DE19801223C2 - Method for transmitting a microwave or millimeter wave signal along an optical transmission path - Google Patents

Description

The invention relates to a method for transmitting a microwave or Millimeter wave signal along an optical transmission path according to the preamble of Claim 1.

Optical microwave and millimeter wave transmission (the latter is described in the following) The term microwave transmission is generally included) is among others for the supply the base stations of mobile radio systems with high radio frequencies of great interest. there becomes an optical microwave signal in a suitable manner at the beginning of the transmission path generated, transmitted via optical fibers and at the base station by means of a photodiode, the one has sufficient cutoff frequency received. This means that the base station is immediately available electrical microwave signal, consisting of a subcarrier and often imprinted Signal modulation, available.

To generate and transmit this microwave subcarrier, but also to imprint the Signal modulation, some methods are known. An overview can be found e.g. B. in "Optical Microwave Technology for Future Cellular Mobile Networks "by R.-P. Braun and co-authors in Telecommunications / Electronics, Berlin, Vol. 45, pp. 63 ff., September 1995.

For the practical implementation, above all those processes are of interest, which involve the The electrical signal obtained in the photodiode is essentially independent of the quality Dispersion of the optical transmission link is. This is not the case with all procedures. Known methods for the dispersion-independent acquisition of microwave signals are under among others that of L. Noel, D. Marcenac and D. Wake: "Optical millimeter-wave generation technique with high efficiency, purity and stability. "in Electronics Letters, Vol. 32, pp. 1997 f., October 1996, proposed arrangement with master and slave lasers, by H. Schmuck: "Comparison of optical millimeter-wave system concepts with regard to chromatic dispersion." in Electronics Letters, Vol. 31, pp. 1848 f., October 1995, discussed methods with external Double sideband modulation with suppressed carrier or that of G.H. Smith, D. Novak and Z. Ahmed: "Overcoming chromatic-dispersion effects in fiber-wireless systems incorporating external modulators. "in IEEE Transactions on Microwave Theory and Techniques, Vol. 45, p. 1410, August 1997, proposed method with external single sideband modulation.  

In US 5 596 436 optical filters are used for the selection of microwave sidebands to achieve a dispersion-independent transmission. In US 5 596 436 this is Optical source output signal with multiple independent microwave signals necessarily different frequency modulated, this signal mixture over a optical transmission path and after division of the optical signal one each this microwave signals selected by optical filtering and fed to a photo receiver. It is imperative to mix down into the baseband.

From DE 197 10 033 C1 a generic method is also known, in which the optical signals combined in a fiber bus are fed to an external optical modulator, which is driven by it with a desired subcarrier frequency (f _sub ) or a subharmonic. The method is intended to convert various signals in the baseband or intermediate frequency range, which have been impressed on optical carriers of different wavelengths, to a microwave or millimeter-wave subcarrier with the aid of a component, the optical demultiplexing carried out here being used exclusively for optical channel separation.

The object of the invention is to provide a simple method in which one A microwave signal can be taken from the photodiode, the power of which is independent of is the dispersion of the optical transmission link and that is particularly for Wavelength division multiplex systems are suitable.

According to the invention, the object is achieved by a method having the features of claim 1 solved. Advantageous refinements of the method are defined in subclaims 2 to 6 specified.

It is essential to the invention that a simple linear optical phase modulator with the half subcarrier frequency is operated and an optical filtering takes place in addition to the optical carrier only allows the first two sidebands for detection with the photodiode. The resulting signal at the subcarrier frequency is therefore independent of the dispersion the optical transmission path. The procedure is particularly useful when using a optical wavelength division multiplex system. Here, only an external one Phase modulator required for subcarrier generation of all optical channels, and the necessary filtering is done simply by demultiplexing the optical channels.

With the external phase modulation of an optical carrier signal E (t) = E ₀ cos (ω _c t) (f _c = ω _c / 2π light frequency) with the modulation frequency f _m = ω _m / 2π

E (t) = E ₀ [J ₀ (m) cosω _c t - J ₁ (m) sin (ω _c ± ω _m ) t - J ₂ (m) cos (ω _c ± 2w _m ) t + + - - , , .],

where J _k (m) denote the Kth order Bessel functions with the modulation index m as argument.

The result is the carrier as well as numerous modulation sidebands, which, however, are generally extinguished when directly detected by means of a photodiode and are therefore not directly detectable. If this signal is transmitted over an optical fiber link, the modulation sidebands experience an additional phase shift relative to the carrier due to the fiber dispersion. If the dispersion is assumed to be linear, the following signal results:

E (t) = E ₀ [J ₀ (m) cosω _c t - J ₁ (m) sin (ω _c ± ω _m + ϕ) t - J ₂ (m) cos (ω _c ± 2ω _m + 4ϕ) t + + - -. , .]

with ϕ = πcDL (ω _m / ω _c ) ² and ϕ _k = k ² ϕ (for the kth sideband), as well as the dispersion parameter D, the transmission length L and the speed of light c. Direct reception is now possible, but this is strongly dependent on D, L, and ω _m . With a constant modulation frequency, there is a sine distribution of the power over the fiber length. At certain transmission distances, total signal extinction occurs, e.g. B. at f _m = 60 GHz after about 2 km in standard fiber at 1550 nm.

Optical filtering of the first two sidebands results

E (t) = E ₀ [J ₀ (m) cosω _c t - J ₁ (m) sin (ω _c ± ω _m + ϕ) t],

from which the optical power, which is proportional to the photocurrent, can be calculated:

I _PD ~ E ² (t) / E ₀ ² = -2J ₀ (m) J ₁ (m) sinϕcosω _m t + J ₁ ² (m) cos2ω _m t.

It can be seen that the term with cos2ω _m t is not a function of the dispersion phase angle ϕ. This is the microwave signal obtained in the method according to claim 1. The modulation frequency is therefore doubled and a signal is obtained at the photodiode that is independent of the dispersion of the transmission link, a phase modulator being used. The phase modulator has the advantage over a Mach-Zehnder intensity modulator that it has a much simpler internal structure and only half the modulation power is required for its control. In addition, the optical modulation signal is twice as strong, which is why an electrical power gain of 6 dB compared to a Mach-Zehnder modulator is achieved on the photodiode (according to W. Nowak, M. Sauer: "Dynamic range increase in optical microwave subcarrier systems through dispersion management", MIOP '97, Sindelfingen, April 1997).

This method can be used particularly advantageously in a WDM system according to M. Sauer, W. Nowak: "Simultaneous upconversion of several channels in mm-wave subcarrier transmission systems for wireless LANs at 60 GHz. ", Microwave Photonics (MWP'97), Duisburg / Essen, September 1997. Here, a plurality of optical carrier signals is generated by means of one single modulator impressed the subcarrier signal. The filtering then takes place simultaneously with the already necessary demultiplexing of the optical channels, d. H. the demultiplexers transmit only the carrier with the first two side bands. The Demands of frequency stability and filter characteristics of the demultiplexers are included not very high, since it is microwave or millimeter wave signals and the  next sidebands, which need to be heavily damped, further away from the wearer lie. The filter edge must be between the first and second sidebands.

The invention is explained in more detail below using an exemplary embodiment. In the Show drawing

Fig. 1 shows a transmission link designed according to the invention

Fig. 2, the optical signal spectrum to a laser diode (LDI)

Fig. 3, the optical signal spectrum after the multiplexer (MUX)

Fig. 4, the optical signal spectrum after the phase modulator (MOD)

Fig. 5 shows the spectral arrangement of the optical filter (FI) in an optical channel

Fig. 6, the optical signal spectrum of a channel after the demultiplexer (DEMUX)

In Fig. 1 a according to the invention formed transmission path is shown. A number of laser diodes (LD1 to LDn) of different emission wavelengths (λ ₁ to λ _n ) (representation of an optical signal spectrum of any laser diode in FIG. 2), which can be modulated with the modulation signals P ₁ to P _n , are by means of a multiplexer (MUX ) combined on a fiber bus (FB). The resulting signal spectrum is shown in FIG. 3, where Δλ is the optical channel spacing. This signal mixture is modulated by means of an external phase modulator (MOD) with the frequency f _m , which corresponds to half the subcarrier frequency. The resulting signal spectrum is shown in FIG. 4. The signal is transmitted via optical fibers (LWL), which can have any dispersion. Demultiplexing (DEMUX) is carried out in such a way that only the first two modulation sidebands are transmitted, which is shown in FIG. 5. The Δλ _-3dB bandwidth of the filter (FI) must be selected so that the modulation sidebands with the distance f _m from the carrier frequency pass the filter, while the sidebands with higher frequency spacings are strongly attenuated. The resulting signal spectrum is shown in FIG. 6. The photodiodes (PD1 to PDn) in FIG. 1 now each receive a signal spectrum corresponding to FIG. 6 of a carrier wavelength assigned to them (λ ₁ to λ _n ). The dispersion-independent signals at the subcarrier frequency in the millimeter wave range (P _{sub, 1} to P _{sub, n} ) can be taken from the photodiodes.

Claims (6)

1. A method for transmitting a microwave or millimeter wave signal along an optical transmission path, in which a microwave or millimeter wave signal can be taken at the output, the power of which is independent of the dispersion of the optical transmission path, in which the output signal of a laser diode (LDi) or other suitable narrowband optical source, a microwave signal in the intermediate frequency range (P _i ) is impressed, characterized in that the optical signal is modulated by means of an external phase modulator (MOD) with a micro or millimeter wave signal (f _m ), which is more than has twice the frequency of the intermediate frequency signal, after transmission via a dispersion-based optical transmission path, the optical filtering is carried out in such a way that, in addition to the optical carrier, only the first two sidebands of the signal, which was modulated with the phase modulator (MOD), together with the this Sideband existing intermediate frequency signal are supplied to the photo receiver (PDi), the useful signal (P _{sub, i} ) being obtained from the mixture of these two side band signals together with the intermediate frequency signal in the photo receiver (PDi). 2. The method according to claim 1, characterized in that the optical transmission path is used in an optical wavelength division multiplex system, the output signals from laser diodes (LDi) or other suitable narrowband optical sources of different emission wavelengths (λ _i ) each independent microwave signals in Intermediate frequency range (P _i ) are impressed, these optical output signals are then merged into a fiber bus (FB), these optical signals combined in the fiber bus are modulated using an external phase modulator (MOD) with a micro or millimeter wave signal (f _m ), which has a frequency that is more than twice as high as the highest intermediate frequency signal, and that after the transmission over a dispersion-based optical transmission path, the demultiplexing is carried out in such a way that, in addition to the optical carrier, only the first two sidebands of the signal transmitted with the phase modulator (MOD) encouraging was coded, together with the intermediate frequency signal present around these sidebands, to the photo receiver (PDi), the useful signal (P _{sub, i} ) being obtained from the mixture of these two sideband signals together with the intermediate frequency signal in the photo receiver (PDi). 3. The method according to claim 2, characterized in that the demultiplexing for all optical Channels are carried out simultaneously with a component (DEMUX). 4. The method according to claim 2, characterized in that the demultiplexing distributed with several multiplexers. 5. The method according to claim 2 and 3 or 4, characterized in that the Sideband selection after demultiplexing by one or more suitable optical filters is done or improved. 6. The method according to claim 1, 2, 3, 4 or 5, characterized in that an optical Amplifier for all or individual optical channels is used.