KR101694376B1 - flicker lighting apparatus having GPS and time synchronizing thereof - Google Patents

Abstract

The present invention relates to a flickering and lighting apparatus using GPS and a time synchronizing method thereof. The flickering and lighting apparatus using GPS comprises: a GPS reception module; a counter for counting a clock pulse signal output from a clock generation unit; a comparator for outputting a first signal when a value output from the counter reaches a set target value; an edge signal generator for outputting a second signal corresponding to a 1 pps signal output from the GSP reception module; a logical sum treatment unit for outputting a one second generation signal when any one of the first signal and the second signal is received; a switch unit for supplying a power to the GPS reception module from a power supply unit or blocking the same; and a control unit for controlling the switch unit to perform an operation mode for supplying power to the GPS reception module and a non-operation mode for blocking supply of the power in a set idle pattern, adjusting an internal time to be synchronized with a time output from the GPS reception module by using the one second generation signal output from the logical sum treatment unit, the second signal corresponding to the 1 pps signal, and time data output from the GPS reception module in the operation mode, and updating the internal time by using the one second generation signal output from the logical sum treatment unit and controlling a lamp driving unit to flicker lamps when the current internal time corresponds to a set lamp flickering time in the non-operation mode. According to the flickering and lighting apparatus using GPS and a time synchronizing method thereof, the time can be synchronized with a reference time with a time gap less than or equal to one millionth second while intermittently operating the GPS reception module, and power consumption can be reduced.

Description

[0001] Flicker lighting apparatus using GPS and time synchronization method [0002]

The present invention relates to a flashing equalization apparatus using GPS and a time synchronization method thereof, and more particularly, to a flashing equalization apparatus using GPS and capable of synchronizing an internal time with GPS time and a second unit while intermittently operating a GPS receiving module, Time synchronization method.

In general, a flashing device for blinking at night is used for ship navigation marking or airborne obstacle indication.

The flashing lights for marking the ship route are usually formed in the form of light buoys and are spaced apart along the route so as to guide the route for entering the port.

These flashing devices are structured to operate periodically to improve discrimination.

In addition, the flashing devices provided in the display area are required to be constructed so that the flashing patterns are synchronized with each other so that the display target area can be visually recognized visually from a long distance.

As a method for synchronizing the blinking of a plurality of flashing devices installed over a large area, a method of transmitting a synchronization control signal by a wired or wireless propagation system can be considered.

In the case of the wired propagation system, it is troublesome to construct a control line for transmitting a synchronization signal, and it is very difficult or impossible to construct a control line at sea.

On the other hand, a synchronous flashing device for synchronizing the flashing time with the wireless propagation method is disclosed in Korean Patent Publication No. 2000-0065008.

However, in the case of the radio wave propagation system, the available radio wave resources are limited, and reception errors due to interference with other radio wave signals in the adjacent region may occur, and the power consumption is large, which is disadvantageous in constructing a low power consumption system.

Meanwhile, there is a method of synchronizing the blinking time of the flashing devices by using the GPS receiving module. However, if the flashing device is to be driven at the lowest power as much as possible, a method of keeping the time synchronization precision high while driving the GPS receiving module intermittently Is required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a GPS receiver which can intermittently operate a GPS receiver module, A flashing equalizer, and a time synchronization method therefor.

According to an aspect of the present invention, there is provided a flashing and equalizing apparatus using GPS, including a GPS receiving module; A clock generator for generating a clock pulse signal at a period less than one second; A counter for counting a clock pulse signal output from the clock generator and outputting the clock pulse signal to a first output terminal and resetting a count value when a reset signal is received from the reset terminal; A comparator for outputting a first signal when a value output from the counter reaches a set target value; An edge signal generator for outputting a second signal corresponding to a 1pps signal outputted every second when the GPS receiver module is operated; An OR circuit for outputting a 1 second generation signal when the first signal or the second signal is received and providing the 1 second generation signal as a reset signal of the counter; A lamp driving unit for driving the lamp to blink according to a control signal; A switch unit for supplying or cutting off power from the power supply unit to the GPS receiving module; Wherein the control unit controls the switch unit so that the GPS receiving module performs an operation mode in which power is supplied in a predetermined idle pattern and a non-active mode in which power is cut off, and in the operation mode, A second signal corresponding to the 1pps signal and the time data output from the GPS receiving module to update the internal time in the internal register so as to be synchronized with the time output from the GPS receiving module, And a control unit for updating the internal time using the 1 second generation signal output from the OR processing unit and controlling the lamp driving unit so that the lamp blinks when the current internal time corresponds to the set lamp blinking time.

Preferably, the control unit cuts off the power supplied to the GPS receiving module when the number of times that the internal time coincides with the time data received from the GPS receiving module in the operation mode reaches the set number of times, .

According to an aspect of the present invention, the control unit is set to switch to the operation mode every time the internal time reaches the preset time.

If the second signal corresponding to the 1pps signal is not generated, the control unit increments the counter value in seconds of the internal time when the 1-second generation signal is received from the OR processing unit and sets the state value in the second unit update mode If the previous state value is the update mode in the second state in the state where the second signal is generated, does not increase the counter value in seconds of the internal time, and if the previous state value is updated in the second state Mode, the counter value of the second time of the internal time is incremented and set to the update waiting mode in seconds.

In order to achieve the above object, a time synchronization method of a flashing equalizer according to the present invention includes: Supplying power to the GPS receiving module to perform an active mode; I. An internal time in which an internal register is updated by using a one second generation signal output from the OR circuit in the operation mode, time data output from the second signal, and time data output from the GPS reception module is output from the GPS reception module And when the number of times that the internal time coincides with the time data received by the GPS receiving module reaches the set first number, the power supplied to the GPS module is cut off and the process is switched to the non- ; All. And updating the internal time using the 1-second generation signal output from the logical sum processing unit in the non-active mode.

According to the flashing equalization apparatus and its time synchronization method using the GPS according to the present invention, the GPS receiving module can be synchronized with the standard time at less than one millionth of a second while operating intermittently, and the power consumption can be reduced do.

1 is a block diagram showing a flashing equalizer using GPS according to the present invention,
FIG. 2 is a flowchart showing a time synchronization and lamp blinking control process of the control unit of FIG. 1,
FIG. 3 is a flow chart showing in detail the GPS time data synchronization process of FIG. 2,
4 is a flowchart showing a 1-second time update process of the controller of FIG.

Hereinafter, a flashing equalizer and a time synchronization method according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a flashing equalizer using GPS according to the present invention.

1, a flashing and equalizing apparatus according to the present invention includes a GPS receiving module 110, a clock generating unit 120, a 1-second timer 130, a switch unit 151, a power supply unit 155, a controller 160 A lamp driving unit 170, and a lamp 180. [

The GPS receiving module 110 is operated when power is supplied from the power supply unit 155 via the switch unit 151 and outputs time data corresponding to the universal time received from the GPS satellite and a 1 pps signal once a second.

The 1pps signal output from the GPS reception module 110 is provided to an edge signal generator 135 to be described later and the time data S3 is provided to the control unit 160. [

The clock generating unit 120 generates a clock pulse signal at a period less than one second.

The frequency of the clock pulse generated by the clock generating unit 120 may be suitably applied according to the synchronization accuracy to be applied.

The clock generator 120 is applied with a clock pulse generator 120 and a pre-frequency divider 123.

The frequency of the clock pulse generated by the clock generator 120 is, for example, 10 ³ to 10 ⁹ Hz.

For example, the clock pulse generator 120 has a clock frequency of 1 MHz.

The predistortion circuit 123 outputs a clock pulse corresponding to the divided value set for the clock pulse output from the clock pulse generator 120.

For example, if the clock frequency of the clock pulse generator 120 is 1 MHz and the frequency division value of the pre-frequency divider 123 is set to 1000, the pre-frequency divider 123 outputs a clock pulse every 1/1000 second Output.

It is needless to say that the pre-frequency divider 123 may be omitted and the clock signal output from the clock pulse generator 120 may be directly output to the counter 131, which will be described later, unlike the illustrated example.

The 1 second timer 130 includes a counter 131, a comparator 133, an edge signal generator 135, and an OR gate 137.

The counter 131 counts the clock pulse signal output from the clock generator 120 and outputs the clock pulse signal to the comparator 133 through the first output terminal 131b. When the reset signal is received from the reset terminal 131a, To "zero ".

The comparator 133 outputs the first signal when the value output from the counter 131 reaches the set target value. In the illustrated example, the first signal is configured to output a high signal corresponding to the logical value "1 ".

The target value of the comparator 133 may be set to a count value corresponding to one second of the clock pulse.

The edge signal generator 135 detects the edge of the 1pps signal outputted every second from the GPS receiving module 110 and outputs the second signal S2 corresponding to the detected edge.

Here, the second signal is configured to output a high signal corresponding to the logical value "1 ".

The second signal output by the edge signal generator 135 corresponding to the 1pps signal is provided to the controller 160 as a 1pps interrupt signal.

The OR gate 137 is applied as an OR processing unit and receives a high signal corresponding to a logical sum when any one of the first signal outputted from the comparator 133 and the second signal outputted from the edge signal generator 135 is received 1 sec generation signal S1 to the control unit 160 and provides the 1 second generation signal S1 as the reset signal of the counter 131. [

That is, the counter 131 resets the current count value when a high signal corresponding to the one-second generation signal is received from the OR gate 137 to the reset terminal 131a.

The switch unit 151 is controlled by the control unit 160 to supply or cut off power from the power supply unit 155 to the GPS receiving module 110.

The power supply unit 155 supplies power necessary for driving the flashing device.

The power supply unit 155 may be constructed so as to pre-charge the power generated from the solar cell 158 and convert the charged power to a voltage corresponding to the driving element, as shown in the illustrated example.

The power supply unit 155 may be constructed to be operated only by a built-in battery, or may be constructed in various manners such as a method of charging and supplying power generated by wind power or tidal force other than the solar battery.

The lamp driving unit 170 drives the lamp 180 in a blinking manner in accordance with the control signal output from the control unit 160.

The lamp 180 may be a light emitting diode.

The control unit 160 controls the switch unit 151 to perform the GPS receiving module 110 in the active mode in which the power is supplied in the set idle pattern and the non-active mode in which the power supply is interrupted.

The control unit 160 also receives the 1 second generation signal S1 output from the OR gate 137 and the 1pps signal from the edge signal generator 135 in the operation mode in which power is supplied to the GPS reception module 110 (Not shown) by using the second signal S2 output correspondingly and the time data signal S3 output from the GPS receiving module 110 to the GPS receiving module 110. [ In the non-operating mode, the internal time is updated using the 1-second generation signal S1 output from the OR gate 137, and the current internal time is adjusted to be synchronized with the lamp flashing time The lamp driving unit 170 is controlled so that the lamp 180 is flickered.

When the number of times that the internal time coincides with the time data received from the GPS receiving module 110 reaches the set first number in the active mode, the controller 160 cuts off power supplied to the GPS receiving module 110, As shown in Fig.

According to an aspect of the present invention, the controller 160 is set to be switched to the operation mode every time the internal time becomes the set time.

Here, on-time is a time zone in which both minutes and seconds are zero, and refers to 1:00, 2:00, 3:00,,, 24:00.

The controller 160 determines whether the 1-second generation signal S1 is generated due to the clock pulse count value reaching the target value or by the second signal generated by the edge signal generator 135, In synchronization with the update of the second unit value recorded in the register for counting the number of seconds.

If the second signal corresponding to the 1pps signal is not generated, the control unit 160 increases the counter value in seconds of the internal time when the 1-second generation signal S1 is received from the OR gate 137, The second signal is set to the update mode, and if the previous state value is the update mode in the second state in the state where the second signal is generated, the counter value in seconds of the internal time is not increased, If the mode is the second-unit update mode, the counter value in seconds of the internal time is incremented and set to the update wait mode in seconds.

Hereinafter, the time synchronization and the lamp control process of the controller will be described with reference to FIG.

First, when power is supplied to or reset from the controller 160, an initialization process is performed and an initial set value is set (step 220).

The initialization synchronization flag (first_sync_flag) is set to "1" to determine whether the initialization process is an initialization process for use in the subsequent cycle control routine, And sets the time synchronization flag (time_sync_flag) for determining whether or not to synchronize with time to "0 ".

In the subsequent cycle control routine, first, it is determined whether the initialization synchronization flag is "1" (step 230).

If it is determined in step 230 that the initialization synchronization flag is "1 ", it is determined whether the time synchronization flag (time_sync_flag) is" 1 "

If it is determined in step 240 that the time synchronization flag (time_sync_flag) is not "1 ", it is determined whether the ON time of the GPS reception module 110 exceeds the first limit setting time (step 250).

The first limit setting time is set to three minutes as an example.

If it is determined in step 250 that the ON time of the GPS receiving module 110 does not exceed the first limit setting time, the GPS time data synchronization process is performed (step 300).

The GPS time data synchronization process will be described later.

After the step 300, it is determined whether the internal time corresponds to the set blinking control time (step 310). If the blinking control time corresponds to the blinking control time, the lamp 180 is controlled to be turned on or off according to the operation condition (step 320).

Otherwise, if it is determined in step 310 that it does not correspond to the blinking control time, the process returns to step 230.

On the other hand, if it is determined in step 230 that the initialization synchronization flag is not "1 ", it is determined whether the GPS reception module is powered on (step 231).

If it is determined in step 231 that the power of the GPS receiving module 110 is turned on, it is determined whether the on time of the GPS receiving module 110 has exceeded a second limit setting time (step 232).

Here, the second time limit is preferably shorter than the first time limit, for example, set to "1" minutes.

If it is determined in step 232 that the on-time of the GPS receiving module 110 has exceeded the second limit setting time, the power of the GPS receiving module 110 is turned off (step 233).

Otherwise, in step 232, it is determined whether the time synchronization flag is "1 " (step 234) if it is determined that the ON time of the GPS receiving module 110 has not exceeded the second limit setting time.

If it is determined in step 234 that the time synchronization flag is "1 ", the process proceeds to step 233, and if it is determined that the time synchronization flag is not" 1 &

If it is determined in step 231 that the power of the GPS receiving module 110 is turned off, it is determined whether it is a set sync time (step 235).

If the synchronization adjustment time is determined in step 235, the power of the GPS reception module 110 is turned on, the time synchronization flag value is set to "0", and the GPS operation time (GPS ON time) is counted (step 236) .

Here, the time synchronization flag value "0" is a display value for a state in which the time synchronization adjustment processing is not completed, and "1"

On the other hand, if it is determined in step 240 that the time synchronization flag (time_sync_flag) is "1 ", or if the ON time of the GPS receiving module 110 exceeds the first limit setting time, the initial synchronization flag (first_sync_flag) (Step 242), and turns off the GPS receiving module 110 (step 244).

Hereinafter, the GPS time data synchronization process will be described with reference to FIG.

First, it is determined whether the received data is normally received from the GPS receiving module 110 (step 310).

 That is, it is determined whether the GXRD_FLAG for recording whether or not the received data is received from the GPS receiving module 110 is "1" (step 301), and if the GXRD_FLAG is "1" .

If it is determined in step 310 that the received data is normally received from the GPS receiving module 110, time data is extracted from the GPS receiving data string (step 320).

Next, it is determined whether the time data extracted from the GPS reception data coincides with the time recorded in the internal time count register (step 330).

If it is determined in step 330 that they do not match, the GPS reception data is updated so as to be updated with the hour, minute, and second counter register values of the internal time (step 340).

After step 340, a synchronization count (SYNC_COUNT) value for determining whether the internal time has reached the first set number of times that the time data matches with the time data received from the GPS reception module 110 is set to "0 & , The process proceeds to step 370.

On the other hand, if it is determined that the 1pps signal is synchronized in step 330, it is determined whether the 1pps signal, that is, the second signal and the 1 second generation signal are synchronized, and determines whether the 1pps_ok_flag value to be recorded is 1 (step 361).

Here, a process of determining whether a 1pps signal is synchronized with a 1-second occurrence signal and setting it to a value "1" will be described later.

If it is determined in step 361 that the 1pps_ok_flag value is 1, the 1pps_ok_flag value is changed to 0 (step 363), and the synchronous count (SYNC_COUNT) value is incremented by 1 (step 365).

If it is determined in step 361 that the value of 1pps_ok_flag is "0 ", the process proceeds to step 350.

After step 365, it is determined whether the sync count (SYNC_COUNT) value is greater than the set number, that is, whether the first number has been reached (step 367).

If it is determined in step 367 that the synchronization count (SYNC_COUNT) value has reached the set number of times, the process of setting the time synchronization to TIME_SYNC_FLAG = "1" is set (step 369).

After step 369, GXRD_FLAG is set to "0 " and the RCIF value is also set to" 1 " (step 370).

Meanwhile, the signals corresponding to the 1pps signal, that is, the second signal and the one second generation signal are applied to the control unit 160 as an interrupt signal, and the synchronization process of the second unit signal will be described with reference to FIG.

First, it is determined whether a 1pps interrupt signal, that is, a second signal, is generated (step 410).

If it is determined in step 410 that the 1pps interrupt signal, that is, the second signal, is not generated, it is determined whether a 1 second generation interrupt signal is generated (step 420).

If it is determined in step 420 that a one-second generation signal has been generated, the register's second counter value is incremented (step 422) and the timer flag TIMER_PROC is set to "1 " (step 424).

After step 424, the process proceeds to step 430.

Here, the timer flag indicates whether or not the counter value in seconds has been updated.

That is, when the timer flag is "1 ", it indicates that the register counter value in seconds is increased.

On the other hand, if it is determined in step 410 that the 1pps interrupt signal, i.e., the second signal is generated, it is determined whether the timer flag value is "1 " (step 412).

If it is determined in step 412 that the timer flag value is not "1 ", the second register counter value is increased (step 414), and the timer flag value is set to" 0 " (step 416).

Otherwise, if it is determined in step 412 that the timer flag value is "1 ", the timer flag value is set to" 0 " without increasing the second register counter value (step 416).

After step 416, the 1 pps_ok-flag value indicating that the time unit of seconds is synchronized with the second signal is increased by setting the 1 pps_ok-flag value to 1 (step 418), and the hour, minute and second time- Carry-up adjustment is performed (step 430).

After step 430, it is determined whether an interrupt due to reception of GPS reception data has occurred ((RCIE && RCIF = 1) (step 440).

If it is determined in step 440 that an interrupt due to the reception of the GPS reception data has occurred, the GPS reception data is sequentially stored in the buffer (step 450).

After step 450, it is determined whether the time data reception is completed (step 460).

If it is determined in step 460 that the time data reception is completed, the reception completion flag GRXD is set to " 1 " and the RCIE value is set to "0 "

After step 470, the RCIF value is set to "0 " (multi-step 480) in order to re-enable interrupts of the GPS reception data.

According to the flashing equalization apparatus and the time synchronization method using the GPS, the GPS receiving module 110 can be operated intermittently, and the seconds unit can be synchronized with the standard time to 1 / 10,000th of a second or less, Provides advantages.

110: GPS receiving module 120: clock generating unit
130: 1 second timer 151:
155: power supply unit 160:
170: lamp driving unit 180: lamp

Claims (6)

A GPS receiving module;
A clock generator for generating a clock pulse signal at a period less than one second;
A counter for counting a clock pulse signal output from the clock generator and outputting the clock pulse signal to a first output terminal and resetting a count value when a reset signal is received from the reset terminal;
A comparator for outputting a first signal when a value output from the counter reaches a set target value;
An edge signal generator for outputting a second signal corresponding to a 1pps signal outputted every second when the GPS receiver module is operated;
An OR operation unit for outputting a 1-second generation signal when one of the first signal and the second signal is received and providing the 1-second generation signal as a reset signal of the counter;
A lamp driving unit for driving the lamp to blink according to a control signal;
A switch unit for supplying or cutting off power from the power supply unit to the GPS receiving module;
Wherein the control unit controls the switch unit so that the GPS receiving module performs an operation mode in which power is supplied in a predetermined idle pattern and a non-active mode in which power is cut off, and in the operation mode, A second signal corresponding to the 1pps signal and the time data output from the GPS receiving module to update the internal time in the internal register so as to be synchronized with the time output from the GPS receiving module, And a control unit for updating the internal time using the 1 second generation signal output from the OR processing unit and controlling the lamp driving unit so that the lamp blinks when the current internal time corresponds to the set lamp blinking time,
The control unit increases the counter value of the internal time in seconds and sets the state value in the second unit update mode when the 1 second generation signal is received from the OR processing unit in a state in which the second signal corresponding to the 1pps signal is not generated, If the previous state value is the update mode in the second state in the state where the second signal is generated, the counter value of the second time of the internal time is not increased, and the previous state value in the state where the second signal is generated, If it is not, increases the counter value of the second unit of the internal time and sets it to the update waiting mode per second. The GPS receiver according to claim 1, wherein the control unit cuts off power supplied to the GPS receiver module when a number of times that the internal time coincides with the time data received from the GPS receiver module reaches a preset first number in the operation mode, And a non-active mode is switched to a non-active mode. 3. The apparatus of claim 2, wherein the controller is configured to switch to the operation mode every time the internal time reaches a set time. delete A clock generating unit for generating a clock pulse signal at a period less than 1 second, a clock generating unit for counting the clock signal output from the clock generating unit and outputting the counted clock signal to a first output terminal, and when a reset signal is received from the reset terminal, A comparator for outputting a first signal when a value output from the counter reaches a set target value, and a comparator for outputting a second signal corresponding to a 1pps signal outputted every second in operation from the GPS receiving module An edge signal generator for outputting a 1 second generation signal when one of the first signal and the second signal is received and providing the 1 second generation signal as a reset signal of the counter; A switch unit for supplying and disconnecting power from the power supply unit to the GPS receiving module; The control unit controls the switch unit to perform the operation mode in which the power is supplied in the set idle pattern and the non-active mode in which the power supply is cut off, and uses the 1 second generation signal, the second signal, and the time data output from the GPS reception module And a controller for controlling the lamp driving unit such that the lamp is flickered if the current internal time is equal to the set lamp flashing time while adjusting the internal time for updating and using the internal register to be synchronized with the time output from the GPS receiving module In a time synchronization method of a flashing equalizer,
end. Supplying power to the GPS receiving module to perform an active mode;
I. An internal time in which an internal register is updated by using a one second generation signal output from the OR circuit in the operation mode, time data output from the second signal, and time data output from the GPS reception module is output from the GPS reception module And when the number of times that the internal time coincides with the time data received by the GPS receiving module reaches a set first number of times, the power supplied to the GPS receiving module is cut off to switch to the non-moving mode ≪ / RTI >
All. And updating the internal time using the 1-second generation signal output from the logical sum processing unit in the non-active mode,
When the signal for one second is received from the OR processing unit in a state where the second signal is not generated in the step (b), the counter increments the internal time counter in seconds and sets the state value to the update unit in seconds,
If the previous state value in the state in which the second signal is generated is the update mode in the second unit, does not increase the counter value in seconds of the internal time,
Wherein if the previous state value is not the update mode in the second state in the state in which the second signal is generated, the second counter increments the counter value in seconds of the internal time and sets the update state to the update wait mode in seconds. Synchronous method.
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