- G08—SIGNALLING
- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/005—Traffic control systems for road vehicles including pedestrian guidance indicator
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/50—Network services
- H04L67/52—Network services specially adapted for the location of the user terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W4/00—Services specially adapted for wireless communication networks; Facilities therefor
- H04W4/02—Services making use of location information
Definitions
- the present invention relates to a communication device that performs wireless communication by radio waves via a communication network, a guidance method in the communication device, a guidance processing program, and a recording medium.
- an in-vehicle navigation device having a wireless communication function disclosed in Japanese Patent Application Laid-Open No. 2003-101462.
- the navigation device uses an incoming radio wave from a GPS (Global Positioning System) satellite to change the current location to the destination. It has a general navigation function that searches for the optimal route (recommended route) up to and displays the optimal route on a display on a map. It has a function of receiving road map information from the like.
- GPS Global Positioning System
- the in-vehicle navigation device having a wireless communication function is not limited to receiving calls and map information, but is also capable of wirelessly transmitting various information such as music and images distributed from distribution sites on the Internet. It can be downloaded via a communication network, and by presenting such various information to a user or the like, it is possible to provide excellent convenience.
- Patent Document 1 JP 2003-101462 A
- the communication quality depends on the radio wave condition.
- Mobile devices such as navigation devices and mobile phones that have a wireless communication function, for example, in locations where radio waves cannot reach or where radio waves are not good. In such a case, there is a problem that the original wireless communication function cannot be exhibited when the mobile terminal is moved to a location.
- a mobile communication device such as a navigation device or a mobile phone
- a third party such as a public institution can quickly and quickly be notified. It is recognized that the importance of a mobile communication device such as a navigation device or a mobile phone as a communication means in an emergency because it is possible to make an accurate notification.
- the electric field intensity of a communication radio wave distributed on a storage medium such as a CD-ROM together with road map information is used.
- the distribution information is stored in the device in advance, and by comparing the current position of the user or the like while moving with the road map information and the electric field strength distribution information, the user is moving in a place with poor radio wave conditions (outside the communication area). Or not.
- a search is made for a place with good radio wave conditions (within the communicable area) from the above-mentioned road map information and electric field strength distribution information, and the user or the like is called from outside the communicable area.
- the route for guiding to the possible area is displayed on a map as a map, that is, navigation is performed.
- the user or the like is moved to a location having a good radio wave condition by using the electric field strength distribution information of the communication radio wave distributed on a storage medium such as a CD-ROM. Because of the guidance, the electric field strength distribution information itself becomes outdated, and when guiding the user or the like from outside the communicable area to within the communicable area, the There is a problem in that it is not possible to perform highly reliable guidance based on the current position during the actual movement.
- the present invention has been made in view of such conventional problems, and presents a mobile communication system capable of presenting a place having a good radio wave condition to a user and the like, and presenting highly reliable information on the radio wave condition. It is intended to provide a device.
- the invention according to claim 1 is a communication device that performs wireless communication by radio waves via a communication network, wherein a position information detecting unit that detects a position of the communication device and outputs position information, Electric field intensity measuring means for measuring electric field intensity of radio waves and outputting electric field intensity information; a storage means for storing the position information and the electric field intensity information in association with each other as actual measurement information; Guiding means for creating an electric field intensity distribution based on the actually measured information, and presenting a direction in which the radio wave condition becomes favorable at the current position of the communication device based on the created electric field intensity distribution and the positional information. It is characterized by the following.
- the invention according to claim 7 relates to a guidance method in a communication device that performs wireless communication by radio waves via a communication network, and detects a position of the communication device and outputs position information.
- the radio wave condition at the current position of the communication device is determined based on the electric field intensity distribution created by the process and the position information output in the position information output step.
- Situation characterized by having a a presentation step of presenting a direction is improved.
- the invention according to claim 8 is a program that causes a computer provided in a communication device that performs wireless communication by radio waves via a communication network to perform a guidance process, and detects a position of the communication device.
- a recording medium is characterized in that the guidance processing program according to the eighth aspect is recorded and recorded.
- FIG. 1 is a block diagram showing a configuration of a mobile communication device according to an embodiment of the present invention.
- FIG. 2 is a block diagram illustrating a configuration of a mobile communication device according to an embodiment.
- FIG. 3 is a diagram for explaining functions of the mobile communication device shown in FIG. 2.
- FIG. 4 is a view showing a picture mark displayed on a display unit provided in the mobile communication device shown in FIG. 2.
- FIG. 5 is a flowchart showing an operation example of the mobile communication device shown in FIG. 2.
- FIG. 6 is a flowchart showing an operation example of the mobile communication device shown in FIG. 2.
- FIG. 7 is a flowchart showing an operation example of the mobile communication device shown in FIG. 2.
- FIG. 1 is a block diagram illustrating a configuration of a main part of the mobile communication device according to the present embodiment.
- the mobile communication device 1 includes a control unit 2, a position information detection unit 3, a communication unit 4, an electric field strength measurement unit 5, a guidance unit 6, and a storage unit 7.
- the position information detection unit 3 has a GPS receiver and the like, detects the position of the mobile communication device 1 using radio waves arriving from GPS satellites, and generates position data Dps indicating the detection result. Output.
- the communication unit 4 performs radio communication by radio waves via a mobile communication network when a user or the like makes a telephone call, performs mail communication, Internet communication, or the like.
- the electric field intensity measuring unit 5 measures the electric field intensity of the radio wave based on the received signal received by the communication unit 4 during communication, and outputs electric field intensity data Dep indicating the measurement result.
- the storage unit 7 stores the electric field intensity data Dep output from the electric field intensity measurement unit 5 as actual measurement data Da. That is, by associating the electric field intensity data Dep with the position data Dps, the electric field intensity data Dep specifying the measurement location is stored as the actual measurement data Da. Then, by storing the electric field strength data D which is output every moment as actual measurement data Da, a database for storing a large number of actual measurement data Da is constructed.
- the guiding unit 6 determines the current position (in other words, the current position of the user or the like) when the mobile communication device 1 moves based on the position data Dps output from the position information detecting unit 3. Upon detection, an electric field strength distribution is created based on the actual measurement data Da stored in the storage unit 7. Then, with respect to the detected current position, the communication unit 4 detects a direction in which a favorable radio wave condition is obtained from the electric field intensity distribution, and presents the detected direction on a display or the like.
- the control unit 2 controls the operation of the mobile communication device 1 as a whole, and also deletes the actual measurement data Da past a predetermined time already stored in the storage unit 7 and further adds new actual measurement data Da.
- the latest measured data Da is accumulated by deleting the already measured old measured data Da in order.
- the communication unit 4 performs communication when the communication unit 4 performs communication.
- the electric field intensity is actually measured by the electric field intensity measuring unit 5, and the storage unit 7 associates the electric field intensity data Dep output from the electric field intensity measuring unit 5 with the position data Dps output from the position information detecting unit 3.
- a database is constructed by storing the measured data Da attached. Then, when the guiding unit 6 presents a place where the communication unit 4 can communicate in a favorable radio wave condition, an electric field intensity distribution is created based on the measured data Da, and based on the electric field intensity distribution. Then, a direction in which a favorable radio wave condition can be obtained is detected.
- the information on the electric field strength of the radio wave measured at the place where the user or the like has actually moved is stored as the actually measured data Da associated with the position information.
- the direction (location) where a good radio wave condition can be obtained for the communication unit 4 is detected by using the stored actual measurement data Da. High guidance information can be presented.
- FIG. 2 is a block diagram illustrating a configuration of a mobile phone having a navigation function according to the present embodiment
- FIG. 3 is a diagram illustrating functions of the mobile phone.
- this mobile phone (hereinafter referred to as “mobile communication device”) 1 includes a control unit 2, a position information detection unit 3, a communication unit 4, an electric field strength measurement unit 5, a guidance unit 6, and a storage unit. It comprises a unit 7, a display unit 8, and an operation unit 11.
- the control unit 2 is formed of a circuit having a microprocessor (MPU) and the like, and executes the system program stored in the ROM or the like in advance by the microprocessor. 1. Control the whole operation.
- MPU microprocessor
- An operation unit 11 is connected to the control unit 2, and various operation buttons (not shown) provided on the operation unit 11 are operated by a user or the like, so that the control unit 2 is controlled. It is possible to give desired instructions.
- the position information detection unit 3 the communication unit 4, the electric field strength measurement unit 5, and the guidance unit
- the storage unit 6, the storage unit 7, and the operation unit 11 are interconnected via a so-called data bus, address bus, and control bus.
- the position information detection unit 3 has a GPS receiver that receives an incoming radio wave from a GPS satellite, and based on a received signal received by the GPS receiver, the current position of the mobile communication device 1 (Latitude and longitude) and supplies the position data Dps indicating the measurement result to the control unit 2.
- the mobile communication device 1 when an instruction of “start navigation” is given by a user or the like via the force operation unit 11 described in detail later, the mobile communication device 1 At the same time as the gazing operation is started, the position information detecting unit 3 starts the positioning operation, detects the current position (latitude and longitude) moment by moment, and supplies each position data Dps to the control unit 2 one by one.
- control unit 2 supplies the position data Dps to the guidance unit 6 one by one, so that the optimal route to the destination desired by the user or the like is displayed on the display unit 8 based on each position data Dps. A so-called navigation process for displaying a diagram is performed.
- the control unit 2 creates actual measurement data Da, which will be described later, based on the individual position data Dps output from the position information detection unit 3, and stores the first measurement data Da in the storage unit 7.
- the electric field strength information is stored in the file 10a.
- the communication unit 4 has a communication device for performing wireless communication via a mobile communication network, and a user or the like operates the operation unit 11 to make a telephone call, perform a mail communication, or use the Internet. When communication or the like is performed, the communication operation is performed under the control of the control unit 2.
- the electric field strength measuring unit 5 measures the reception sensitivity of the incoming radio wave (in other words, the electric field strength of the incoming radio wave) every moment. And supplies the field strength data D indicating the measurement result to the control unit 2 one by one. That is, the communication device provided in the communication unit 4 is provided with a frequency conversion circuit that receives an incoming radio wave and generates an intermediate frequency signal, and the electric field strength measuring unit 5 determines an effective value of the intermediate frequency signal. By measuring such factors, the electric field strength of the incoming radio wave is measured.
- the electric field intensity measuring unit 5 of the present embodiment measures the electric field intensity of the arriving radio wave by measuring the effective value of the intermediate frequency signal and the like. You can also measure.
- the control unit 2 transmits the electric field intensity data Dep, the position data Dps output from the position information detecting unit 3, and the control Generates actual measurement data Da by combining three pieces of data with time data Dtm output from a clock circuit (not shown) provided in unit 2, and generates a first electric field intensity provided in storage unit 7. It is stored in the information file 10a.
- control unit 2 correlates the position data Dps, the electric field intensity data Dep, and the time data Dtm, thereby obtaining the electric field intensity of the arriving radio wave at the place where the user or the like actually exists, the measurement date and time, and the like. Is generated and stored in the first electric field strength information file 10a.
- the control unit 2 when a user or the like carries the mobile communication device 1 and moves while making a telephone call or performing mail communication or Internet communication, the control unit 2 generates the measured data Da one after another. By storing the information in the storage unit 7, a database having information on the electric field intensity distribution is constructed. [0043] Further, even when a user or the like does not make a phone call, does not perform e-mail communication, Internet communication, or the like, the electric field strength measurement unit 5 measures the radio wave condition between the base station and the mobile station to obtain an electric field.
- the controller 2 outputs the intensity data Dep, and the control unit 2 successively generates actual measurement data Da in which the electric field intensity data Dep, the position data Dps, and the time data Dtm are associated with each other, and stores the measured data Da in the storage unit 7.
- a database having information on the electric field intensity distribution is constructed.
- the storage unit 7 is formed of a rewritable nonvolatile semiconductor memory or the like, and manages various data in accordance with a file system having a predetermined directory structure.
- the information file 10a it has a map information file 9 for storing map data Dm, and a second electric field strength information file 10b for storing distribution data Db.
- the map information file 9 is a so-called map information database that stores the latest map data Dm distributed from a distribution site on the Internet, for example.
- the first electric field intensity information file 10a is a database that stores information indicating the electric field intensity of an incoming radio wave at a place where a user or the like actually exists by storing the above-described measured data Da. I have.
- the second electric field intensity information file 10b stores distribution data Db indicating the electric field intensity of the radio wave in each place, which is distributed together with the map data Dm from, for example, a distribution site on the Internet. It is an information database.
- the guiding unit 6 is formed by a digital signal processor (DSP) or the like, and displays information useful for a user or the like on a display unit 8 formed by a liquid crystal display or the like. It has a function.
- DSP digital signal processor
- the guidance unit 6 has a ⁇ normal guidance function> as a first function.
- the guidance unit 6 starts the navigation processing, and the user or the like communicates by telephone, mail communication, or Internet communication.
- the communication unit 4 performs the communication operation and the communication is not performed, the ⁇ normal guidance function> is activated and the operation mode becomes the “normal guidance”.
- the guidance unit 6 determines the position (start position) of the user or the like when the navigation start instruction is input by using the position data Dps from the position information detection unit 3. And the optimum route from the start position to the destination which can satisfy the search conditions (for example, the shortest distance, the shortest time, etc.) preset by the user or the like via the operation unit 11. Then, map data Dm near the start position is read from the map information file 9 in the storage unit 7, and displayed on the display unit 8 in a map together with the optimum route. That is, as shown in FIG. 3A, the optimal route R1 from the start position A to the destination B is displayed together with the map.
- the guiding unit 6 moves the position of the user or the like (current position) based on the position data Dps supplied momentarily from the position information detecting unit 3. Is detected, and the current position of the user or the like is displayed in real time by a cursor such as an arrow indicating the traveling direction. Therefore, as shown in FIG. 3 (a), if the user moves along the optimum route R1 from the start position A to the destination B, the cursor moves along the optimum route R1. Etc. can be informed of the current location
- the map data Dm near the current position is read from the map information file 9, and the map, the optimal route R1, and the cursor are displayed. Provide a display that is easy for the user or the like to see until reaching the destination B.
- the guiding unit 6 sets the moved position as a new start position and sets a new optimal route to the destination B.
- the map data Dm in the vicinity of the new start position is read from the map information file 9 and displayed on the display unit 8 together with the new optimum route.
- the current position of the user or the like is displayed by the cursor, and the same processing is repeated, thereby performing the navigation processing corresponding to the moving state of the user or the like.
- the guiding unit 6 has a ⁇ communication guiding function> as a second function.
- the user or the like operates the operation unit 11, designates a desired destination, and starts the “navigation start”.
- the guidance unit 6 starts the navigation process, and when the user or the like is performing telephone, mail communication, Internet communication, or the like, that is, when the communication unit 4 is performing a communication operation, ⁇ Communication Guidance Function> is activated and the operation mode is set to “Communication Guidance”
- the guidance unit 6 determines the position (start position) of the user or the like when the navigation start instruction is issued by the position data from the position information detection unit 3. Data from the start position to the destination, and searches for an optimal route that can satisfy the conditions set by the user, such as the shortest distance, the shortest time, etc. Further, the map data Dm near the start position is read from the map information file 9 and displayed on the display unit 8 together with the optimum route on the map, and the current position accompanying the movement of the user or the like is displayed with the cursor.
- the guidance unit 6 basically performs the same navigation processing as the above-described “normal guidance” operation mode even in the “communication guidance” operation mode.
- the route is a route in which a good radio wave condition can be obtained for the communication unit 4 and satisfies the above conditions set by the user or the like.
- the route to be obtained is searched as the optimal route.
- the guiding unit 6 determines an area from the start position A to the destination B, that is, an area that is not limited to roads, as a search area based on search conditions in which setting conditions of the user or the like are relaxed.
- the actual measurement data Da and distribution data Db corresponding to the search area are read from the first and second electric field strength information files 10a and 10b.
- an electric field intensity distribution in the search area is created based on the read actual measurement data Da and distribution data Db, and based on the electric field intensity distribution.
- the guide unit 6 presents a place with good radio wave conditions to the user and the like by displaying the created electric field intensity distribution in a contour line.
- the guiding unit 6 gives priority to the measured data Da stored in the first electric field intensity file 10a with respect to the distribution data Db stored in the second electric field intensity file 10b. And an electric field strength distribution in a place where the measured data Da is not stored is created based on the distribution data Db. Then, when searching for the optimal route, first, a search is performed based on the electric field strength distribution created from the measured data Da, and the electric field strength distribution at a place where the measured data Da is not stored is obtained from the distribution data Db. By complementing with a distribution, a search is made for the optimal route without a break from the start position to the destination.
- the electric field intensity distribution created from the actually measured data Da and the electric field intensity distribution created from the distribution data Db are displayed in a contour line on the display unit 8, so that the radio wave condition with good radio conditions can be given to a user or the like. Present the location.
- the guiding unit 6 searches for the optimal route using the actually measured data Da stored in the first electric field strength information file 10a, and determines a location with a good radio wave condition. Since the information is presented as the electric field intensity distribution, it is possible to provide navigation information based on extremely reliable measured data Da measured when the user or the like actually moves.
- the search for the optimum route and the display of the electric field intensity distribution are performed using the actually measured data Da and the distribution data Db, but only the actually measured data Da is used.
- the search for the optimum route and the display of the electric field strength distribution may be performed by using the above-described method.
- the measured data Da is stored, and the optimum route at the location is searched based on the electric field intensity distribution created from the measured data Da, and the searched optimum route is displayed on a map. By connecting along a road or the like, an optimal route in a place where the actual measurement data Da is not stored may be approximately searched.
- the guidance unit 6 has a ⁇ map non-display function> as a third function.
- the guidance unit 6 performs the navigation processing in the above-described “normal guidance” or “communication guidance” operation mode and displays the route to the destination on the map on the display unit 8, the user displays the map. If no instruction is given, the guiding unit 6 enters the operation mode of "map non-display", and as shown in FIG. 4 (a), a part of the display screen without displaying the map on the display unit 8. Only at this point, a picture mark M indicating the direction in which the user or the like should travel from the current position to move along the route to the destination is displayed.
- the guiding unit 6 continues the navigation processing without displaying the map on the display unit 8, creates the electric field intensity distribution, and searches for the optimal route. Then, the current position of the user or the like during movement is detected, and the direction in which the user or the like should travel from the current position to move along the optimal route is detected. Then, instead of not displaying the map, the direction in which the user or the like should proceed from the current position is displayed by a picture mark M on a part of the display screen of the display unit 8.
- the guiding unit 6 includes a plurality of line groups on the right side of the antenna pattern. Display the added picture pattern M on a part of the display screen. If the user or the like should proceed from the current position to the left, a pattern pattern M with multiple lines added to the left of the antenna pattern is displayed as shown in Fig. 4 (b). Display on a part of the screen. In addition, when the user or the like should proceed from the current position on the rear side, as shown in FIG. 4 (c), a pattern pattern M in which a plurality of line groups are added below the antenna pattern is displayed. Display on a part of the display screen. When the user or the like should proceed from the current position on the front side, as shown in Fig. 4 (d), a pattern group M with a plurality of lines added above the antenna pattern is displayed. Display on a part of the display screen.
- the user or the like moves in the direction indicated by the picture mark M, For example, it is possible to reach a destination while displaying information other than a map such as a mail message or information downloaded via the Internet on almost the entire display screen of the display unit 8.
- the user and the like can not only display various kinds of information but also arrive at the destination while performing communication or the like under favorable radio wave conditions.
- map non-display function it is possible to display other information on the display unit 8 while providing the navigation information to the user and the like, thereby improving the operability of the user and the like. I can do it.
- the guidance unit 6 displays the favorable direction of the radio wave condition in various pattern patterns M on the display screen of the display unit 8, it is possible to present a guidance display that is easy for the user or the like to understand.
- the guidance unit 6 has a ⁇ moving priority automatic switching function> as a fourth function.
- the guidance unit 6 When the guidance unit 6 performs the navigation processing by the ⁇ communication guidance function> in accordance with the instruction of the user or the like, the ⁇ moving priority automatic switching function> operates in parallel.
- the guiding unit 6 calculates the moving distance L of the user or the like during a predetermined time ⁇ (for example, 5 minutes).
- the travel speed S is calculated from the ratio of the travel distance L to the time ⁇ . Further, the movement speed S is calculated every time. If the calculated moving speed S is smaller than the threshold Th (for example, 4 km / h), it is determined that the user or the like is moving on foot.
- the guidance unit 6 continues the navigation processing by the ⁇ communication guidance function> described above and the display unit 8 displays an optimal route with good radio wave conditions on a map
- the user or the like follows the optimal route.
- the guiding unit 6 determines that the vehicle is moving while placing importance on a favorable radio wave condition, and continues the navigation by the ⁇ communication guiding function> described above. In other words, even when it is determined that the user or the like is moving on foot, the guiding unit 6 is moving while emphasizing a good radio wave condition if the user or the like moves along the optimal route. Then, the navigation by ⁇ communication guiding function> described above is continued.
- the guidance unit 6 continues the navigation processing by the ⁇ communication guidance function> described above and displays the optimal route with good radio wave conditions on the display unit 8 on a map, the user If it is determined that the user does not move along the appropriate route and is moving on foot, the user etc. is good. It is determined that the movement in the desired direction is more important than the important radio wave condition, and the navigation processing is switched to the above-described ⁇ normal guidance function>.
- the guidance unit 6 The system automatically detects the moving state of the user, etc., and switches from the ⁇ communication guidance function> that presents an optimal route with good radio wave conditions to the navigation processing using the ⁇ normal guidance function>.
- the guidance unit 6 detects the current position of the user, which moves only momentarily by simply switching to the navigation processing by the ⁇ normal guidance function>, based on the position data Dps, and determines the surrounding area of the current position. Read the corresponding measured data Da and distribution data Db from the first and second field strength information files 10a and 10b. Then, an electric field intensity distribution in the above-mentioned surrounding area is created based on the read actual measurement data Da and the distribution data Db, and the electric field intensity distribution is displayed in a contour line, so that the radio wave condition is improved for the user and the like. May be presented.
- the guidance unit 6 continues the navigation process in the “communication guidance” operation mode by the above-described “map non-display function”, and determines the direction in which the user or the like should proceed from the current position in FIG. a)
- a user or the like is moving in a direction according to the picture mark M when the picture is displayed on only a part of the display screen by the picture mark M or the like illustrated in the example of the map mark M by the ⁇ map non-display function>.
- the navigation processing in the operation mode of “communication guidance” is continued. That is, even if it is determined that the user or the like is moving on foot, the guiding unit 6 considers a good radio wave condition as important if the user or the like is moving in the direction according to the picture mark M. It is determined that the user is moving toward the destination while watching, and the navigation process in the operation mode of “communication induction” is continued by the above-described “map non-display function”.
- the guidance unit 6 continues the navigation process in the “communication guidance” operation mode by the above-described ⁇ map non-display function>, and determines the direction in which the user or the like should proceed from the current position.
- the guidance unit 6 determines the direction in which the user or the like should proceed from the current position.
- the user etc. does not move in the direction according to the picture mark M and is moving on foot.
- the navigation processing is performed as described above in the “normal guidance”. Is switched to the navigation processing according to the operation mode.
- the guidance unit 6 automatically detects the moving state of the user or the like and switches to the navigation by the ⁇ normal guidance function>, so that guidance according to the actual moving state of the user or the like can be performed.
- the direction in which a good radio wave condition is obtained is continuously displayed by the electric field intensity distribution, so that the user or the like can use the telephone, mail communication, or the Internet. Able to provide excellent convenience when trying to communicate.
- the guiding unit 6 has a ⁇ field strength display function> as a fifth function.
- the guidance unit 6 displays “automatic electric field strength”.
- the display mode is set to the ⁇ display '' operation mode, and without performing navigation processing, a good mark of the radio wave condition is indicated by a picture mark M on a part of the display screen of the display unit 8 in the same manner as illustrated in FIG. indicate.
- the navigation unit 6 does not perform the navigation process, and the position information detection unit 3 instantaneously transmits the communication unit 4 as the communication operation starts.
- the output position data Dps the current position where the user or the like moves is detected, and the actual measurement data Da and distribution data Db corresponding to the area around the current position are converted to the first and second electric field strength information.
- an electric field strength distribution in the above-mentioned surrounding area is created based on the read actual measurement data Da and the distribution data Db, and further based on the electric field strength distribution, a direction that is closest to the current position and has the best radio wave condition. Is displayed only on a part of the display screen by the picture mark M.
- the guiding unit 6 determines the direction in which the radio wave condition becomes good, as shown in FIG.
- the image is displayed on only a part of the display screen of the display unit 8 by the various picture marks M shown in (d).
- a user or the like simply presents a favorable direction of a radio wave condition simply by making a telephone call, performing email communication, Internet communication, or the like.
- a good direction of the radio wave condition is presented according to the moving position of the user or the like, it is possible to guide the user or the like so that communication can be performed in a good communication state.
- the guiding unit 6 indicates a favorable direction of the radio wave condition based on the actual measurement data Da measured when the user or the like actually moves. Since the mark M is displayed, extremely reliable navigation information can be presented.
- the guiding unit 6 has a ⁇ field strength manual display function> as a sixth function. In addition to the user designating the navigation using the ⁇ communication guidance function>, operate the operation unit 11 with no telephone and no e-mail communication or Internet communication. When the instruction for detecting the position is made, the guiding unit 6 is set to the operation mode of the “electric field strength manual display”, and as shown in FIG. The direction of the good radio wave condition is displayed.
- the guiding unit 6 activates the position information detecting unit 3 and starts inputting the position data Dps. Then, based on the position data Dps supplied from time to time, the current position where the user or the like moves is detected, and the actual measurement data Da and distribution data Db corresponding to the area around the current position are first and second data. Read from the electric field strength information files 10a and 10b of 2. Further, an electric field strength distribution in the above-mentioned surrounding area is created from the read actual measurement data Da and the distribution data Db, and based on the electric field strength distribution, a direction that is closest to the current position and has the best radio wave condition is determined. , Is displayed on a part of the display screen by the picture mark M.
- the user and the like can know the direction in which the radio wave condition is good even when the communication is not in progress, so the radio wave condition is checked before starting communication. Communication can be started in a good place.
- the user or the like does not make a telephone call, does not perform e-mail communication, Internet communication, or the like. In both cases, the user presents a favorable direction of the radio wave condition according to the moving position of the user or the like. Before trying to instruct Yong, it is possible to quickly and surely know a place where a good communication state can be obtained, thereby providing excellent convenience.
- the mobile communication device 1 has a function of communicating with a short-range communication system laid in a building.
- a communication device conforming to the so-called Blue Tooth standard is laid on each floor in a building and the communication unit 4 communicates with the communication device on each floor. It detects the electric field strength of the radio wave arriving from the communication device, and supplies the electric field strength data Dep to the control unit 2. Then, the control unit 2 creates the actually measured data Da based on the electric field intensity data D mark and stores it in the first electric field intensity information file 10a.
- the guiding unit 6 causes the measurement data stored in the first field strength information file 10a to be stored. Based on the data Da, an electric field distribution of radio waves arriving from the communication device laid in the above-mentioned building, that is, a three-dimensional electric field intensity distribution is created, and the best radio waves close to the current position of the user etc. The direction in which the situation is obtained is detected based on the electric field intensity distribution, and is displayed on the display unit 8 with the picture mark M.
- the guiding unit 6 is shown in FIG. In this way, a pattern pattern M, in which a plurality of ellipses are added above the antenna pattern, is displayed on a part of the display screen.
- a pattern pattern M with multiple ellipses added below the antenna pattern is displayed on a part of the display screen.
- the guide unit 6 displays the favorable direction of the radio wave condition on the display unit 8 in various pattern patterns M, it is possible to present a guide display that is easy for the user and the like to understand.
- the mobile communication device 1 has a function of transmitting the electric field intensity data Dps at the current position actually measured by the electric field intensity measurement unit 5 from the communication unit 4 to the base station.
- the control unit 2 has a function of downloading the electric field intensity data, creating actual measurement data Da from the electric field intensity data, and storing the data Da in the first electric field intensity information file 10a.
- the mobile communication device 1 when a large number of owners transmit the electric field intensity data Dps at their current positions from the communication unit 4 to the base station, the mobile communication device 1 accumulates the electric field intensity data Dps and Has a function of creating a shared database and distributing the shared electric field strength data to the mobile communication device 1 of each owner.
- the guiding unit 6 uses the shared actual measurement data Da stored in the first electric field strength information file 10a. An electric field strength distribution is created, and a favorable direction of the radio wave condition is displayed on the display unit 8.
- the controller 2 creates the data based on the electric field intensity data Dep output from the electric field intensity measuring unit 5 and deletes the measured data Da stored in the first electric field intensity information file 10a in the order of the oldest data. ⁇ Measured data timeout function> is provided.
- the control unit 2 creates the actual measurement data Da based on the electric field intensity data D output from the electric field intensity measurement unit 5 as described above, the electric field intensity data D and the position information detection
- the actual measurement data Da is generated by combining the three data of the position data Dps output from the unit 3 and the time data Dtm output from the clock circuit power provided in the control unit 2. And stores it in the first electric field strength information file 10a.
- control unit 2 checks the time data Dtm of each measured data Da stored in the first electric field strength information file 10a, and deletes the data from the oldest measured data Da in order, thereby reducing the storage capacity of the storage unit 7. Within the range, new measured data Da is secured in the first electric field strength information file 1 Oa.
- the latest measured data Da can be stored by effectively using the storage unit 7 having a limited storage capacity. It is possible to create a high-level and electric-field-intensity distribution, and to present highly reliable guidance information to a user or the like.
- the guiding unit 6 operates while the above-described ⁇ moving priority automatic switching function>, ⁇ field strength automatic display function>, ⁇ field strength manual display function>, etc. are operating.
- the electric field intensity is created based on the actually measured data Da stored in the first electric field intensity information file 10a, it is possible to provide guidance information that is extremely reliable and highly convenient.
- the guiding unit 6 creates the electric field intensity distribution, it becomes possible to create a high-density electric field intensity distribution, and the radio wave condition is changed for every slight moving distance of the user or the like. It is possible to present the good direction of the vehicle by the picture mark M or the like, so that the user or the like can immediately know the place where the radio wave condition is good by looking at the picture mark M or the like.
- the ⁇ measured data timeout function> particularly when a user or the like moves in a relatively small area, it is possible to provide highly reliable and highly convenient guidance information.
- FIG. 5 is a flowchart showing the navigation operation by the ⁇ communication guidance function> and the ⁇ normal guidance function>
- FIG. 6 is a flowchart showing the operation when the guidance unit 6 creates the electric field intensity distribution
- FIG. 7 is a flowchart showing the operation of the guidance unit 6 by the ⁇ moving priority automatic switching function>.
- the user or the like operates the operation unit 11 to specify a desired condition (for example, a shortest distance, a shortest time, or the like) and give an instruction to start navigation.
- the guidance unit 6 starts the navigation processing.
- step S1 the guidance unit 6 determines whether navigation by ⁇ communication guidance function> is designated by the user or the like, and if so, the process proceeds to step S2, and the communication guidance function is performed.
- the navigation processing according to ⁇ > is started.
- step S3 it is determined whether the user or the like has reached the destination, and the processing of steps S1 to S3 is repeated until the user or the like reaches the destination.
- step S3 when it is determined that the user or the like has reached the destination, the navigation processing by the ⁇ communication guiding function> is terminated.
- the guidance unit 6 performs the navigation processing by the ⁇ communication guidance function> according to the instruction. Do.
- step S1 when the guiding unit 6 determines that the navigation by the ⁇ communication guiding function> is not specified, the process proceeds to step S4 to determine whether the communication unit 4 is in a communication state. Determine whether or not. If the communication is being performed, the process proceeds to step S5, and the guiding unit 6 automatically starts the navigation processing by the ⁇ communication guiding function>. Then, in step S3, when it is determined that the user or the like has reached the destination, the guiding unit 6 sets the ⁇ communication guiding function>. The navigation processing according to the above is terminated.
- step S4 if the guiding unit 6 determines that the communication unit 4 is not in a communication state, the process proceeds to step S6, and the navigation processing by the ⁇ normal guidance function> is automatically started. I do. Then, in step S3, when it is determined that the user or the like has reached the destination, the guidance unit 6 ends the navigation processing by the ⁇ normal guidance function>.
- the navigation processing by the ⁇ communication guidance function> is automatically performed. If the user specifies navigation start and does not make a phone call, does not perform e-mail communication, Internet communication, etc., the navigation processing is automatically performed by the ⁇ normal guidance function>. It is possible to provide excellent operability to users and the like.
- step S10 when the guiding unit 6 creates an electric field distribution, first, in step S10, it is checked whether or not actually measured data exists in the first electric field intensity information file 10a. For example, the process proceeds to step S11, and it is further checked whether or not there is actually measured data Da measured within a predetermined time. That is, if the electric field intensity distribution is created based on the old actual measurement data, the electric field intensity distribution becomes unreliable.Therefore, in step S11, it is further checked whether the actual measurement data Da actually measured within a predetermined time exists. .
- step S12 If there is actual measurement data Da actually measured within the predetermined time, the process proceeds to step S12, where the actual measurement data Da actually measured within the predetermined time is preferentially used, and the second The distribution data Dm stored in the electric field intensity information file 10b is used as a complement, and an electric field intensity distribution is created based on the measured data Da and the distribution data Dm, and the electric field intensity distribution creation processing ends. .
- step S10 or S11 described above when the guiding unit 6 determines that the measured data does not exist or the measured data Da measured within a predetermined time does not exist, the process proceeds to step S13. Then, it is checked whether distribution data exists in the second electric field strength information file 10b. Then, if the distribution data Db exists, the guiding unit 6 proceeds to step S14, creates an electric field intensity distribution based on the distribution data Db, and completes the electric field intensity distribution creation processing. To end. [0115] As described above, the guiding unit 6 gives the user or the like a favorable direction of the radio wave condition by creating the electric field intensity distribution by giving priority to the latest measured data Da and complementing the distribution data Db. In this case, highly reliable guidance information can be presented.
- the guidance unit 6 performs navigation processing by the ⁇ communication guidance function> in accordance with the instruction of the user or the like.
- step S20 the optimal route is presented to the user or the like.
- step S21 the force by which the user or the like has moved according to the presentation is checked.
- step S21 the force by which the user or the like has moved according to the presentation is checked.
- step S21 the navigation processing by the ⁇ communication guiding function> is continued, and when the user or the like reaches the destination, the navigation processing ends.
- step S21 the process proceeds to step S23, and the guiding unit 6 automatically performs the navigation processing by the ⁇ normal guidance function>. And when the user reaches the destination, the navigation processing ends.
- the guiding unit 6 provides the user and the like with excellent convenience by performing the navigation process in accordance with the actual moving situation of the user and the like.
- a user or the like is guided by the various functions described above, and therefore, excellent convenience can be provided to the user and the like.
- the measured data Da is stored in the first field strength information file 10a, an electric field strength distribution is created based on the measured data Da, and the optimal distance to the destination is determined based on the created field strength distribution. Since it searches for a route or presents a direction with good radio wave conditions, highly reliable guidance information based on the latest information can be presented to users and the like.
- the direction in which the favorable direction of the radio wave condition is presented by the pattern mark M is good depending on other presentation methods.
- a vibrating element may be provided in the housing of the mobile communication device 1, and the vibration mode of the vibrating element may be changed so that a favorable direction of the radio wave condition is presented by vibration.
- one or a plurality of color light emitting elements that change to a different color is provided at one end of the housing of the mobile communication device 1, and by changing the emission color of these color light emitting elements, A good direction of the radio wave condition may be presented.
- the mobile communication device 1 as a mobile phone has been described, the mobile communication device 1 of the present embodiment can also be applied to a so-called in-vehicle navigation device having a wireless communication function.
- control unit 2 constituting the mobile communication device 1, the position information detection unit 3, the communication unit 4, the electric field strength measurement unit 5, the guidance unit 6, and the storage unit 7 are implemented by computer programs. It can also be realized by a microprocessor (MPU) that executes. That is, a microprocessor (MPU) is caused to execute a computer program for performing the functions of the control unit 2, the position information detection unit 3, the communication unit 4, the electric field strength measurement unit 5, the guidance unit 6, and the storage unit 7.
- the navigation by various functions such as the above-mentioned ⁇ communication guidance function> and ⁇ electric field strength automatic display function) may be performed by the microprocessor.
- a computer program for causing the microprocessor (MPU) to perform the functions of the control unit 2, the position information detection unit 3, the communication unit 4, the electric field strength measurement unit 5, the guidance unit 6, and the storage unit 7 is provided on a CD.
- a computer program stored in the storage medium such as a DVD or a DVD, and the computer program stored in the storage medium is executed by the microprocessor (MPU). Navigation using the various functions described above may be performed.
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- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Automation & Control Theory (AREA)
- Navigation (AREA)
- Traffic Control Systems (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
Description
Claims
Priority Applications (2)
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EP05721250A EP1732341A1 (en) | 2004-03-25 | 2005-03-22 | Communication device, guide method, guide processing program, and recording medium |
JP2006511462A JPWO2005094110A1 (ja) | 2004-03-25 | 2005-03-22 | 通信装置、誘導方法、誘導処理用プログラム、及び記録媒体 |
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JP2004089333 | 2004-03-25 | ||
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WO2005094110A1 true WO2005094110A1 (ja) | 2005-10-06 |
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PCT/JP2005/005150 WO2005094110A1 (ja) | 2004-03-25 | 2005-03-22 | 通信装置、誘導方法、誘導処理用プログラム、及び記録媒体 |
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EP (1) | EP1732341A1 (ja) |
JP (1) | JPWO2005094110A1 (ja) |
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US11075704B2 (en) | 2017-06-28 | 2021-07-27 | Panasonic Intellectual Property Management Co., Ltd. | Radio wave environment display device and method for displaying radio wave environment |
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JPWO2005094110A1 (ja) | 2008-02-14 |
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