DE3808892A1 - Amplifier for light with equal amplitudes of the output pulses - Google Patents

Abstract

The repeaters used in optical communication are intended, inter alia, to convert a series of optical input pulses of variable amplitude into a series of output pulses of equal but amplified amplitude. The device proposed here consists of an electrical parallel circuit of a controlling element 10, for example a photoconductor, a photodiode or a photodiode connected to active electronic components, and of an optical amplifier 11 which has a constant current IE flowing through them. The current flowing through the controlling element is, in the simplest case, proportional to the intensity of the input pulses, and the amplification of the optical amplifier is proportional to the current which flows through it. In this way, a current-controlled amplification of the optical amplifier is achieved, at the output of which there then appears a series of pulses of equal intensity. <IMAGE>

Description

The invention relates to an amplifier for light same amplitudes of the output pulses, e.g. in optical communication in repeaters is used.

When transmitting data via optical fibers the light pulses are not only due to dispersion deformed, but it also decreases as a result of damping Signal level. When transmitting over long distances therefore provide amplifiers (repeaters) that the incoming impulses to a uniform level lift and undo the pulse deformation. The present invention relates to incoming Light pulses of different amplitude (intensity) in a sequence of output pulses of the same amplitude To convert (intensity).

The previously known solutions to generate the same optical output pulses Amplitude work as follows:  

At the entrance of a repeater intended for this purpose there is a converter that has a Optical impulses arriving in converts electrical impulses. This converter is one downstream electronic amplification device, which amplifies the electrical impulses thus obtained. The output of the electronic amplifier is again with a converter, e.g. a semiconductor laser connected, the electrical impulses into light impulses transformed back. The output from this converter The pulses are then regulated to the same amplitude.

The known solutions have the disadvantage that they require a large amount of circuitry by converting "light pulses - electrical pulses - light pulses". In addition, the amplification of electrical pulses in the gigabit range is not easy to handle.

The object of the invention is therefore a technically simple and at high Transfer rates safe to handle or amplifier To specify repeaters with the optical input pulses different amplitude in optical output pulses same amplitude to be converted.

This problem is solved by a device with the Combination of features of the main claim. The Subclaims contain refinements and Developments of the invention.

The device according to the invention has the advantage that because of the direct optical amplification of the Circuit effort reduced. Are also high Transfer rates with direct optical amplification  easier to handle than by using the electronic amplification. Another advantage is in the simple way of controlling or regulating the Amplification of the optical amplifier to see that through an electrical parallel connection of optical Amplifier and photoelectric converter is achieved.

In the following, several embodiments of the Invention described and with reference to the figures explained. Show it:

Fig. 1 shows the basic structure of the device according to the invention,

FIG. 2a to 2c, circuit examples.

In Fig. 1, 10 is a controlling element, which can be a photoconductor, a photodiode, a phototransistor or the interconnection of a photodiode or a transistor. 11 denotes an optical amplifier, 12 a partially reflecting mirror and 13 a mirror. 14 identifies the power supply to the control element 10 and to the optical amplifier 11 . 15 and 16 identify signal profiles, which will be discussed in more detail below. A light beam designated A reaches the partially reflecting mirror 12 , from which it is broken down into the two partial beams B and C. The optical path C with mirror 13 can also be designed, for example, as a glass fiber or as a waveguide. Part C reaches the control element C via the mirror 13 , part B reaches the input of the optical amplifier 11 . The light beam A consists of light pulses of different amplitudes. The same applies to the two beams B and C. The maximum possible intensity of the incident light beam A is P _E. Due to the fiber attenuation, not all incoming light pulses have the same intensity. For the intensity of the individual light pulses at A , y × P _E generally applies, the relationship 0 less than Y less than 1. If the partially reflecting mirror has the reflectivity R , the light intensity P ₂ = (1- R) × y × P _E reaches the optical amplifier 11 . The intensity P ₁ = R × y × P _E reaches the controlling element 10 . The time course of the intensity of the input beam A or the beams B and C is denoted by 15 in FIG. 1. _A light beam denoted by D with pulses of the same intensity P _A , denoted by 16 in FIG. 1, leaves the output of the optical amplifier 11 . In the controlling element 10 , charge carriers are generated in proportion to the incoming light intensity P ₁ , whereby the resistance of this element changes. The change in resistance results in a change in the current I ₁ . Since the total current I _{E is} constant, the current I _{2 also changes} . If the optical amplifier 11 is designed so that its gain is proportional to the current I ₂ flowing through the amplifier, then a very simple gain control can be achieved in certain areas. A light signal D with pulses of the same intensity is then available at the output of the optical amplifier 11 . A reconstruction of the pulse shape following the amplifier is only sensibly possible if there are pulses of the same intensity or amplitude.

Fig. 2 shows a plurality of circuit examples for realizing the invention. A photoconductor 21 is connected in parallel to the optical amplifier 20 in FIG. 2a, and a photodiode 22 in FIG. 2b. In Fig. 2c, the current flowing through the optical amplifier 20 current is controlled by a transistor 23, whose base is connected to a photodiode 22. Integrated arrangements in which the photodiode and the transistor are designed as a phototransistor are also conceivable. This arrangement has the advantage that non-linear effects, such as occur in the simple photoconductor or photodiode arrangement, can be compensated for directly by the phototransistor. All three exemplary embodiments shown can be produced with discrete components, but also monolithically integrated on a chip, for example with the materials InP, InGaAsP. Due to the integrated design, the device can be used up to very high data transmission rates. To control the amplification of the optical amplifier 20 , the operating points of the photoconductor 21 or the photodiode 22 or the combination of photodiode 22 and transistor 23 must be set accordingly. The linearization of the characteristic curves of the individual components required for this purpose is not derived here since it is not the subject of the invention.

Claims (10)

1. Device for converting optical input pulses of variable amplitude into amplified optical output pulses of the same amplitude with a gain-controllable amplifier and a gain-controlling element, characterized in that the amplifier and the controlling element are electrically connected in parallel. 2. Device according to claim 1, characterized in that the amplifier is an optical amplifier. 3. Device according to claims 1 and 2, characterized in that the parallel circuit consisting of the amplifier and the controlling element is flowed through by a constant current I _E. 4. The device according to claim 3, characterized in that a partial current I _{1 of} the current I _E flows through the controlling element and a partial current I _{2 of} the current I _E flows through the amplifier. 5. The device according to claim 4, characterized in that the current flowing through the controlling element I ₁ depends on the amplitude of the optical input pulses. 6. The device according to claim 5, characterized in that the amplification of the optical amplifier is controlled by the current I ₂ flowing through it. 7. The device according to one or more of claims 1 to 6, characterized in that the controlling element is a photoconductor. 8. The device according to one or more of claims 1 to 6, characterized in that the controlling element is a photodiode. 9. The device according to one or more of claims 1 to 6, characterized in that the controlling element a combination of a transistor and one Is a photodiode or an integrated phototransistor. 10. Device according to claims 1 to 9, characterized by their use in repeaters at optical communication.