KR100935314B1 - Low power position measuring system - Google Patents

Abstract

The present invention relates to a positioning system for reducing the current consumption of the auxiliary power supply when the main power supply is cut off.

A low power positioning system according to the present invention includes a first regulator receiving a main voltage and outputting a plurality of driving voltages; An auxiliary power supply configured to charge the main voltage and output a charged voltage; A second regulator receiving the voltage supplied from the main voltage or the auxiliary power supply unit and supplying a predetermined magnitude of the RTC driving voltage; A reset voltage output unit including a third regulator and receiving one of a plurality of driving voltages output from the first regulator and outputting a reset voltage to the third regulator; And a central processor configured to measure a current position and measure a time by receiving the RTC driving voltage, thereby increasing the usage time of the auxiliary power by reducing current consumption of the auxiliary power.

Positioning, GPS, TTFF (Time to First Fix), Real Time Clock (RTC), low power

Description

Low power position measuring system

The present invention relates to a positioning system for reducing power consumption, and more particularly, by connecting a reset voltage output unit generating a reset voltage to a regulator that is driven when a main voltage is applied and outputs a plurality of driving voltages. The present invention relates to a low power positioning system that can reduce consumption.

In general, in order to drive to a destination by driving a car, the driver must know the road to be normally driven or drive by referring to a traffic guide atlas or road traffic sign. However, it is very difficult to drive while checking the course of a road or a novice driver.

Therefore, with the recent development of electronic communication technology, the electronic control of vehicle control has been accelerated, and the positioning system such as the Global Positioning System, which is used in airplanes or ships, is also considered in consideration of providing convenience to the driver's traffic geography. Efforts have been made to introduce them to vehicles.

Currently developed vehicle positioning system stores information about geography, road type, intersection, etc., which are information about traffic geography required in memory, and receives information about location transmitted through multiple satellites. The position is determined and output through the display device.

These positioning systems are gradually miniaturized and developed to be used as portable vehicles as well, so that a separate power supply device such as a battery is provided. It is becoming.

Hereinafter, a positioning system according to the related art will be described with reference to related drawings.

1 is a circuit diagram showing a positioning system according to the prior art.

First, as shown in FIG. 1, the positioning system according to the related art includes a central processing unit 110 for positioning a current positioning system using a signal applied from a satellite, and a first and second regulator 120. 140, the second diode D2, the auxiliary power supply 130, and the reset controller 150.

In this case, the first regulator 120 receives a main voltage (Main-Vcc) supplied to the positioning system and outputs a plurality of driving voltages V01 and V02 for driving the positioning system.

The second diode D2 is composed of two diodes, each diode having an anode connected to the main voltage Main_Vcc or an auxiliary power supply 130 and a cathode connected to the second regulator 140. Connected.

In addition, the auxiliary power supply unit 130 includes a first diode D1, a resistor R, and a charging means Bat, and includes a main voltage Main_Vcc applied through the first diode D1 and the resistor R. ) Is charged to the charging means Bat, and when the main voltage Main_Vcc is not applied, the auxiliary power charged in the charging means Bat is output.

The second regulator 140 is connected to the second diode D2 and receives the main voltage Main_Vcc or an auxiliary power source to drive an RTC (real time clock) terminal of the central processing unit 110. Output the voltage V03.

The reset controller 150 has a Vin terminal and a Vsen terminal, and the Vin terminal receives the RTC driving voltage V03 output from the second regulator 140, and the Vsen terminal is output from the first regulator 120. The driving voltage V02 is applied.

In this case, when the main voltage Main_Vcc is supplied and the driving voltage V02 is applied to the Vsen terminal, the reset control unit 150 outputs a reset voltage V04 having a magnitude corresponding to the RTC driving voltage V03. By doing so, the central processing unit 110 is reset.

In the conventional positioning system having such a configuration, when the main voltage Main_Vcc is applied, the first regulator 120 operates to output a plurality of driving voltages V01 and V02 to drive peripheral devices (not shown). Then, the charging means (Bat) of the auxiliary power supply unit 130 is charged.

In addition, the second regulator 140 is driven by the main voltage Main_Vcc to transfer the RTC driving voltage V03 to the central processing unit 110 so that the RTC terminal of the central processing unit 110 is driven to time Will count. At this time, the reason for counting the time in the RTC stage is to make it possible to quickly find a satellite that can be received at the current position in the initial operation of the positioning system. That is, since the satellite rotates the earth's orbit at regular intervals, it is always located at the fixed position at a given time, so that the user can quickly find a satellite that can be received, thereby reducing the initial operating time of the positioning system. .

However, the above-described positioning system according to the prior art has the following problems.

In the conventional positioning system, when the main voltage Main_Vcc is supplied, the central processing unit 210, the first and second regulators 120 and 140, the auxiliary power supply unit 130, and the reset control unit may be provided through the main voltage Main_Vcc. 150 is all driven, but when the supply of the main voltage (Main_Vcc) is cut off, that is, when the driving of the positioning system is stopped, the second regulator 140 and the auxiliary regulator supplied by the auxiliary power supply 130; Only the reset control unit 150 is driven.

In this case, the second regulator 140 outputs an RTC driving voltage V03 to drive the RTC terminal of the central processing unit 210 to count the time, and resets the RTC driving voltage V03 to the reset controller 150. In addition, the consumption of auxiliary power is increased by being supplied and driven.

Accordingly, in the conventional positioning system, when the supply of the main voltage (Main_Vcc) is cut off and the auxiliary power is used, the power of the auxiliary power is consumed by the driving of the reset controller 150, so that the driving time of the RTC stage using the auxiliary power is increased. There was a problem that is shortened.

In addition, as the driving time of the RTC stage is shortened, when attempting to position the current position by restarting the positioning system, there is a problem in that it takes a lot of time to find satellites and thus the reliability is low.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and does not connect the reset voltage output unit that generates the reset voltage with the auxiliary power supply unit, but connects the regulator with a regulator that is driven when the main voltage is applied and outputs a plurality of driving voltages. The goal is to provide a low-power positioning system that can find satellite signals quickly by reducing power consumption.

Low power positioning system according to the present invention for achieving the above object, the first regulator for receiving a main voltage and outputting a plurality of driving voltage; An auxiliary power supply configured to charge the main voltage and output a charged voltage; A second regulator receiving the voltage supplied from the main voltage or the auxiliary power supply unit and supplying a predetermined magnitude of the RTC driving voltage; A reset voltage output unit configured to receive a driving voltage of a plurality of driving voltages output from the first regulator and output a reset voltage; And a central processor configured to measure the current position and measure the time by receiving the RTC driving voltage, thereby increasing the use time of the auxiliary power by reducing the current consumption of the auxiliary power.

In this case, the auxiliary power supply unit, a first diode to receive the main voltage to the anode; A resistor, one end of which is connected to the cathode of the first diode; And charging means for charging both terminals of the resistor connected to the other end of the resistor and the negative terminal of the resistor and charging the main voltage applied through the first diode and the resistor.

The charging means may output a charged voltage when the main voltage is not applied through the first diode and the resistor.

The reset voltage output unit may include: a reset controller configured to receive a driving voltage from among a plurality of driving voltages output from the first regulator and output a reset control signal; And a third regulator configured to receive the reset control signal and output a reset voltage for resetting the central processing unit.

In addition, the anode is characterized in that it further comprises a second diode connected to the main voltage and the auxiliary power supply and the cathode connected to the second regulator.

In the low-power positioning system according to the present invention, the power consumption of the auxiliary power supply is reduced by connecting the reset voltage output unit for generating the reset voltage to the regulator which is driven when the main voltage is applied and outputs a plurality of driving voltages. There is an effect that can be reduced.

In addition, in the low-power positioning system according to the present invention, as the use time of the auxiliary power becomes longer when the main power supply is cut off, the count time of the time becomes longer, so that the initial operation time can be quickly found when the positioning system is restarted. As it is shortened, there is an effect of improving reliability.

Details regarding the construction and effects of the low power positioning system according to the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

Example

Hereinafter, a low power positioning system according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram showing a positioning system according to the present invention.

First, as shown in FIG. 2, the low power positioning system according to the present invention includes a central processing unit 210, first and second regulators 220 and 240, an auxiliary power supply unit 230, and a reset voltage output unit 250. Is made of.

Here, the central processing unit 210 measures the position of the current positioning system using a signal received from a satellite, etc., and has an RTC stage therein to count the current time by itself.

The first regulator 220 receives a main voltage Main_Vcc supplied to the positioning system and outputs a plurality of driving voltages V01 and V02 for driving a plurality of devices (not shown) included in the positioning system. do.

The auxiliary power supply 230 includes a first diode D1, a resistor R, and a charging means Bat, and the first diode D1 and the resistor R when the main voltage Main_Vcc is supplied. The main voltage Main_Vcc applied through the above is charged in the charging means Bat.

In this case, the first diode D1 receives the main voltage Main_Vcc as an anode, a cathode is connected to one end of the resistor R, and one end of the resistor R is connected to the first diode D1. It is connected to the cathode of and the other end is connected to both terminals (+) of the charging means (Bat). In addition, the charging means Bat has a positive terminal (+) connected to the other end of the resistor (R), the negative terminal (−) is grounded, and is applied through the first diode (D1) and the resistor (R). Charge main voltage (Main_Vcc). If the supply of the main voltage Main_Vcc is cut off, the charging means Bat outputs the charged voltage as an auxiliary power source.

The second regulator 240 operates by receiving an auxiliary power supplied from the main voltage Main_Vcc or the auxiliary power supply 130 to operate the RTC driving voltage V03 for driving the RTC terminal of the central processing unit 210. Output

The second diode D2 may be further provided between the auxiliary power supply 230 and the second regulator 240. The second diode (D2) is composed of two diodes, each diode is connected to the second regulator by the anode receives the main voltage (Main_Vcc) and the auxiliary power is connected to each other. Accordingly, the second diode D2 outputs the main voltage Main_Vcc and the auxiliary power only to the second regulator 240, and blocks the components applied to the auxiliary power supply 230 through the second regulator 240.

In addition, the reset voltage output unit 250 includes a reset control unit 251 and a third regulator 252, the driving voltage (V01) of any one of the driving voltage (V01, V02) of the first regulator 220. ), The reset voltage output unit 250 operates when the driving voltage V01 is supplied to output the reset voltage V04. In the present invention, the reset voltage output unit 250 is connected to the V01 driving voltage.

Here, the reset control unit 251 is provided with a Vin terminal and a Vsen terminal, is connected to the third regulator 252, the main voltage (Main_Vcc) is supplied to the first regulator 220 is supplied with a driving voltage (V01). When the operation is performed, a reset control signal S is generated.

The third regulator 252 is connected to the reset control unit 251 and the central processing unit 210, and resets the central processing unit 210 when a reset control signal S is applied from the reset control unit 251. Outputs a reset voltage (V04).

In particular, the reset voltage output unit 250 is connected to the first regulator 220 which is operated only when the main voltage Main_Vcc is supplied without being connected to the second regulator 240 as in the related art. When the supply of Main_Vcc) is cut off and only the auxiliary power source is used, power consumption can be reduced, thereby increasing the use time of the auxiliary power output from the charging means Bat.

Power consumption in the low-power positioning system of the above configuration can be confirmed in Table 1 below.

[Table 1] shows the results of 10 tests using the Ms514S 3.4mAh battery, and the test method measures the discharge time after fully charging the battery.

As shown in Table 1, the low-power positioning system according to the present invention shows that the average current consumption of the battery is 6.04 uA, which reduces the current consumption of the battery by about 12.9% compared to the conventional 6.82 uA current consumption of the battery. have. In addition, it can be seen that the discharge time of the battery also lasts for 562 hours, which is 64 hours longer than the conventional 498 hours, thereby increasing the count time of the RTC stage.

Accordingly, the low-power positioning system according to the present invention has an advantage of reducing the consumption of only the auxiliary power by connecting the reset voltage output unit 250 to the first regulator 220 that does not use the auxiliary power.

In addition, as the usage time of the auxiliary power supply becomes longer, the count time of the RTC stage of the central processing unit 210 also increases, so that the initial operation time is shortened and the initial operation time is shortened as the satellite can be found faster than the conventional positioning system when the positioning system is reused. There is an effect to improve.

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and various substitutions, modifications, and changes within the scope of the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It will be appreciated that such substitutions, changes, and the like should be considered to be within the scope of the following claims.

1 is a circuit diagram of a positioning system according to the prior art.

2 is a circuit diagram of a positioning system according to the present invention.

<Description of Symbols for Major Parts of Drawings>

210: central processing unit 220: first regulator

230: charging unit 240: second regulator

250: reset voltage output unit 251: reset control unit

252: third regulator

Claims (5)

A first regulator receiving a main voltage and outputting a plurality of driving voltages; An auxiliary power supply configured to charge the main voltage and output a charged voltage; A second regulator receiving the voltage supplied from the main voltage or the auxiliary power supply unit and supplying a predetermined magnitude of the RTC driving voltage; A reset voltage output unit including a third regulator and receiving one of a plurality of driving voltages output from the first regulator and outputting a reset voltage to the third regulator; And A central processor configured to measure a current position and measure time by receiving the RTC driving voltage; Low power positioning system comprising a. The method of claim 1, wherein the auxiliary power supply unit, A first diode receiving the main voltage as an anode; A resistor, one end of which is connected to the cathode of the first diode; And Charging means for charging a main voltage applied through the first diode and the resistor, both terminals being connected to the other end of the resistor and the negative terminal being grounded; Low power positioning system comprising a. The method of claim 2, And the charging means outputs the charged voltage when the main voltage is not applied through the first diode and the resistor. The method of claim 1, wherein the reset voltage output unit, A reset controller configured to receive a driving voltage from among the plurality of driving voltages output from the first regulator and output a reset control signal; And A third regulator receiving the reset control signal and outputting a reset voltage for resetting the central processing unit; Low power positioning system comprising a. The method of claim 1, And a second diode having an anode connected to the main voltage and an auxiliary power supply and a cathode connected to the second regulator.

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