FR2802038A1 - HYBRID LASER AND MICROWAVE COMMUNICATION METHODS AND SYSTEMS - Google Patents

Abstract

A hybrid laser and microwave communication system is disclosed, which comprises a laser communication device (LA), a microwave communication device (MW) and a switching means ( SW) making it possible to switch from one to the other. The invention applies in particular to the transmission of communications.

Description

The present invention relates to methods and systems for

  hybrid communication where we can adopt a

  laser communication and micro communication

  waves. In particular, the present invention relates to the method and to the hybrid communication system by laser and microwave which makes it possible mainly to undertake communication by laser and occasionally to undertake communication by

  microwave, depending on weather conditions.

  As wireless communication methods, there is microwave communication and laser communication. The microwave communication method is a wireless communication method using microwaves, including high frequencies (HF). Laser communication is another wireless communication method that primarily uses the light from a semiconductor laser. Each of these

  methods has its strength and its weakness.

  Communication by laser does not cause radio interference because it uses the light of an ultra high frequency semiconductor laser which is in the tera-hertz range. Also, there are no administrative regulations regarding the frequency band for laser communication and the quality of communication is excellent. However, laser communication has a weakness in that it is sensitive to weather conditions such as fog. For example, when there is significant fog, the attenuation in laser communication can become so large that communication can be stopped. This poses a serious problem in building an environment for long distance wireless communication networks.

  using laser communication.

  On the contrary, microwave communication

  is not so easily affected by fogs.

  However, there is often frequency interference in microwave communication, lowering the

quality of communication.

  The object of the present invention is to provide communication methods and systems which complement laser communication which is sensitive to mists. Another object of the present invention is to provide hybrid laser and microwave communication methods and systems which, in order to overcome the weakness of laser communication, occasionally adopt microwave communication when the quality of the communication by laser is deteriorated

because of the fogs.

  The invention will be better understood, and other aims, characteristics, details and advantages thereof

  will appear more clearly in the description

  Explanatory which will follow made with reference to the attached schematic drawings given solely by way of example illustrating several embodiments of the invention and in which: - Figure 1 is a structure diagram of the system of the present invention; - Figure 2 is a diagram to illustrate the general characteristic of the laser communication method; - Figure 3 is a structure diagram of the switching means of the system of the present invention; - Figure 4 is a structure diagram of the photoreceptor of the general laser communication device; FIG. 5 is a time diagram illustrating the switching actions towards the microwave communication device in the system according to the

present invention.

  In order to achieve the above-mentioned goals, a method and a hybrid laser and microwave communication system according to the present invention, equipped with a laser communication device and a microwave communication device. waves, ordinarily initiates communication using the laser communication method and when the magnitude of the signal received from the laser is less than a threshold value, initiates microwave communication via the switching means allowing

such conversion.

  Detailed explanations of the method and

  hybrid laser and micro communication system

  waves of the present invention are given below in

referring to the drawings.

  Figure 1 is a structure diagram of the

system of the present invention.

  Figure 1 shows the communication between sides "A" and "B", both using the hybrid laser and microwave communication system.

  produced according to the present invention.

  The hybrid laser and microwave communication system of the present invention, illustrated in FIG. 1, comprises a device for communication by

  laser (LA), a micro- communication device

  waves (MW) and a switching means (SW) which is capable of selecting one of these two methods of

communication.

  The laser communication device (LA) modulates communication signals into laser signals and

  transmits such signals to the other side through the photo-

  transmitter (Tx). Such a laser communication device (LA) receives laser signals transmitted from the other side to the photoreceptor (Rx) and demodulates such signals. The microwave communication device (MW) modulates the microwave communication signals to transmit them to the other side and demodulates the microwaves received to regenerate the communication signals. The switching means (SW) selects either the laser communication device (LA) or the microwave communication device (MW) according to the fog conditions. Ordinarily, the laser communication device (LA) is used for communication in this system, but when the magnitude of the signals received by the laser communication device is below a threshold value, the microwave communication device ( MW) is selected for communication using microwaves. The selection of one of the communication devices by the switching means (SW) is carried out as follows. If the laser communication device (LA) is selected by the switching means (SW), the input and output port of the laser communication device is connected to the input and output port of the general system. Of the same

  way, if the micro communication device

  waves (MW) is selected by the switching means (SW), the input and output port of the microwave communication device is connected to the port

  input and output of the general system.

  On the other hand, even when the laser communication device (LA) is not selected for communication by the switching means (SW), the signals received at the laser communication device (LA) are input by means of communication (SW) for a measurement of the magnitude of such signals by the indicator of the strength of the received signal (which will be described below) in the switching means (SW). In other words, the switching means (SW) of the system of the present invention monitors the magnitude of the

  signals received by the laser communication method.

  If fogs cause the magnitude of the received laser signals input to the switching means (SW) to decrease below a predetermined threshold value, the switching means (SW) connects the input and output port of the system to the microwave communication device input and output port

  (MW) in order to initiate communication by micro-

  waves. If the mists disappear with the result that the magnitude of the received laser signals increases above the threshold value, the switching means (SW) connects the input and output port of the system to the input and output port. of the laser communication device (LA) for laser communication. Since the quality of laser communication is generally higher, it is desirable to use laser communication in ordinary times and to use microwave communication only when reception of laser signals is deteriorated due to fog. . If the mists disappear and the quality of the laser communication is recovered, it is therefore desirable to

  convert back to laser communication.

  Figure 2 is a diagram to illustrate the general characteristic of the communication method

by laser.

  Laser signals are severely attenuated when they pass through an atmosphere containing mists. As a result of this attenuation, effective coverage of laser communication devices is limited and in severe cases, there may be an interruption of

Communication.

  As illustrated in Figure 2, if the laser communication method is used for communication between points a and b, the laser transmitted from the photo-emitter (Tx) in the air loses its energy during propagation, because of particles in the air like dust and mists. Likewise, the attenuation of the laser energy transmitted in the air depends on the divergent angle (a) and the dimension of the lens at the receiving end. The attenuation by particles such as dust and mists is called "weather attenuation" and the attenuation by other elements is called "reception area attenuation". In order for laser communication to be feasible, the sum of the weather mitigation and the reception area mitigation must not be

less than -90dB.

  The attenuation of the reception area is determined by the following equation, according to the measurement squared (to the diameter) of the laser beam at the reception end and

  the square measurement (or diameter) of the photo-

  receiver if the distance from the end of

  transmission and the receiving end is 1km.

  (Laser end of transmission end) x [square measurement of the lens at the photo-receptor (or diameter) / square measurement of the laser beam (or diameter)]. For example, if the diverging angle (a) is lmRd when the distance between the transmitting end (a) and the receiving end (b) is lkm, the diameter (S) of the transmitted laser beam from transmitting end (a) to receiving end (b) which is separated from lkm from (a), is from lm. With S being lm, if the laser output is 20mW and if the diameter of the lens at the photo-receptor is 100mm, then "the attenuation of the reception area" calculated according to

  the above equation will be -27dB.

  Attenuation by weather conditions due to thick fog will be around -50dB / km if the visibility range is 270m and around -70dB / km if the visibility range is 200m. Thus, in fogs with a visibility range of 200m to 270m, the sum of "attenuation of the reception area" and "attenuation by weather conditions" can be around -77dB to -97dB . Since the current minimum sensitivity of the laser beam signal detector is -90dB, the sum of the "weather attenuation" and the attenuation of the reception area must not be less than -90dB for a

laser communication.

  In the city center, there are only a few days a year where the fogs are thick enough to prevent communication by laser. Thus, the hybrid laser and microwave communication method and system according to the present invention adopts laser communication in ordinary time and uses microwave communication only when laser communication

is bothered by fogs.

  In what follows are given, with reference to FIGS. 3, 4 and 5, detailed explanations of the switching actions from laser communication to microwave communication and vice versa for the hybrid communication method and system by laser

  and microwave of the present invention.

  Figure 3 is a structure diagram of the means

  the system of the present invention.

  The switching means (SW) includes a received signal strength indicator (RSSI) which receives the received electrical signal, which has been received and modulated at the photoreceptor (Rx) of the laser communication device (LA) and generates a signal voltage which is proportional to the strength of this received signal; a comparator (Comp.) which compares the magnitude of the voltage signal at the output of said indicator of the strength of the received signal (RSSI) with the predetermined threshold value and emits a voltage signal (LOS = signal los) of a logical level depending on the result of this comparison; a control unit (CC) which generates a switching control signal (SC) based on the logic level of the voltage signal at the output of the comparator (Comp.); and a switching unit (SB) which connects the input / output port of the communication system either to the input / output port of the laser communication device (LA) or to the input / output port of the communication device microwave (MW), based on the switching control signal (SC) which is

  introduced by the control unit (CC).

  The received signal strength indicator (RSSI) generates a voltage signal proportional to the magnitude of the signals received at the photoreceptor (Rx) of the laser communication device (LA). As shown in the photoreceptor (Rx) structure diagram of the general laser communication device in Figure 4, the signal from the laser received at the lens to the photoreceptor (Rx) is converted into an electrical signal by the APD module and circuits limiters. This received signal is introduced into the strength indicator of the

  signal received (RSSI) from the switching means (SW).

  In the received signal strength indicator (RSSI), a voltage signal proportional to the strength of the received signal is generated and this voltage signal is

introduced to the comparator (Comp.).

  The comparator (Comp.) Compares the strength of the electrical signals received, introduced by the photoreceptor (Rx), with the threshold value (predetermined) and generates a voltage signal (LOS) having a logic level value based on the result of this comparison. This signal from

  voltage is introduced to the control unit (CC).

  The control unit (CC) generates a switching control signal (SC) according to the voltage signal (LOS) at the output of the comparator (Comp.). The switching control signal (SC) allows the input / output port of the general communication system to be connected to the input / output port of the laser communication device (LA) when the strength of the received signal is more large than the threshold value, or at the port

  input / output of the micro communication device

  waves (MW) when the strength of the received signal is less than

the threshold value.

  The switching unit (SB) connects the input / output port for communication either to the input / output port of the laser communication device (LA) or to the input / output port of the microphone communication device -waves (MW), based on the switching control signal (SC) transmitted by said control unit (CC). The operation of the hybrid laser and microwave communication system of the present invention, having the structure described above, is

explained in the following.

  In the initial state, the input / output port for communication is connected to the input / output port of the laser communication device (LA). Thus, communication using the laser communication device (LA) is undertaken. If fogs form and the signal strength received at the laser communication device (LA) gradually decreases due to these fogs until the signal strength measured at the received signal strength indicator (RSSI ) becomes lower than the threshold value, the level of the voltage signal (LOS) at the output of the comparator (Comp.) changes. Then, the switching control signal (SC) to be transmitted by the control unit (CC) is determined accordingly. Finally, in the switching unit (SB), switching the input / output port for communication by the communication device

  by laser (LA) to the communication device by micro-

  waves (MW) is undertaken, allowing communication to be undertaken by the communication device by

microwave (MW).

  Even during communication using the microwave communication device (MW), the strength of the laser communication signals received at the photoreceptor (Rx) of the laser communication device (LA) is monitored at the strength indicator of the received signal (RSSI) from the switching means (SW). During this monitoring, if the strength of the received laser signals becomes greater than the threshold value, the level of the voltage signal (LOS) at the output of the comparator (Comp.) Is generated and thus, the switching control signal ( SC) of the control unit (CC) is determined accordingly, forcing the switching unit (SB) to initiate switching of the input / output port for communication from the microwave communication device (MW) to the laser communication device (LA). Therefore, communication by the communication device by

laser (LA) is validated.

  FIG. 5 is a time diagram illustrating the switching actions towards the microwave communication device in the system according to the

present invention.

  LOS in FIG. 5 is a voltage signal at the output of the comparator (Comp.) Of the communication means (SW) as a result of the comparison of the voltage value indicating the strength of the signal at the output of the indicator of the received signal strength (RSSI), with standard voltage value. FIG. 5 illustrates an example where LOS is converted to "High Level" if the strength of the signal received from the laser is less than the threshold value. In the figure, "tp" is the time interval between the conversion of LOS to "High Level" and the completion of switching to the microwave communication device (MW). In other words, it is only after the time "tp" has passed after conversion of LOS to "High Level" that switching to the device

  microwave communication (MW) is accomplished.

  The switching action is taken with such a time interval to prevent the microwave communication device (MW) from being enabled on an occasion where the strength of the laser signal is momentarily reduced and recovered immediately thereafter. The value of "tp" can be specified by a user in the range

from 0.05 ms to 200 ms.

  The hybrid laser and microwave communication method and system of the present invention employs both the radio communication device

  laser and microwave communication device.

  With such a system, under normal conditions, communication by the laser is undertaken. However, when the magnitude of the signals received by the communication by the laser is below the threshold value due to meteorological conditions such as fog, the present invention allows communication by a microwave, completing the weakness of the communication.

by laser.

Claims (5)

  1. Hybrid laser and microwave communication system, characterized in that it comprises: a laser communication device (LA) which modulates electrical signals into laser signals and transmits said signals and which receives laser signals transmitted by the other side and demodulates such signals into electrical signals; a microwave communication device (MW) which modulates the electrical signals into microwave signals and transmits such signals and which receives microwave signals transmitted from the other side and demodulates these signals into electrical signals; and a switching means (SW) which, equipped with a received signal strength indicator monitoring the magnitude of the signals received at the laser communication device, connects the input / output port for communication to the input port / output of the microwave communication device for communication by the microwave communication device if the output value measured at said indicator of the strength of the received signal is less than a predetermined threshold value. 2. System according to claim 1, characterized in that the switching means comprises: an indicator of the strength of the received signal (RSSI) which receives the electrical signals received, which have been received and demodulated at the photoreceptor of the laser communication device and generates a voltage signal which is proportional to the strength of said received signal; a comparator (Comp.) which compares the magnitude of the voltage signal at the output of said received signal strength indicator with the predetermined threshold value and outputs a voltage signal at a logic level dependent on the result of said comparison; a control unit (CC) which generates a switching control signal based on the logic level of the voltage signal (LOS) at the output of the comparator; and a switching unit (SB) which connects the input / output port of the communication system either to the input / output port of the laser communication device or to the input / output port of the micro communication device. waves based on the switching control signal which is introduced from the control unit ordered.   3. System according to claim 2, characterized in that the switching unit (SB) in the initial state connects the input / output port for communication to the input / output port of the communication device by laser.   4. Method of hybrid communication by laser and microwave, characterized in that it comprises: (a) a step of communication by laser in which electrical signals are modulated into laser signals and transmitted and the laser signals transmitted from other side are received and demodulated into electrical signals; (b) a step of measuring the magnitude of the signal, in which the magnitude of the received laser signals is measured during the laser communication; (c) a step in which, if the magnitude of the laser signals received, measured in said step (b) is less than the threshold value, the input / output port for the communication is connected to the port   input / output of the micro communication device   waves to allow communication by microwave signals; (d) a monitoring step in which the magnitude of the received laser signals is monitored, even while step (c) is undertaken; and (e) a step in which, if the magnitude of the received laser signals, measured in said step (d), becomes greater than the threshold value, the input / output port for communication is again connected to the port d input / output of the laser communication.   5. Method according to claim 4, characterized in that the switching action connecting the input / output port for communication to the port   input / output of the micro communication device   waves in the above-mentioned step (c) is undertaken when a time interval "tp" has elapsed after the strength of the received laser signal has fallen below the value threshold.