RU2383988C2 - Bidirectional amplifier, half-duplex operation system with said amplifier and method of half-duplex operation - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to bidirectional amplifier, half-duplex operation system with said amplifier and method of half-duplex operation. Proposed amplifier comprises amplifier, device to determine transmission direction for input signal of data coming into bidirectional amplifier that doubles as switching control signal feed device and switching device to change the connection state in response to switching control signal so that amplifier (C) amplifies data signal in direction of transmission.

EFFECT: determination of data signal transmission direction by comparing data signals transmitted in two directions, higher sensitivity of reception.

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Description

FIELD OF THE INVENTION

The present invention relates to the field of communication, in particular to a single-frequency bi-directional amplifying device, a half-duplex communication system comprising a single-frequency bi-directional amplifying device, and a method for performing half-duplex communication.

State of the art

Currently, systems with coaxial cables typically use two separate frequencies for bidirectional communication; in other words, the frequency used for communication in the direction from the host to the terminal is different from the frequency used for communication in the direction from the terminal to the host. When the transmission range is long or when adding users, you need to add more amplifiers.

Figure 1 presents a schematic diagram of a full duplex communication system in a coaxial network of the prior art. Currently, FDM (Frequency-Division Multiplexing, Frequency Division Multiplexing) is used as a communication technology in coaxial cable networks; in other words, the frequency used in the upstream transmission is separate from the frequency used in the downstream transmission. As shown in FIG. 1, when a high frequency is used in communication in a direction from host 60 to terminal 80, only a low frequency can be used in communication in a direction from terminal 80 to host 60. On the other hand, when a low frequency is used in communication in a direction from host 60 to terminal 80, only a high frequency can be used in communication in a direction from terminal 80 to host 60. Thus, the host 60 and the terminal 80 cannot use the same frequency for communication. The bi-directional amplifier 70 includes two amplifiers, respectively, for amplifying low-frequency signals and high-frequency signals.

From the description of FIG. 1, it follows that the existing amplification technology is designed for full duplex FDM communication and the amplifier has different operating frequencies in the upstream and downstream directions. This amplifier cannot amplify half-duplex data signals of the same frequency; in other words, the amplifier cannot be used in half-duplex communications on a single frequency.

The existing half-duplex communication system can satisfy the requirements of a long transmission range only by increasing the transmission power and reception sensitivity. If the attenuation between the host and the terminal exceeds the threshold value, the single-frequency half-duplex communication should be replaced by a two-frequency full-duplex communication, which will allow the use of known bi-directional amplifiers for signal amplification. However, in this case, the cost and employment of spectral resources increases.

Disclosure of invention

The present invention provides an amplifying device, a communication system comprising such a device, and a communication method for solving the problem of the inability to implement single-frequency bi-directional amplification in the prior art.

The present invention provides a bi-directional amplifier device including an amplifier (C). A bi-directional amplifier device amplifies a data signal transmitted in two directions at the same frequency, and further includes a transmission direction determination device configured to determine a direction of transmission of a data signal arriving at the bi-directional amplifier device and with the possibility of supplying a switching control signal in accordance with a certain direction of transmission, and a switching device configured to switch the state of the connection in accordance Corollary to the control switching signal so that the power (P) is amplified data signal in the transmission direction and transmit the amplified data signal in a transmission direction of the receiving side.

Options for additional technical solutions bidirectional amplifying device described below.

The device for determining the direction of transmission includes two detectors configured to determine the power of data signals transmitted respectively in two directions of transmission; and a comparison device configured to compare the powers detected by the two detectors, in order to determine the transmission direction and supply the switching control signal.

The device for determining the direction of transmission additionally includes two amplifiers (E and G), made with the possibility of amplification of powers determined respectively by two detectors; moreover, the comparison device determines the direction of transmission by comparing the power amplified by amplifiers (E and G).

The device for determining the direction of transmission can determine the direction of transmission in accordance with the incoming control signal of the transceiver.

The device for determining the direction of the transmission may also include a filter configured to extract the control signal of the transceiver from the signal supplied from the receiving side or the transmission side of the data signal, and a demodulator configured to demodulate and issue the selected control signal of the transceiver, and the control signal demodulated by the demodulator the transceiver serves as a switching control signal for controlling the state of the switching device.

The switching device includes two on-off single-pole switches connected respectively to the input and output of the amplifier (C).

The present invention further provides a single frequency half duplex communication system comprising at least one first communication side, at least one second communication side and a bi-directional amplifying device between the first communication side and the second communication side; wherein the bi-directional amplifier device includes an amplifier (C); a transmission direction determining device configured to determine a transmission direction of a data signal arriving at a bi-directional amplifying device and supply a switching control signal in accordance with a determined transmission direction, and a switching device configured to switch a state in accordance with a control signal so that amplifier (C) amplified the data signal in the transmission direction and transmitted the amplified data signal in the transmission direction by one hundred receiving ONU.

Options for additional technical solutions for a single-frequency half-duplex communication system are described below.

The device for determining the direction of transmission includes two detectors configured to determine the power of data signals transmitted respectively in two directions of transmission; and a comparator configured to determine a transmission direction by comparing powers determined respectively by two detectors.

The device for determining the direction of transmission further includes two amplifiers (E and G), configured to amplify the powers determined respectively by two detectors, and the comparing device determines the direction of transmission by comparing the powers amplified by amplifiers (E and G).

The device for determining the direction of transmission can determine the direction of transmission in accordance with the control signal of the transceiver sent from the first communication side or from the second communication side.

The first communication side or the second communication side includes a modulator configured to modulate a transceiver control signal supplied from the first or second communication side; and a mixer configured to mix the control transceiver signal modulated by the modulator with a data signal and transmit the mixed control transceiver signal and data signal to a bi-directional amplifier device.

The device for determining the direction of transmission includes a filter configured to extract the control signal of the transceiver from the signal supplied from the first or second side of the communication; and a demodulator configured to demodulate and issue a transceiver control signal allocated by the filter; moreover, the transceiver control signal demodulated by the demodulator serves as a switching control signal for controlling the state of the switching device.

The switching device includes two on-off single-pole switches connected respectively to the input and output of the amplifier (C).

The present invention further provides a method of single-frequency half-duplex communication, including determining the direction of transmission of the data signal to be amplified; amplifying the data signal in the transmission direction by means of an amplifier in accordance with the determined transmission direction; and transmitting the amplified data signal in the transmission direction to the receiving side.

Additional process options are described below.

Determining the direction of transmission includes determining the power of data signals transmitted in two directions of transmission, and determining the direction of transmission by comparing the power of data signals transmitted in two directions of transmission.

When determining the direction of transmission, the direction of transmission can be determined by using the control signal of the transceiver sent together with the data signal.

According to the present invention, a data signal transmitted bi-directionally at the same frequency can be amplified by determining the transmission direction of the data signal and amplifying the data signal transmitted in the transmission direction by an amplifier in accordance with the determined transmission direction.

Brief Description of the Drawings

Figure 1 is a structural block diagram of a full duplex communication system of the prior art.

FIG. 2 is a structural block diagram of a single frequency half duplex communication system according to a first embodiment of the present invention, where the switch is in the first state.

FIG. 3 is a structural block diagram of a single frequency half duplex communication system according to a first embodiment of the present invention, where the switch is in a second state.

FIG. 4 is a structural block diagram of a single frequency half duplex communication system according to a second embodiment of the present invention.

The implementation of the invention

The following describes in detail a single-frequency half-duplex communication system, a bi-directional amplifying device, and a single-frequency half-duplex communication method according to embodiments of the present invention with reference to FIGS. 2-4. A single-frequency half-duplex communication system includes a host 10 (20), a bi-directional amplifier 30 (40) and a number of terminals 50, while a number of terminals 50 are connected to a bi-directional amplifier 30 (40) through a distribution network. The bi-directional amplifier 30 (40) is configured to amplify a data signal supplied by the host 10 (20) or the terminal 50, and the host 10 (20) and the terminal 50 do not send data at the same time. Bidirectional amplifier 30 (40) performs the function of determining the direction of transmission and can amplify the transmitted data signal through amplifier C.

2 shows a single frequency half duplex communication system according to a first embodiment of the present invention. In this embodiment, a bi-directional amplifier 30 determines the direction of transmission using a detector.

The bi-directional amplifier 30 includes two detectors D and F connected to the host 10 and the terminal 50, respectively, and configured to determine the effective value of the power of the data signal transmitted by the host 10 and the terminal 50; two amplifiers E and G associated with the detectors D and F, respectively, and configured to enhance the effective power value at the output of the detectors D and F; a comparison device H, configured to determine a transmission direction by comparing the outputs of amplifiers E and G and supplying a switching control signal; two-position single-pole switches A and B, made with the possibility of switching the state in accordance with the switching control signal from the comparing device H in such a way as to transmit the data signal supplied by the transmission side to the input of amplifier C via the two-position single-pole switch A, while the amplifier C transmits a signal data to the receiving side after amplification of the data signal.

The operation process of the single-frequency half-duplex communication system according to the first embodiment of the present invention is described in detail below.

When host 10 is a transmission side, the data signal transmitted from host 10 after being detected by detector D is transmitted for amplification to amplifier E. Comparison device H compares the output voltages of amplifier E and amplifier G at the two inputs of comparison device N. At this point, since host 10 is in a transmission state, the voltage at the output of amplifier E is obviously higher than the voltage at the output of amplifier G. Comparison device H provides a switching control signal according to this comparison result. The switching control signal is transmitted to the two-position single-pole switches A and B, so that both two-position single-pole switches A and B are in a first state, as shown in FIG. Thus, the data signal of the host 10 is supplied to the amplifier C via the on-off single-pole switch A and transmitted to the terminal 50 through the on-off single-pole switch B after it has been amplified by the amplifier C.

When the terminal 50 is a transmission side, the data signal transmitted by the terminal 50 after being detected by the detector F is transmitted for amplification to the amplifier E. The comparing device H compares the output voltages of the amplifier E and the amplifier G at the two inputs of the comparing device H and provides a switching control signal in accordance with the comparison result so that both on-off single-pole switches A and B are in a second state (as shown in FIG. 3). Thus, the data signal of terminal 50 is supplied to amplifier C via a two-position single-pole switch A and transmitted to host 10 via a two-position single-pole switch B after it has been amplified by amplifier C.

FIG. 4 shows a single frequency half duplex communication system according to a second embodiment of the present invention. In this embodiment, the bi-directional amplifier 40 determines the transmission direction in accordance with the transceiver control signal from the host 20. When the bi-directional amplifier 40 receives the transceiver control signal from the host 20, the bi-directional amplifier 40 determines that the transmission direction is the direction from the host 20 to the terminal 50. In the case when the bi-directional amplifier 40 does not receive the control signal transceiver from the host 20, the bi-directional amplifier 40 determines that the direction of transmission is the direction with the term ala 50 to the host 20.

In this embodiment, the host 20 includes a modulator J and a mixer K. When the host 20 is a transmission side, the modulator J modulates the transmit and receive control signal and sends the modulated transmit and receive control signal to the mixer K. Mixer K mixes the data signal and the modulated transmit and receive control signal in one cable and collectively sends a data signal and a modulated control signal to a bi-directional amplifier 40.

The bi-directional amplifier 40 includes a filter L configured to recognize a control signal of the transceiver in the signal supplied from the host 20 (including the data signal and the control signal of the transceiver); a demodulator M, configured to demodulate the transceiver control signal recognized by the filter L; two-position single-pole switches A and B, made with the possibility of switching the state in accordance with the control signal of the transceiver demodulated by the demodulator M in order to transmit the data signal supplied by the transmitting side to the input of the amplifier C via the two-position single-pole switch A, while the amplifier C transmits a data signal to receiving side via a two-position single-pole switch B after amplification of the data signal. The two-position single-pole switches A, B and amplifier C in this embodiment are the same as in the first embodiment.

When the demodulator M provides a control signal for the transceiver, both two-position single-pole switches A and B are in a first state, as shown in FIG. 4. When the demodulator M does not provide a control signal for the transceiver, both two-position single-pole switches A and B are in the second state.

The operation process of the single frequency half duplex communication system according to the second embodiment of the present invention is described in detail below.

When host 20 is a transmission side, host 20 sends together a data signal and a modulated transceiver control signal to a bi-directional amplifier 40 via a modulator J and mixer K. Filter B of a bi-directional amplifier 40 extracts a transceiver control signal in the signal transmitted from the host 20 and sends a transceiver control signal to the demodulator M. The demodulator M controls the on-off single-pole switches A and B after demodulating the control signal of the transceiver in such a way that both on-off x SPDT switch A and B are in the first state, as shown in Figure 3. Thus, the data signal of the host 20 is supplied to the amplifier C using the on-off single-pole switch A and transmitted to the terminal 50 through the on-off single-pole switch B after amplification by the amplifier C.

When the terminal 50 is a transmission side, since the filter L does not detect a control signal of the transceiver, both two-position single-pole switches A and B are in a second state. Thus, the data signal of terminal 50 is supplied to amplifier C via a two-position single-pole switch A and transmitted to host 20 via a two-position single-pole switch B after amplification by amplifier C.

In this embodiment, the control of the change in state of the switch can also be performed by the control signal of the transceiver supplied by the terminal 50. The point here is similar to the case of controlling the change of state of the switch by the control signal of the transceiver provided by the host 20, so that it will not be described in detail again.

According to the technical solution of the embodiments of the present invention, the direction of transmission is determined by determining the intensity of the data signals sent from the host or from the terminal to the bi-directional amplifier, or by recognizing the control signal of the transceiver supplied by the host; and the switch is switched in accordance with a certain direction of transmission in order to amplify the transmitted data signal by means of an amplifier so that bidirectional signals can be transmitted at the same frequency, and the bandwidth is only half of the bandwidth in the prior art. Since the control signal is transmitted, the modulation method is simple and the bandwidth is small. Additionally, in the present invention, only one amplifier is used to amplify data signals in both directions, which reduces costs.

Those skilled in the art will appreciate the additional advantages and modifications. Thus, in a broad sense, the present invention is not limited to the specific details and exemplary embodiments shown and described herein. Accordingly, various modifications and changes can be made without departing from the spirit of the invention and without going beyond the scope of protection of the present invention, characterized by the attached claims and its equivalents.

Claims (9)

1. Bidirectional amplifier device comprising an amplifier (C) for amplifying a data signal transmitted in two directions at one frequency, comprising a transmission direction determination device configured to determine a power of data signals transmitted in two directions of transmission, respectively, and comparing two powers to determine the direction of transmission of the data signal entering the bi-directional amplifier device, as well as with the possibility of applying the switching control signal to etstvii with a particular transmission direction; and a switching device configured to switch the connection state in accordance with the switching control signal so that the amplifier (C) amplifies the data signal in the transmission direction and transmits the amplified data signal in the transmission direction to the receiving side. 2. The device according to claim 1, characterized in that the device for determining the direction of transmission contains two detectors configured to determine the power of data signals transmitted respectively in two directions of transmission; and a comparison device configured to compare the powers detected by the two detectors to determine a transmission direction and supply a switching control signal. 3. The device according to claim 2, characterized in that the device for determining the direction of transmission further comprises two amplifiers (E and G), configured to amplify the powers determined respectively by two detectors, and the comparison device determines the direction of transmission by comparing the powers amplified by amplifiers (E and G). 4. The device according to any one of claims 1 to 3, characterized in that the switching device comprises two on-off single-pole switches connected respectively to the input and output of the amplifier (C). 5. A single-frequency half-duplex communication system comprising at least one first communication side, at least one second communication side and a bi-directional amplifier device between the first communication side and the second communication side, the bi-directional amplifier device comprising an amplifier (C), a device determine the direction of transmission, made with the possibility of determining the power of data signals transmitted respectively in two directions of transmission, and comparing the two powers to determine the direction of the lane cottages data signal to the bidirectional amplifying device, and also to supply a switching control signal according to the determined transmission direction; and a switching device configured to switch the connection state in accordance with the switching control signal so that the amplifier (C) amplifies the data signal in the transmission direction and transmits the amplified data signal in the transmission direction to the receiving side. 6. The system according to claim 5, characterized in that the device for determining the direction of transmission contains two detectors configured to determine the power of data signals transmitted respectively in two directions of transmission; and a comparator configured to determine a transmission direction by comparing powers determined respectively by two detectors. 7. The system according to claim 6, characterized in that the device for determining the direction of transmission further comprises two amplifiers (E and G), configured to amplify the powers determined respectively by two detectors, and the comparison device determines the direction of transmission by comparing the powers amplified by amplifiers (E and G). 8. The system according to any one of claims 5 to 7, characterized in that the switching device comprises two on-off single-pole switches connected respectively to the input and output of the amplifier (C). 9. The method of single-frequency half-duplex communication, in which the direction of transmission of the data signal to be amplified is determined by determining the power of data signals transmitted respectively in two directions of transmission, and comparing the two powers; amplify the data signal in the transmission direction by means of an amplifier in accordance with the determined transmission direction and transmit the amplified data signal in the transmission direction to the receiving side.

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