TWI818746B - Laser transmitter and method of operation - Google Patents

Abstract

The invention discloses a laser transmitter and an operating method thereof. The laser transmitter may include: a laser signal receiving unit configured to receive a monitoring laser signal transmitted by the laser-based speed monitor; and a laser signal transmitting unit configured to respond to the received monitoring laser signal. The signal transmits the interfering laser signal; the control unit is used to measure the signal interval of the received monitoring laser signal when the monitoring laser signal is detected, use the measured signal interval to calculate the information of the interfering laser signal, and calculate the information based on the calculated information Generate interference laser signals.

Description

Laser transmitter and method of operation

The invention relates to a laser transmitter and an operating method thereof.

Press, general vehicles currently use various types of speedometers or safety alarm devices to prevent speeding, and use different microwave or laser signals to identify various dangerous road conditions. For example, different types of speed guns used to measure vehicle speed to prevent speeding may include those using X-band, Ku-band, K-band, Ka-band, laser, etc. In addition, providing road condition information can transmit information such as level crossings, construction areas, emergency vehicles, etc., and the safety warning system can transmit various information such as fog areas, construction areas, campuses, deceleration zones, etc., and present it in coded form.

According to related technologies, speed detection methods used in navigation systems, GPS systems, etc. can only input coordinates at a predetermined location and provide information to the driver when the vehicle passes by the coordinates. However, this technology cannot be used to detect microwaves or lasers. Types of mobile speed camera equipment.

Therefore, a radar detector is known, which is a system that detects laser or ultra-high frequency waves emitted by a speed gun, measures the speed, and notifies the driver through voice, text, or signal tones. Radar detectors, which use microwaves or lasers, have been developed and used in some countries for safe driving functions in vehicles.

The object of the present invention is to provide a laser transmitter and a method of operating the laser transmitter, which are used to measure the speed of a moving object, monitor the laser signal emitted by the monitor to the moving object, and emit interference laser signals to target the moving object. Detected surveillance laser signal.

A laser transmitter according to an embodiment of the present invention may include: a laser signal receiving unit configured to receive a monitoring laser signal transmitted by a laser-based speed monitor; and a laser signal sending unit configured to respond to the received monitoring signal. The laser signal sends the interfering laser signal; the control unit is used to measure the signal interval of the received monitoring laser signal when the monitoring laser signal is detected, use the measured signal interval to calculate the information of the interfering laser signal, and calculate the information based on the calculation. The information generates interference laser signals.

The aforementioned control unit can measure the signal intervals in sequence by receiving the preset n monitoring laser signals (where n is a natural number), and can calculate the timing setting time, signal interval and emission time signal of the interference laser by using the measured signal signal interval.

The timing setting time can be determined as the shortest signal interval among the measured signal intervals. The signal spacing interfering with the laser signal can be determined as the common divisor of the measured signal spacing. The transmission time of an interfering laser signal can be calculated by multiplying the average of the measured signal intervals by a preset number of monitored laser signals.

After the control unit sequentially measures the signal intervals by receiving n monitoring laser signals, when the period of the timing setting time has ended, it can transmit the interference laser signal within the calculated interval and continue for the calculated transmission time. Elapses from the time point when the nth monitoring laser signal is received.

If the monitoring laser signal is received after the interference laser signal is sent, the control unit can repeatedly send the interference laser signal at a timed setting starting from the time point when the monitoring laser signal is received.

Another aspect of the invention provides a method for operating a laser transmitter.

A method of operating a laser transmitter according to an embodiment of the present invention may include: receiving a monitoring laser signal transmitted by a laser-based speed monitor; measuring a signal interval of the received monitoring laser signal; and calculating using the measured signal interval Information that interferes with the laser signal to be transmitted; generates the interference laser signal based on the calculated information and transmits the interference laser signal.

A laser transmitter and an operating method thereof can detect a monitoring laser signal emitted to a moving object by a speed monitor for measuring the speed of the moving object, and can emit an interference laser signal in response to the detected monitoring laser signal.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

The technical content, features and effects of the present invention will be clearly presented in the following detailed description of the preferred embodiments with reference to the drawings. In addition, in the description of the present invention, the accompanying drawings are used to explain the basic steps and necessary structures of the present invention in a schematic manner. Therefore, only the elements related to the present invention are shown in the drawings, and terms such as units and modules in the description are shown. It refers to a unit component that handles at least one function or action, and the displayed shape, size, proportion, or related number, etc., is a selective design; it will be described first; various implementations of the present invention will be described below with reference to the accompanying drawings. method is described in more detail.

Referring to FIG. 1 , a laser transmitter is shown. The laser transmitter 10 according to the embodiment of the present invention may include a laser signal receiving unit 11 , a laser signal transmitting unit 12 and a control unit 13 .

The laser signal receiving unit 11 can receive the monitoring laser signal emitted by the laser speed meter 20 . The laser speedometer 20 may be, for example, a speed gun that uses laser to measure the speed of moving objects.

The laser signal sending unit 12 can transmit an interference laser signal for the received monitoring laser signal.

The control unit 13 can control the overall operation of the laser transmitter 10 . For example, the control unit 13 may be composed of a program memory storing a method for executing the method of operating the laser emitter according to the embodiment of the present invention, and a microprocessor operating according to the program stored in the memory.

Specifically, if it is detected that a monitoring laser signal is received through the laser signal receiving unit 11, the control unit 13 may analyze the pattern of the received monitoring laser signal and generate an interference laser signal according to the monitoring laser signal.

Please refer to FIG. 1 to describe the method used by the control unit 13 of the laser transmitter 10 to operate the laser transmitter.

In operation S210, the control unit 13 may detect the monitoring laser signals sent by the laser-based velocimeter 20 and measure the signal intervals between the received monitoring laser signals.

Referring to Figure 3, the control unit 13 can sequentially measure signal intervals by receiving preset n monitoring laser signals (where n is a natural number).

After detecting that the first laser monitoring signal is received, the control unit 13 can measure the signal interval Δt1 between the first laser monitoring signal and the second laser monitoring signal, and can measure the signal interval Δt1 between the second laser monitoring signal and the third laser monitoring signal. The signal interval Δt2 of the laser, and the signal interval Δt3 between the third laser monitoring signal and the fourth laser monitoring signal, and the (n-1)th laser monitoring signal and the nth laser The signal interval between monitoring signals is Δtn-1.

In operation S220, the control unit 13 may calculate the information of the interfering laser signal to be transmitted by using the measurement signal interval of the monitored laser signal.

In order to jam the received surveillance laser signal, it may be necessary to send the jamming laser signal immediately before the surveillance laser signal is received. Therefore, according to the control unit 13 of the embodiment of the present invention, in order to transmit the interference laser signal just before receiving the monitoring laser signal, the interference laser signal can be transmitted at the shortest possible interval before the reception time of the monitoring laser. After measuring the signal interval, the laser signal is first received. In one example, the signal interval of the interfering laser signal can be modified according to the hardware performance of the laser diode included in the laser signal transmitting unit 12, and can be set to the shortest signal interval that can be implemented by hardware.

Referring to FIG. 3 , the control unit 13 can use the measured signal interval of the monitoring laser signal to calculate the timing setting time ts, the interval tinterval between the interfering laser signals, and the transmission time tTx of the interfering laser signal.

In one example, the timing setting time ts may be determined as the shortest signal interval among the measured signal intervals of the monitoring laser signal. Furthermore, the interval tinterval between the interfering laser signals can be determined as the greatest common divisor of the measured signal intervals of the monitoring laser signals. Furthermore, the transmission time tTx of the jamming laser signal can be calculated by multiplying the average value of the measured signal intervals of the monitoring laser signal by the preset number of monitoring laser signals to be jammed.

Typically, jamming can be achieved by transmitting interfering laser signals against at least three monitoring laser signals. In this way, the number of monitoring laser signals used to calculate the transmission time tTx of the interference laser signal can be set to at least three. However, the number of interfered surveillance laser signals can be increased to any supported level.

In operation S230, the control unit 13 may generate an interference laser signal according to the calculated interference laser signal information, and transmit it to the laser speedometer 20 through the laser signal sending unit 12.

As shown in Figure 3, the control unit 13 can measure the signal intervals sequentially by receiving n monitoring laser signal signals, and then can transmit within the duration of the calculated transmission time tTx in a determined interval tinval starting from a. Interference with laser signals. The time point of the timing setting time ts after the nth monitoring laser signal is received.

For example, as shown in Figure 4, if the number of interfered monitoring laser signals is set to 3 taking into account hardware performance, the transmission time tTx of the interfering laser signal can be set to 3 times the average value of the measurement signal interval. In addition, please refer to Figure 4. The control unit 13 can perform the first round of transmission when the timing setting time ts elapses from the time point when the nth monitoring laser signal is received, and transmit interference within the duration of the calculated transmission time. The laser signal tTx is in the determined time interval tinterval, and the second round of transmission can be performed at the timing setting time ts of the received monitoring laser signal reception time point after the first round of transmission is completed. In addition, if the monitoring laser signal is received after the second round of transmission is completed, the control unit 13 can perform a third round of transmission, and continue to repeatedly transmit the interference laser signal depending on whether the monitoring laser signal is received thereafter.

The control unit 13 can determine whether to repeatedly transmit the interference laser signal based on whether a monitoring laser signal is received after one round of transmitting the interference laser signal. Therefore, if after one round of transmitting the interfering laser signal is completed, if a monitoring laser signal is received, the control unit 13 can repeatedly transmit the interfering laser by setting the timing from the received monitoring time point to the timing setting time ts. transmit signal. If the monitoring laser signal is not received, the control unit 13 may stop repeatedly transmitting the interfering laser signal.

Figure 5 shows an example of a measurement of the signal separation between received monitoring laser signals. As shown in Figure 5, the laser speedometer 20 can send monitoring laser signals at random intervals. The shortest signal interval among the measurement signal intervals for monitoring laser signals is 4.12ms, and the greatest common denominator of the measurement signal intervals for monitoring laser signals can be 0.01ms. Therefore, the timing setting time ts can be set to 4.12ms, and the interval between interference laser signals can be set to 0.01ms.

In addition, the average value of the measurement signal interval for monitoring the laser signal is 6ms, so the transmission time tTx of the interfering laser signal can be set to 3 times 6ms, that is, 18ms.

Therefore, in the situation shown in Figure 1 (and referring to Figure 5), the control unit 13 can measure that the intervals between the five monitoring laser signals received in the detection and measurement section are 6.17ms, 8.06ms, 4.12ms and 7.27ms. From this, the timing setting time ts and the interval tinterval interfere with the laser signal, and the transmission time tTx of the interference laser signal can be determined.

As shown above, the laser transmitter 10 according to the embodiment of the present invention can adaptively generate interference laser signals by measuring the signal interval of the received monitoring laser signal to generate information about the interference laser signal to be transmitted, thereby Effectively interfere with surveillance laser signals.

Therefore, the laser transmitter 10 according to the embodiment of the present invention can generate an interference laser signal, which can not only interfere with the monitoring laser signal with a constant signal interval, but also interfere with the laser signal with a random signal interval. .

The components of the above embodiments can also be easily understood from a process perspective, that is, each component can be understood as a process. Likewise, the process of the above-described embodiment can also be easily understood from the perspective of the components of the device.

The above technical features can be implemented in the form of program instructions, which can be executed using various computer means and recorded in computer-readable media. Such computer-readable media may include program instructions, data files, data structures, etc., individually or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be a medium known and used by those skilled in the computer software field. Examples of computer-readable media may include magnetic media such as hard disks, floppy disks, tapes, etc., optical media such as CD-ROM, DVD, etc., magneto-optical media such as floppy disks, etc., hardware devices such as ROM, RAM, flash memory, etc. Configuration is used to store and execute program instructions. Examples of the instruction program may include not only machine language code generated by a compiler but also high-level language code that can be executed by a computer by using an interpreter or the like. The hardware described above may be used as one or more software modules that operate to perform the actions of embodiments of the invention, and vice versa.

The embodiments of the present invention are disclosed for illustrative purposes only. Those of ordinary skill in the art can make various modifications, changes and additions without departing from the spirit and scope of the present invention, but it should be understood that these modifications, changes and additions are included in the claims described below within the scope of the present invention. From the above, the invention in this case has many advantages and has significant practical characteristics, and the technical means and methods for its application are indeed developed by the inventor of this case. The invention sincerely meets the requirements for a patent and is stipulated in accordance with the law. File an application and pray for patent rights.

10:Laser launcher

11:Laser signal receiving unit

12:Laser signal sending unit

13:Control unit

20:Laser speedometer

FIG. 1 is a structural diagram conceptually showing a laser transmitter according to an embodiment of the present invention; FIG. 2 is a flow chart illustrating a method for operating a laser transmitter according to an embodiment of the present invention; FIGS. 3 , 4 and 5 are diagrams illustrating a method for operating a laser transmitter according to an embodiment of the present invention.

10:Laser launcher

11:Laser signal receiving unit

12:Laser signal sending unit

13:Control unit

20:Laser speedometer

Claims (1)

A laser transmitter, including: a laser signal receiving unit for receiving a monitoring laser signal emitted by a laser-based speed monitor; a laser signal sending unit configured to send interference to the received monitoring laser signal Laser signal; control unit, used to measure the signal interval of the received monitoring laser signal when the monitoring laser signal is detected, use the measured signal interval to calculate the information of the interference laser signal, and generate the interference laser based on the calculated information The characteristic is that: the control unit receives the preset n monitoring laser signals (where n is a natural number), measures the signal intervals in sequence, and uses the measured signal intervals to calculate the timing setting time of the interference laser signal, Signal interval and emission time; the timing setting time is determined as the shortest signal interval among the measured signal intervals; and the signal interval that interferes with the laser signal is determined as the common divisor of the measured signal interval; and, the emission of the interference laser signal The time is calculated by multiplying the average value of the measured signal intervals by a preset number of monitoring laser signals; after the control unit sequentially measures the signal intervals by receiving the n monitoring laser signals, After a period of time, in the calculated interval, the interference laser signal is transmitted within the duration of the calculated transmission time; the timing setting time starts from the time point when the nth monitoring laser signal is received; after the interference laser signal is completed If the monitoring laser signal is received after the transmission of the radio signal, the control unit repeatedly transmits the interference laser signal by setting the time to the timing setting time.