FREQUENCY DIVISION MULTIPLE ACCESS COMMUNICATION METHOD BASED ON HARMONIC MODULATION TECHNOLOGY

Abstract

A method is disclosed that divide a total frequency band of a communication system into several equally spaced non-overlapping information channels, which are allocated to different users; the information channels are in one-to-one correspondence with the users; user signals from different addresses are distinguished based on frequency, thereby completing the multiple access connection; and duplex communication between two users uses a fundamental frequency and harmonics for information transmission. A process of the information transmission is as follows: different information is first modulated and then is separately loaded on different harmonic components, different information is transmitted through different harmonic components or component combinations so that each pair of information channels can transmit N groups of different information at the same time, and finally the fundamental frequency and harmonic information received by a receiving end is demodulated to obtain all the transmitted information.

Claims

1. A frequency division multiple access communication method based on harmonic modulation technology, wherein a total frequency band of a communication system is divided into several equally spaced non-overlapping information channels, which are allocated to different users; the information channels are in one-to-one correspondence with the users; user signals from different addresses are distinguished based on frequency, thereby completing a multiple access connection; and duplex communication between two users uses a fundamental frequency and harmonics for information transmission, realizing use of a pair of frequency channels to communicate with different users at the same time.

2. The frequency division multiple access communication method based on the harmonic modulation technology according to claim 1, wherein a process of the information transmission is as follows: different information is first modulated and then is separately loaded on different harmonic components, different information is transmitted through different harmonic components so that each pair of information channels can transmit N groups of different information at the same time, and finally the fundamental frequency and harmonic information received by a receiving end is demodulated to obtain all the transmitted information.

3. The frequency division multiple access communication method based on the harmonic modulation technology according to claim 2, wherein before the information transmission, a fixed harmonic mode is stored in advance and a given harmonic component is used to calculate all different signals, thereby demodulating a desired signal from other signals.

4. The frequency division multiple access communication method based on the harmonic modulation technology according to claim 3, wherein based on the fixed harmonic mode stored in advance, the given harmonic component is used to calculate all two different signals, so that a specific process of demodulating the desired signal from other signals is as follows: assuming that all harmonic modes are known:
V.sub.out=a.sub.0f.sub.0+a.sub.2f.sub.2+a.sub.3f.sub.3+a.sub.4f.sub.4+a.sub.5f.sub.5+ . . . +a.sub.nf.sub.m  (1) where a.sub.n represents a n-th harmonic coefficient, n=0, 2, 3, 4, . . . ; f.sub.0represents the fundamental frequency; f.sub.m represents a m-th harmonic component, and m=2, 3, 4, . . . ; at this time, both a first signal and a second signal are loaded on even and odd harmonics for transmission, respectively, and the following can be obtained:
V.sub.out.sup.p=a.sub.0.sup.pf.sub.0+a.sub.2.sup.pf.sub.2+a.sub.4.sup.pf.sub.4+a.sub.6.sup.pf.sub.6+a.sub.8.sup.pf.sub.8+ . . .   (2)
V.sub.out.sup.v=a.sub.0.sup.vf.sub.0+a.sub.3.sup.vf.sub.3+a.sub.5.sup.vf.sub.5+a.sub.7.sup.vf.sub.7+a.sub.9.sup.vf.sub.9+ . . .   (3) finally, a mixed signal of the first signal and the second signal received simultaneously at the signal receiving end is:
V.sub.out=a.sub.0.sup.vf.sub.0+a.sub.0.sup.pf.sub.0+a.sub.2.sup.pf.sub.2+a.sub.3.sup.vf.sub.3+a.sub.4.sup.pf.sub.4+a.sub.5.sup.vf.sub.5+a.sub.6.sup.pf.sub.6+a.sub.7.sup.vf.sub.7+a.sub.8.sup.pf.sub.8+a.sub.9.sup.vf.sub.9+ . . .   (4) it can be known from (1) and (4) that:
a.sub.0.sup.vf.sub.0+a.sub.0.sup.pf.sub.0=a.sub.0f.sub.0  (5)
a.sub.2.sup.pf.sub.2=a.sub.2f.sub.2; a.sub.4.sup.pf.sub.4=a.sub.4f.sub.4; a.sub.6.sup.pf.sub.6=a.sub.6f.sub.6; a.sub.8.sup.pf.sub.8=a.sub.8f.sub.8; . . .   (6)
a.sub.3.sup.vf.sub.3=a.sub.3f.sub.3; a.sub.5.sup.vf.sub.5=a.sub.5f.sub.5; a.sub.7.sup.vf.sub.7=a.sub.7f.sub.7; a.sub.9.sup.vf.sub.9=a.sub.9f.sub.9; . . .   (7) since the fundamental frequency used when transmitting the first signal and the second signal is the same, only the harmonic components are different, and it can be known from (5) that:
a.sub.0.sup.vf.sub.0=a.sub.0.sup.pf.sub.0=½a.sub.0f.sub.0  (8) therefore, according to formulas (6)-(8), the receiving end can demodulate both the first signal and the second signal.

5. The frequency division multiple access communication method based on the harmonic modulation technology according to claim 2, wherein when the different information is modulated and then is separately loaded on different harmonic components for information transmission, different combinations of harmonic components may further be selected for transmission of signals as needed.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] In order to more clearly illustrate the technical solutions in embodiments of the present disclosure or the prior art, the measures that need to be used in the description of the embodiments or the prior art will be briefly described below. Obviously, the drawings in the following description are only some embodiments of the present disclosure, and other drawings can be obtained by those of ordinary skill in the art from these without creative efforts.

[0019] FIG. 1 is a schematic diagram of a working principle of the conventional frequency division multiple access communication method;

[0020] FIG. 2 is a working schematic diagram of a frequency division multiple access communication method based on harmonic modulation technology; and

[0021] FIG. 3 is a harmonic modulation circuit diagram.

DETAILED DESCRIPTION

[0022] The present disclosure will be further described below in conjunction with a conventional frequency division multiple access communication method and a specific embodiment of the present disclosure:

[0023] The conventional frequency division multiple access communication method assigns a specific information channel to each user, and these information channels are allocated to users requesting services as required. During the entire call, other users cannot share this frequency band. It can be seen from FIG. 1 that in a Frequency Division Duplex (FDD) system, one information channel, i.e., a pair of frequency channels, is allocated to a user. One frequency channel is used as a forward (downlink) information channel, i.e. an information channel from a base station (BS) to a mobile station (MS); the other is used as a reverse (uplink) information channel, i.e. an information channel from the mobile station to the base station. The base station of this communication system must transmit and receive multiple signals of different frequencies at the same time; and communication between any two mobile users must be relayed through the base station, and thus 2 information channels (1 pair of frequency channels) must be occupied at the same time to achieve duplex communication. Since a pair of frequency channels can only communicate with one user, it causes a waste of frequency spectrum resources.

[0024] However, think about the natural communication between humans. For 7 billion people, its frequency bandwidth is only 20 Hz-20 kHz! Noise, animals, wind, trees and other natural sounds only occupy this bandwidth. However, the humans can easily identify them. For example, in a concert, many different instruments play the same melody, but the people can identify each instrument. The reason is that every instrument is playing the same pitch (the same fundamental frequency), but the modes of the harmonics are different. This shows that, in fact, harmonics can also carry information, and not only the fundamental frequency currently in common use can carry information.

[0025] Based on this, as shown in FIG. 2, the present embodiment sets forth a frequency division multiple access communication method based on a harmonic modulation technology, which is specifically as follows:

[0026] A total frequency band of a communication system is divided into several equally spaced non-overlapping information channels, which are allocated to different users; the information channels are in one-to-one correspondence with the users; user signals from different addresses are distinguished based on frequency, thereby completing a multiple access connection; and duplex communication between two users uses a fundamental frequency and harmonics for information transmission, realizing the use of a pair of frequency channels to communicate with different users at the same time.

[0027] Specifically, a process of the information transmission is as follows:

[0028] Different information is first modulated and then is separately loaded on different harmonic components, different information is transmitted through different harmonic components so that each pair of information channels can transmit N groups of different information at the same time, and finally the fundamental frequency and harmonic information received by a receiving end is demodulated to obtain all the transmitted information.

[0029] Herein, a harmonic modulation circuit is as shown in FIG. 3. An output of the harmonic modulation circuit is a sum of all input voltages. For inputs with the same fundamental frequency and different harmonic components, their outputs are different. Before the information transmission, a fixed harmonic mode needs to be stored in advance so that a given harmonic component can be used to calculate all different signals, thereby demodulating a desired signal from other signals.

[0030] For a better understanding, it is assumed that all harmonic modes are known (two signals need to be calculated):

V.sub.out=a.sub.0f.sub.0+a.sub.2f.sub.2+a.sub.3f.sub.3+a.sub.4f.sub.4+a.sub.5f.sub.5+ . . . +a.sub.nf.sub.m  (1)

where a.sub.n represents a n-th harmonic coefficient, n=0, 2, 3, 4, . . . ; f.sub.0 represents the fundamental frequency; f.sub.m ; represents a m-th harmonic component, and m=2, 3, 4, . . . ;

[0031] At this time, both a first signal and a second signal are loaded on even and odd harmonics for transmission, respectively, and the following can be obtained:

V.sub.out.sup.p=a.sub.0.sup.pf.sub.0+a.sub.2.sup.pf.sub.2+a.sub.4.sup.pf.sub.4+a.sub.6.sup.pf.sub.6+a.sub.8.sup.pf.sub.8+ . . .   (2)

V.sub.out.sup.v=a.sub.0.sup.vf.sub.0+a.sub.3.sup.vf.sub.3+a.sub.5.sup.vf.sub.5+a.sub.7.sup.vf.sub.7+a.sub.9.sup.vf.sub.9+ . . .   (3)

[0032] Finally, a mixed signal of the first signal and the second signal received simultaneously at the signal receiving end is:

V.sub.out=a.sub.0.sup.vf.sub.0+a.sub.0.sup.pf.sub.0+a.sub.2.sup.pf.sub.2+a.sub.3.sup.vf.sub.3+a.sub.4.sup.pf.sub.4+a.sub.5.sup.vf.sub.5+a.sub.6.sup.pf.sub.6+a.sub.7.sup.vf.sub.7+a.sub.8.sup.pf.sub.8+a.sub.9.sup.vf.sub.9+ . . .   (4)

[0033] It can be known from (1) and (4) that:

a.sub.0.sup.vf.sub.0+a.sub.0.sup.pf.sub.0=a.sub.0f.sub.0  (5)

a.sub.2.sup.pf.sub.2=a.sub.2f.sub.2; a.sub.4.sup.pf.sub.4=a.sub.4f.sub.4; a.sub.6.sup.pf.sub.6=a.sub.6f.sub.6; a.sub.8.sup.pf.sub.8=a.sub.8f.sub.8; . . .   (6)

a.sub.3.sup.vf.sub.3=a.sub.3f.sub.3; a.sub.5.sup.vf.sub.5=a.sub.5f.sub.5; a.sub.7.sup.vf.sub.7=a.sub.7f.sub.7; a.sub.9.sup.vf.sub.9=a.sub.9f.sub.9; . . .   (7)

[0034] Since the fundamental frequency used when transmitting the first signal and the second signal is the same, only the harmonic components are different, and it can be known from (5) that:

a.sub.0.sup.vf.sub.0=a.sub.0.sup.pf.sub.0=½a.sub.0f.sub.0  (8)

[0035] Therefore, according to formulas (6)-(8), the receiving end can demodulate both the first signal and the second signal.

[0036] In addition to the above, different combinations can be used to transmit the first signal and the second signal. For example, the first signal is loaded with the second and third harmonic components, and the second signal is loaded with the fourth harmonic component. When in actual use, different harmonic component combinations can be selected for transmitting the signals as needed.

[0037] In this embodiment, the harmonic modulation technology is mainly used to perform harmonic modulation on each pair of frequency channels (such as f.sub.1 and f′.sub.1), and the information to be transmitted is separately loaded on different harmonic components or component combinations, so that each pair of frequency channels can simultaneously transmit N Group different information. In this way, each pair of frequency channels may be used to simultaneously realize communication with N users without interference with each other, thereby greatly improving the utilization of existing frequency spectrum resources and alleviating the tension of frequency spectrum resources.

[0038] The embodiments described above are only preferred embodiments of the present disclosure, and do not limit the scope of implementation of the present disclosure. Therefore, any changes made according to the shape and principle of the present disclosure should be covered by the scope of protection of the present disclosure.