KR20140021757A - Gps terminal comprising solar cell - Google Patents

Abstract

Disclosed is a Global Positioning System (GPS) terminal using a solar cell of which it uses the solar cell to charge the battery which can lead to increase the available time of the battery as well as efficiently manage the power in various circumstances of applied solar cell. The GPS terminal using the solar cell comprises a solar cell, a battery which can be charged, a charging circuit which can transfer the power generated from the solar cell to the pre-set voltage to the battery to charge it, a GPS signal processing unit which processes the received GPS signal from a GPS antenna to generate location information, and a main control unit that monitors the voltage outputted from the solar cell and controls the charging of the battery according to the outputted voltage from the solar cell to control the battery circuit. [Reference numerals] (15) Solar cell; (21) Main control unit; (23) Charging circuit; (25) Battery; (27) GPS signal processing unit; (29) Wireless lan signal processing unit; (31) Location information storage unit; (33) Display panel

Description

GPS TERMINAL COMPRISING SOLAR CELL "

[0001] The present invention relates to a solar cell terminal employing a solar cell, and more particularly, to a solar cell terminal which can increase the usable time of a battery by charging a battery by applying a solar cell, and efficiently manage power in various environments using a solar cell A solar cell to which the solar cell is applied.

In general, a Global Positioning System (GPS) is a satellite navigation system designed to receive a satellite-based position information from a plurality of satellites in a fixed orbit around the earth. to be.

A satellite positioned above the earth broadcasts a GS signal including its own celestial body position and system time while revolving around the earth along a predetermined orbit, and the GS receiver receives the relative arrival of the GS signals transmitted simultaneously from at least four satellites The time is calculated to determine the exact time and location.

 Recently, personal mobile communication has developed remarkably, and there is a tendency to provide a variety of location information related services to portable terminals by installing a GPS system in the portable terminal. In addition to these personal service areas, ZPTS is also being used to provide location-related information in key industry key areas that form the basis of society, such as aerospace, marine, medical and military.

On the other hand, ZPES can be applied to prevent the occurrence of lost or missing persons in advance by detecting the location of a child or an elderly person with dementia. In this case, the power of the GPS receiver needs to be maintained for a very long time, and it is necessary for the GPS receiver to transmit the position information received from the satellite using other communication means so that the guardian can grasp the position of the GPS receiver. That is, a long-time power supply and transmission of location information are indispensable for a GPS terminal applied to a location-based service provided to prevent a missing person or a demented elderly from missing.

The present invention provides a solar cell terminal employing a solar cell capable of increasing the usable time of a battery by charging a battery by applying a solar cell and efficiently managing power in various environments using the solar cell This is a technical problem to be solved.

According to an aspect of the present invention,

Solar cell;

Rechargeable battery;

A charging circuit for converting the electric power generated by the solar cell into a predetermined voltage and providing the battery with the predetermined voltage to charge the battery;

A GPS signal processing unit for processing the GPS signal received from the GPS antenna to generate position information; And

A main controller for monitoring a voltage output from the solar cell and controlling the charging circuit by controlling the charging circuit according to a voltage output from the solar cell,

The present invention provides a solar cell terminal employing a solar cell.

In one embodiment of the present invention, the paper feed signal processing unit may control to periodically repeat the paper feed signal receiving mode for generating the position information by receiving the paper feed signal and the maximum power saving mode for not receiving the paper feed signal.

In one embodiment of the present invention, the main control unit, when the position information generated by the GPS signal processing unit exists in a preset area, the GPS signal processing unit at the first duty ratio, the GPS signal receiving mode and the maximum power saving The GPS signal processor is set to repeat a mode, and when the position information generated by the GPS signal processor is out of the preset area, the GPS signal processor is further configured to receive the GPS signal receiving mode rather than the first duty ratio. The GPS signal processing unit may be configured to repeat the GPS signal receiving mode and the hibernate mode at a second duty ratio having increased time.

In one embodiment of the present invention, the main controller can monitor the voltage of the battery. When the voltage of the battery is lower than a predetermined reference voltage and the battery is not charged by the solar cell, the main processor may cause the paper dust sensor signal processing unit to generate the paper dust sensor signal by the first duty ratio, And to set the laser signal processing unit to repeat the hibernation mode. When the voltage of the battery is lower than the reference voltage and the battery is charged by the solar cell, the main control unit may control the main signal processing unit such that the power source signal processing unit increases the time of the power- 2 < / RTI > duty ratio and the hibernation mode. When the battery voltage is higher than the reference voltage and the battery is not charged by the solar cell, the main control unit may increase the time of the GPS signal receiving mode by more than the first duty ratio And the paper feed signal processing unit may be set to repeat the paper feed signal reception mode and the maximum power saving mode with a third duty ratio. When the voltage of the battery is higher than the reference voltage and the battery is charged by the solar cell, the main control unit may cause the paper dust sensor signal processing unit to switch the paper dust sensor signal reception mode And the power saving signal processing unit may be set to repeat the power saving signal receiving mode and the maximum power saving mode with a fourth duty ratio which is an increase time of the power saving signal.

One embodiment of the present invention may further include a position information storage unit for cumulatively storing the position information generated by the laser signal processing unit.

One embodiment of the present invention may further include a wireless LAN signal processing unit for periodically transmitting location information accumulated in the location information storage unit to an access point capable of communicating.

In an embodiment of the present invention, when the wireless LAN signal processing unit newly accesses an access point capable of communicating in a state where there is no communicable access point, the wireless LAN signal processing unit newly accesses the location information accumulated and stored in the location information storage unit It can be immediately transmitted to the access point.

In one embodiment of the present invention, the main control unit is a position where the WLAN signal processing unit accumulates and stored in the location information storage unit at a first period when the location information generated by the GPS signal processing unit exists within a preset area. The WLAN signal processor is configured to transmit information to an access point, and when the location information generated by the GPS signal processor leaves the preset area, the WLAN signal processor is shorter than the first period. The WLAN signal processor may be configured to transmit the accumulated location information stored in the location information storage unit to the access point at a second cycle.

According to the present invention, the use of a solar cell as an auxiliary power source allows the battery of the GPS terminal to be charged from time to time, thereby increasing the usable time of the GPS terminal.

In addition, according to the present invention, the operation of the GPS signal processing unit is divided into the GFS signal receiving mode and the Hibernation mode, and the two modes are periodically repeated, thereby reducing the power consumption and further increasing the usable time of the GPS terminal .

In addition, according to the present invention, in consideration of the case where the GPS signal is applied to prevent or prevent the elderly from dementing, it is possible to use a duty cycle divided into a GPS signal receiving mode and a hibernation mode according to the position of the GPS terminal and the battery state of the GPS terminal It is possible to optimize the power consumption of the GPS terminal and adjust the position of the GPS terminal more efficiently by adjusting the operating duty ratio of the operating GPS signal processor appropriately.

In addition, according to the present invention, location information stored in a GPS terminal using a wireless LAN access point in the vicinity of a GPS terminal can be transmitted using the Internet, thereby enabling a third party to more easily grasp the position of the GPS terminal.

In addition, according to the present invention, it is possible to optimize the power consumption of the GPS terminal by appropriately adjusting the period in which the wireless LAN signal processing unit in the GPS terminal transmits the position information through the access point according to the position of the GPS terminal, The position of the terminal can be grasped.

FIG. 1 is a perspective view showing an appearance of a solar cell terminal using a solar cell according to an embodiment of the present invention. FIG.
FIG. 2 is a block diagram illustrating a solar cell terminal employing a solar cell according to an embodiment of the present invention. Referring to FIG.
3 is a graph for explaining the operation of the solar cell terminal using the solar cell according to one embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. In addition, in describing the present invention, the defined terms are defined in consideration of the functions of the present invention, and they may be changed depending on the intention or custom of the technician working in the field, so that the technical components of the present invention are limited It will not be understood as meaning.

FIG. 1 is a perspective view showing an appearance of a solar cell terminal using a solar cell according to an embodiment of the present invention. FIG. Particularly, FIG. 1 (a) is a perspective view showing a front surface of a solar cell terminal to which a solar cell according to an embodiment of the present invention is applied, FIG. 1 (b) Fig. 3 is a perspective view showing a rear surface of the GPS terminal.

As shown in FIG. 1 (a), a GPS satellite terminal 10 to which a solar cell according to an embodiment of the present invention is applied includes a display panel 13 for displaying position information and the like on the front surface thereof, The display panel 13 and the buttons 14 may be fixed to the case 12. [ In addition, a button 14 for operation may be further provided on the side surface of the case 12. [

1 (b), a solar cell 10 to which a solar cell according to an embodiment of the present invention is applied may be provided with a solar cell 15 fixed to the case 12 on the rear surface thereof have. The solar cell 10 using the solar cell according to the embodiment of the present invention can generate electric power by exposing the solar cell 15 provided on the rear surface to light.

FIG. 2 is a block diagram illustrating a solar cell terminal employing a solar cell according to an embodiment of the present invention. Referring to FIG.

2, a solar power terminal employing a solar cell according to an embodiment of the present invention includes a solar cell 15, a battery 25, a charging circuit 23, a GPS signal processing unit 27, (21). ≪ / RTI >

In addition, a GPS terminal to which a solar cell according to an embodiment of the present invention is applied may include a location information storage unit 31, a wireless LAN signal processing unit 29, and a display panel 33.

The solar cell 15 may be a variety of solar cells well known in the art as an element for receiving light and generating electrical energy, that is, electric power. For example, as described in Korean Patent No. 10-1101334 (name: a solar cell having a storage device and a manufacturing method thereof), which is a patentee of the Korea Ceramic Technology Institute, a solar cell provided with a storage device May be applied to one embodiment. In the solar cell according to the patent, the power storage device is added to the solar cell itself to smoothly maintain the output performance of the solar cell, and there is no need to separately provide a power storage device for storing electric power.

The battery 25 is a rechargeable battery that can be charged by a charger using a conventional commercial power source or can be charged with electric power produced by the solar cell 15. [

The charging circuit 23 is a circuit for charging the battery 25 by transmitting the electric power produced and output from the solar cell 15 to the battery 25. [ The charging circuit 23 maintains the voltage output from the solar cell 15 at the input rated voltage of the battery for charging and the output voltage of the solar cell 15 is significantly lower than the input rated voltage of the battery, The electrical connection between the solar cell 15 and the battery 25 can be cut off.

The GPS signal processing unit 27 receives the GPS signals of the GPS satellites received by the GPS satellites and can receive position information included in the GPS signals through various signal processes. For example, the GPS signal processing unit 27 blocks signals in the remaining frequency bands except the signal of the 1.575 GHz band, which is the frequency band of the GPS signal, from the high frequency signal received by the GPS antenna, and outputs the high frequency signal of the G / And an RF front end module (not shown) for converting an RF signal in a frequency band of a low frequency band into an intermediate frequency through down conversion and sampling the converted intermediate frequency signal to convert the RF signal into a digital signal, A correlation output is obtained by removing the error due to the Doppler effect in a signal output from the RF front end module, using a pseudo random noise (PRN) code, integrating and outputting the correlation result, The final result of the integration is used to determine and output the final GSPS information. It may be an element comprising a base band processing and so on.

In particular, as described in Korean Patent No. 10-1062761 (entitled: Portable DGPS terminal device) filed by the applicant of the present application and registered as a patent, the GPS signal processing section 27 receives a GPS correction signal provided by the Ministry of Land, Transport and Maritime Affairs And can be an element capable of DGPS (Differential Global Positioning System) signal processing with more precise positional accuracy.

In one embodiment of the present invention, the GFS signal processing unit 27 may be divided into a GFS signal receiving mode in which power consumption is high and a Hibernation mode in which power consumption is minimized. The time period during which each of the GPS signal receiving mode and the hibernation mode is performed within one duty cycle can be determined as a duty ratio, and the duty ratio can be appropriately changed according to the position of the GPS terminal and the battery state of the GPS terminal.

The main control unit 21 is an element for controlling overall power and signal flow between components of the solar cell terminal using the solar cell according to an embodiment of the present invention. The main control unit 21 monitors the voltage output from the solar cell 15 and controls the charging circuit 23 according to the voltage output from the solar cell 15 to control whether the battery is charged. The voltage output from the solar cell 15 can be changed according to the amount of light incident on the solar cell. As described above, the charging circuit 23 supplies the voltage output from the solar cell 15 to the input rated voltage of the battery for charging when a sufficient voltage for charging the battery 25 is input from the solar cell 15 The electric connection between the solar cell 15 and the battery 25 can be cut off when the output voltage of the solar cell 15 is significantly lower than the input rated voltage of the battery and the charging can not be performed. The operation of the charging circuit 23 can be performed by controlling the main controller 21 that monitors the output voltage of the solar cell 15. That is, the main control unit 21 monitors the output voltage of the solar cell 15, and when the output voltage of the solar cell 15 is larger than a predetermined reference voltage for determining whether the battery 25 is charged or not, 23 may be activated so that the battery 25 can be charged. When the output voltage of the monitored solar cell 15 is lower than the reference voltage, the main control unit 21 deactivates the operation of the charging circuit 23 to block the electrical connection between the solar cell 15 and the battery 25 .

The main control unit 21 can set the operation of the GPS signal processing unit 27 according to the position information received by the GPS signal processing unit 27 or the state of charge of the battery 25. [ The setting operation of the main control section 21 will be described later in more detail.

The position information storage unit 31 may store the position information output from the GPS signal processing unit 27 in a cumulative manner. The positional information storage unit 31 may accumulate positional information periodically output from the GPS signal processing unit 27 on a time-by-time basis and convert it into a database.

The wireless LAN signal processing unit 29 can communicate with an access point (AP) located around the GFP terminal in a wireless LAN (Wi-Fi) manner. The wireless LAN signal processing unit 29 may scan the access point around the wireless LAN terminal and maintain a connection state with the access point capable of communicating therewith, and may periodically transmit the location information stored in the location information storage unit 31 to the access point And can be transmitted in a wireless LAN system. The location information transmitted in the wireless LAN mode can be transmitted to the management server for tracking the user location or the guardian of the GFP terminal holder so as to confirm the location of the GFP terminal in real time. The periodic operation of the wireless LAN signal processing unit 29 may be set by the main control unit 21. [

The display panel 33 can be controlled by the main control unit 21 and can control the current position, the reception state of the GPS satellite, the moving speed, etc. according to the user input by the button provided on the GPS terminal and the control of the main control unit 21 Can be visually displayed.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the operation and effect of a solar cell terminal employing a solar cell according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The solar cell terminal employing the solar cell according to the embodiment of the present invention can employ the solar cell 15 as an auxiliary power source to charge the battery from time to time to increase the usable time of the GPS terminal. In addition to the time-saving technique for extending the available time of the solar cell terminal using such a solar cell, the operation of the GPS signal processor 27 may be realized by a power saving mode in which power consumption is high and a maximum power saving mode And repeating the two modes periodically, it is possible to further extend the available time of the GPS terminal.

3 is a graph for explaining the operation of the solar cell terminal using the solar cell according to one embodiment of the present invention.

As shown in Fig. 3, the paper feed signal processing unit 27 can operate to periodically repeat the paper feed signal receiving mode (A) and the maximum power saving mode (B).

The GPS signal reception mode (A) is a mode for receiving a GPS signal from the GPS satellite and processing the GPS signal to generate position information and outputting the generated position information. In the GA signal reception mode (A), it is possible to receive signals from other external elements and output signals to other external elements. In other words, the GFS signal receiving mode (A) is a mode in which all operations of the GFS signal processing unit 27 are normally performed. Therefore, the power consumption is relatively larger in the GFS signal receiving mode (A).

In the hibernation mode (B), power is turned off for the remaining elements except the essential elements for resuming the operation of the next paper feed signal reception mode (A) in the paper feed signal processing unit (27). In the hibernation mode (B), it is a mode that does not receive a GSIS signal from the GSIS satellite or output data to other elements in the GSIS terminal, and does not receive an instruction, etc., and is a mode capable of consuming at least about 1 mA in power consumption.

As described above, in the embodiment of the present invention, in addition to the frequent charging function of the battery through the solar cell, by causing the GPS signal processing unit 27 to repeatedly operate the GPS signal receiving mode (A) and the maximum power saving mode (B) It is possible to maximize the available time of the GPS terminal.

On the other hand, as shown in Fig. 3, the paper dust signal reception mode A and the maximum power saving mode B of the paper dust signal processing unit 27 can be repeatedly operated in one duty cycle C. In the embodiment of the present invention, the main control section 21 controls the operation of each of the above-described embodiments by adjusting the time at which each mode is executed in the duty cycle of the mode operation of the GSPS signal processing section 27, .

The mode operation duty ratio setting of the GPS signal processing unit 27 in the main control unit 21 can be performed according to the current position of the GPS terminal and the battery state of the GPS terminal. Table 1 below

An example of setting the mode operation duty ratio of the GPS signal processing unit 27 performed by the main control unit 21 according to the current position of the GPS terminal and the battery state of the GPS terminal is shown.

Duty setting criteria Gypsy terminal status Setting Duty Remarks Location Within preset areas The first duty The first duty ratio reception signal mode of the first duty ratio < the second duty ratio reception signal mode Exit preset area Second duty Battery charge status Battery Low / Charging The first duty The first and second duty ratios of the first and second duty ratios < the second duty ratio and the third duty ratio,
The second duty ratio and the third duty ratio of the fourth duty ratio reception mode <the fourth duty ratio of the ground signal reception mode Battery LOW / Charging Oil Second duty Battery HIGH / No charge Third duty Battery HIGH / Charging Oil Fourth duty

First, referring to the example of the duty ratio setting according to the position of the GPS terminal, as shown in Table 1, the main control unit 21 is the position information generated by the GPS signal processing unit 27, that is, the position of the GPS terminal in advance When present in the setting area, the GS signal processing unit 27 may set the GS signal processing unit to repeat the GS signal receiving mode A and the hibernation mode B at the first duty ratio. In addition, the main control unit 21 is the position information generated by the GS signal processing unit 27, that is, when the position of the GPS terminal is out of the preset area, the GS signal processing unit 27 receives the GS signal rather than the first duty ratio The GS signal processor 27 may be set to repeat the GS signal receiving mode A and the hibernation mode B with the second duty ratio of increasing the time of the mode A. FIG.

Such a duty ratio setting takes into consideration the case where the GFP terminal according to the embodiment of the present invention is applied to the position confirmation of a child or a demented elderly person. It is preferable that a specific region is set in advance in the main controller 21 in the GFP server, In the presence of the GPS terminal, the GPS signal processing unit 27 is operated so that the GPS signal processing unit 27 operates at a relatively low first duty ratio, and when the GPS terminal is out of the set area, it is determined as an emergency state, It is possible to operate the GPS signal processing unit 27 such that the GPS signal reception mode is relatively long and the second duty ratio is relatively long so as to obtain the information.

Next, as shown in Table 1, the main control unit 21 monitors the voltage of the battery 25 and the voltage of the solar cell 15 to set the duty ratio according to the battery state of the GPS terminal, The duty ratio can be set according to the state of charge of the battery and whether or not it is charged by the solar cell.

More specifically, when the voltage of the battery 25 is lower than a predetermined reference voltage and the battery 25 is not charged by the solar cell 15, the main control unit 21 outputs a signal The GPS signal processing unit 27 is set to repeat the GPS signal receiving mode and the maximum power saving mode with the first duty ratio and the voltage of the battery 25 is lower than the reference voltage and the battery 25 is charged The dust signal signal processing unit 27 repeats the paper dust signal reception mode A and the maximum power saving mode B with a second duty ratio that increases the time of the dust signal reception mode A than the first duty ratio The DSP signal processing unit 17 can be set.

When the voltage of the battery 25 is higher than the reference voltage and the battery is not charged by the solar cell 15, the main control unit 21 controls the laser signal processing unit 27 so that the laser- The gyphase signal processing unit 27 is set so as to repeat the gyphosphate signal receiving mode A and the maximum power saving mode B with the third duty ratio in which the time of the mode A is increased and the voltage of the battery 25 is higher than the reference voltage When the battery 15 is charged by the solar cell 15 and the battery 15 is charged by the solar cell 15, the dust signal processing unit 27 generates the fourth duty ratio that increases the time of the dust signal receiving mode A It is possible to set the paper dust signal processing section 27 to repeat the paper dust signal receiving mode (A) and the maximum power saving mode (B).

Through the setting of the duty ratio, the GFP terminal according to the embodiment of the present invention can further reduce the time of the GFP signal receiving mode and increase the usable time of the GFP terminal as the battery becomes closer to the full discharge.

Meanwhile, the GFP terminal according to an embodiment of the present invention can appropriately control the operation of the wireless LAN signal processing unit 29 and manage the location information of the GFP terminal.

For example, the wireless LAN signal processing unit 29 of the GFP terminal according to an embodiment of the present invention may periodically transmit location information accumulated in the location information storage unit 31 to an access point capable of communicating. On the other hand, when the wireless LAN signal processing unit 29 newly accesses the access point capable of communicating in a state in which there is no access point capable of communicating, regardless of the predetermined transmission period, the wireless LAN signal processing unit 29 transmits the location information accumulated in the location information storage unit It is immediately transmitted to the newly accessed access point so that the location of the GPS terminal can be grasped by the third party.

In addition, the location information transmission period of the wireless LAN signal processing unit 29 can be appropriately set by the main control unit 21 according to the location of the GPS terminal. For example, when the location information generated by the GPS signal processing unit 27 exists in the preset area, the main control unit 21 may perform the location information storage unit 31 at the first cycle of the WLAN signal processing unit 29. The WLAN signal processor 29 is configured to transmit the accumulated location information to the access point, and the WLAN signal processor 29 when the location information generated by the GPS signal processor 27 leaves the preset area. The WLAN signal processor 29 may be configured to transmit the location information accumulated in the location information storage unit 31 to the access point in a second period shorter than the first period.

The location information transmission period setting of the wireless LAN signal processing unit 29 takes into consideration the case where the GFP terminal according to an embodiment of the present invention is applied to the location confirmation of a child or a demented elderly person. The wireless LAN signal processing unit 29 is operated to transmit the position information in a relatively longer period when the specific area is set in the specific area, and when the area is out of the set area, the wireless LAN signal processing unit 29 is judged to be in an emergency state So that the wireless LAN signal processing unit 29 can operate at a relatively shorter period so that more position information can be transmitted to a third party more frequently.

As described above, the embodiment of the present invention can increase the usable time of the GPS terminal by allowing the battery of the GPS terminal to be charged from time to time by employing the solar battery as the auxiliary power source.

In addition, an embodiment of the present invention divides the operation of the GPS signal processing unit into the GPS signal receiving mode and the maximum power saving mode, and repeats the two modes periodically, thereby reducing power consumption and further increasing the available time of the GPS terminal .

In addition, one embodiment of the present invention may be divided into a GPS signal reception mode and a maximum power saving mode depending on the position of the GPS headset or the battery state of the GPS headset, It is possible to optimize the power consumption of the GPS terminal and to more effectively grasp the position of the GPS terminal by adjusting the operation duty ratio of the GPS signal processor to a predetermined duty cycle.

In addition, according to an embodiment of the present invention, location information stored in a GPS terminal using a wireless LAN access point in the vicinity of a GPS terminal can be transmitted using the Internet, so that a third party can more easily grasp the position of the GPS terminal have.

According to an embodiment of the present invention, the power consumption of the GPS terminal is optimized by appropriately adjusting the period in which the wireless LAN signal processing unit in the GPS terminal transmits the position information through the access point, according to the position of the GPS terminal, It is possible to efficiently grasp the position of the GPS terminal.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be determined by the scope of the following claims and equivalents thereof.

10: GASPS terminal 15: Solar cell
21: main control unit 23: charging circuit
25: Battery 27:
29: Wireless LAN signal processing unit 31: Position information storage unit

Claims (8)

Solar cell;
Rechargeable battery;
A charging circuit for converting the electric power generated by the solar cell into a predetermined voltage and providing the battery with the predetermined voltage to charge the battery;
A GPS signal processor for generating location information by processing a GPS signal received from a GPS antenna; And
Main control unit for monitoring the voltage output from the solar cell, controlling the charging circuit according to the voltage output from the solar cell to control whether the battery is charged
GPS terminal applying a solar cell comprising a. The method of claim 1, wherein the GPS signal processing unit,
The GPS terminal to which the solar cell is applied comprises controlling the GPS signal reception mode for generating position information by receiving the GPS signal and a hibernation mode in which the GPS signal is not received.
The method of claim 2, wherein the main control unit,
If the position information generated by the GS signal processing unit exists in a preset area, the GS signal processing unit sets the GS signal processing unit to repeat the GS signal receiving mode and the hibernation mode at a first duty ratio,
When the position information generated by the GPS signal processing unit leaves the preset area, the GPS signal processing unit receives the GPS signal at a second duty ratio in which the time of the GPS signal receiving mode is increased from the first duty ratio. And a GPS signal processor configured to repeat a mode and the hibernation mode. 3. The method of claim 2,
The main control unit monitors the voltage of the battery,
If the voltage of the battery is lower than a predetermined reference voltage and the battery is not charged by the solar cell, the GPS signal processor is configured to repeat the GPS signal receiving mode and the hibernation mode at a first duty ratio. To set up the signal processor,
When the voltage of the battery is lower than the reference voltage and the battery is charged by the solar cell, the GPS signal processor has the second duty ratio at which the time of the GPS signal receiving mode is increased from the first duty ratio. Setting the GPS signal processor to repeat the reception mode and the hibernation mode;
When the voltage of the battery is higher than the reference voltage and the battery is not charged by the solar cell, the GS signal processing unit uses the third duty ratio to increase the time of the GS signal receiving mode rather than the first duty ratio. Setting the GPS signal processing unit to repeat the GS signal receiving mode and the hibernate mode;
When the voltage of the battery is higher than the reference voltage and the battery is charged by the solar cell, the GPS signal processor is further configured to increase the time of the GPS signal receiving mode from the second duty ratio and the third duty ratio. And a GPS signal processor configured to repeat the GPS signal reception mode and the hibernation mode at a duty ratio. 5. The method according to any one of claims 1 to 4,
Further comprising: a position information storage unit for cumulatively storing the position information generated by the laser signal processing unit. The method of claim 5,
Further comprising a wireless LAN signal processing unit for periodically transmitting location information accumulated in the location information storage unit to an access point capable of communicating with the wireless LAN signal processing unit. The wireless LAN signal processing unit according to claim 6,
And immediately transmits the location information stored in the location information storage unit to the newly accessed access point when a new access is made to the access point capable of communicating in the absence of the communicable access point. terminal. 7. The apparatus according to claim 6,
If the location information generated by the GPS signal processing unit exists in a preset area, the WLAN signal processing unit transmits the location information accumulated and stored in the location information storage unit to the access point at a first period. To set the
When the position information generated by the GPS signal processing unit is deviated from the preset area, the wireless LAN signal processing unit transmits position information accumulated in the position information storage unit at a second period shorter than the first period, And the wireless LAN signal processing unit is configured to transmit the wireless LAN signal to the wireless LAN signal processing unit.

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