GB1566850A - Method and apparatus for distortion reduction in optical communication system - Google Patents

Description

(54) METHOD AND APPARATUS FOR DISTORTION REDUCTION IN OPTICAL COMMUNICATION SYSTEM (71) We, NORTHERN TELECOM LIMITED, a company organized under the laws of Canada of, 1600 Dorchester Blvd., West, Montreal, Quebec, Canada, H3HlR1, do hereby declare the invention for which we pray that a patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following statement: Field of the Invention The present invention relates to optical transmitters with reduced distortion of the optical output intensity. Such devices are particularly suited to analog transmission schemes in the field of optical fiber communications.

Background of the Invention The development of practical optical fiber systems has just begun. Such systems utilize modulated light sources, primarily semiconductor light emitting diodes (LEDs), the optical output of which is guided via an optical fiber link to a receiving site. The optical power energy emerging from the fiber then impinges upon a photodetector, usually a back-biased P-I-N semiconductor diode or the like, in which electrical charge carriers are generated and thereafter amplified to yield a useful output signal.

Hence, there are three crucial components in such systems. The optical power source or transmitter, the optical fiber link, and the photodetector or receiver. Should the transmission mode be analog, nonlinear distortion becomes a factor affecting the integrity of operation possibly to the extent that a practical system cannot be realized. The problem of nonlinear distortion is, of course, not new to optical fiber systems. It is, however, a stumbling block here more than in other systems because practical light sources such as LEDs produce a light output the intensity of which does not vary with sufficient linearity with the electrical input signal. As a result, second and third order nonlinearities would produce distortion in, say, a transmitted analog video signal, thereby limiting the quality of transmission. As a result, transmission over longer distances would not be possible.While of course the photodetector is also not fully linear, its contribution to distortion of the signal has been shown to be minimal in comparison with the LED produced distortion.

Summary of the Invention The present invention provides an optical transmitter, in a specific example utilizing LEDs as electrical-to-optical converters and photodetectors as optical-to-electrical converters, that produces an optical output signal more linearly related to the electrical input signal than has hitherto been possible. In simple terms, the final electrical-to-optical converter in the optical transmitter is modulated or excited by a modified electrical signal rather than by the original electrical input signal. As those skilled in the art will later on recognize, the amount of reduction in distortion will depend on the similarity of the electrical-to-optical transfer characteristics of the two electrical-to-optical converters utilized.

Accordingly there is provided an optical transmitter having two parallel signal paths and comprising signal dividing means connected to said first and second signal paths for coupling a first component of an electrical input signal to a first of said signal paths, and a second component of said input signal to a second of said signal paths, said first signal path including a first electrical-to-optical converter optically coupled to an optical-toelectrical converter, said second signal path providing a predetermined electrical delay, means providing the instantaneous difference between signals at the ends of said first and second signal paths, and a second electrical-tooptical converter connected to said means for converting said instantaneous difference into an optical output.

Although the above optical transmitter linearizes the optical output of less linear converters, it should be clear that the more linear the converters utilized the more linear is the final output. Such linearization it must also be understood, is accomplished at the cost of higher complexity as well as some degradation in the signal-to-noise ratio. The latter, however, may be ignored if the input signal-to-noise ratio is reasonable to begin with. The degradation of signal-to-noise ratio should not be considerably more than five decibels.

Brief Description of the Drawings An example embodiment will now be des cribed in conjunction with the accompanying drawings in which: Figure 1 is a schematic of an optical transmitter in accordance with the present inven tion; Figure 2 is a variation of the schematic of Figure 1; Figure 3 shows how a 1800 hybrid transformer may be used to provide the difference between two in-phase signals for use in the transmitters of Figures 1 or 2; Figure 4 shows a difference amplifier for forming the difference between two signals followed by an optical driver and a light emitting diode for use in the transmitters of Figures 1 or 2; Figure 5 shows how a P-I-N photodiode may be biased and connected to an optical receiver for use with the transmitters of Fieures 1 or 2; and Figure 6 is a variation on a portion of the schematic of Figure 1.

Description of the Example Embodiment With reference to Figure 1, the optical transmitter according to the present invention comprises a power divider 10 dividing a thereto input signal Sin into two signal com ponents S1 and S,. The signal S1 is applied to optical driver 11, driving (i.e. biasmg ana' moduianug) a light emitting diode (LED) 12, the optical output of which is coupled to a photodiode 13, such as a P-I-N photodiode, which is electrically coupled to an optical receiver 14. The output of the optical receiver 14 is fed into a subtracting port of a summer 15, the other adding port of which receives the signal S, delayed by a period r by means of a delay network 16.The delay r is chosen to be equal to the delay that the signal S is subjected to from the input of the optical driver 11 to the output of the optical receiver 14. The reason being that both S1 and S2 should arrive at the summer 15 having as close to 0" phase angle between them as is practicable. Usually T is a delay in the order of a few billionths of a second. The output of the summer 15 is fed into an identical optical driver 17 to the optical driver 11. The optical driver 17 also drives a LED 18 identical to the LED 12.

To explain how the circuit operates in simple terms, first, we consider only first order distortion cancellation effects. The signal S1 is converted via the optical driver 11 and the LED 12 into an equivalent optical signal (a1 S1+a), where a1 is an electrical-to-optical conversion factor, and A is the amount of distortion introduced by the LED 12. The optical signal (a1 S,+d) is coupled directly to the P-I-N photodiode 13 and converted therein into an electrical signal which is then amplified by the optical receiver 14. In the embodiment of Figure 1 the gain of the optical receiver 14 is such that the original electrical input signal Si emerges with the distortion A a1 added thereto.This, of course, assuming no distortion added by the P-I-N photodiode 13 and subsequent optical receiver 14. Thus, the signal Si experiences a total gain of unity from the input of the optical driver 11 to the output of the optical receiver 14. If the power divider 10 was such that S2=2S1, then the output signal at the output of the summer 15 would be:

The output optical power Soot of the LED 18 would be:

Of course, A al is much smaller than S1 and the distortion introduced by this term may be ignored for a first order approximation.In other words, the electrical signal S1 was converted to the optical signal Soot with the LED distortion absent A more elaborate analysis shows that all distortion is not fully eliminated. We assume that the LED transfer function is given by: SLE=al S+a2 S2+a, S3+a4S4+ where SLED is the optical output power of the LED and S the electrical signal current through the LED. al, of course, is the conversion efficiency of the LED. a2, a,, etc. are second, third, etc. order distortion factors, and it is often sufficient to consider terms only up to a,. Performing the analysis for the circuit of Figure 1 with S2=2Sl we find that, theoretically, there are no second order dis tnrtion products present. The third order distortion products would be reduced if:

Those skilled in the art will recognize that the above condition would often apply. Yet higher order distortion products are negligible and will not be considered.

Turning now to Figure 2 of the drawings, we discuss a more general case than that considered in conjunction with Figure 1. In the path of the signal S2 there is added an amplifier 19 providing a gain (or loss) factor equal to K+1 2 In addition, the path of the signal S1 is assumed in Figure 2 to have a general gain (or loss) factor of G. Assuming for the moment that G=1, then for K=1 we have again the case of Figure 1, i.e. second order distortion cancellations. To cancel, third order distortion K should assume a different value from unity, namely K should satisfy the cubic equation:

Such equation always has a real root, which root is the desired value for K. In practice, adjustment of the gain of the amplifier 19 would permit an intermediate optimal setting.

One may choose a point between full cancellation of either of the second or third order distortion products.

A still more general case is given for G different from unity, in which case it can be shown that for second order distortion cancellation K should be as follows: K=2G- 1.

This means that the gain factor of the ampll ber 19 K+1 2 must equal G. Again, by varying K, third instead of second order distortion cancellation may be achieved.

Whether one opts for second or third order cancellation, it will be recognized that a general reduction will result in most distortion products. Clearly the higher the order of the distortion product, the less pronounced is the improvement.

Before proceeding to describe some other subsidiary details it should be mentioned that second harmonic distortion was reduced by some 25 dB and third harmonic distortion by some 15 dB in a measurement along the lines of the embodiment shown in Figure 1. These improvements were achieved at fundamental frequencies varying from a few KHz to a few MHz. The components used were off-the-shelf components. For instance, for the summer 15, a 1800 hybrid was used as shown in Figure 3. Since the input signals E1 and Ei (Si and S in Figure 1) are in-phase the 1800 hybrid produces their difference. Such a hybrid is supplied by Anzac as part N HH108 for 0.2 to 35 MHz.

Another alternative to the arrangement of Figure 3 is that shown in Figure 4 of the drawings. There a difference amplifier 20 is used. Such devices are common in the art of signal processing. The difference amplifier 20 then feeds an optical driver 21 directly. An excellent optical driver suitable for such applications has been disclosed in an article entitled: "A 120 MHz Bandwidth Linear Signal Transmission System Using Fiber Optics" by James C. Blackburn in the IEEE Transactions on Instrumentation and Mersurements, 1975, pp. 23W232, Figure 4 on p.

231. Of course, other less elaborate amplifiers may suffice for some applications. Such an optical driver directly biases and modulates the LED 18.

As to optical receivers, an arrangement such as that shown in Figure 5 of the drawings is often suitable. In that Figure a reverse biasing resistor R is utilized, its value usually chosen to optimize the noise behaviour of subsequent amplifier 22. A suitable simple amplifier is part No. XL 152 of Texas Instruments. On the other hand, RCA supplies an integral photodiode/amplifier arrangement under part No.

C30818/819, particularly suitable for analog applications up to several MHz.

Figure 6 of the drawings shows yet another arrangement for achieving the same result of distortion reduction. In this arrangement, the path of the signal S is split into two paths carrying equal signal powers. The additional path is delayed by delay network 27 so that both signals arriving at a final summer 26 arrive in phase. The main path from the delay network 16 goes through an amplifier/ attenuator to ensure that the signals arriving at a first summer 24 have the same magnitude.

The output of the summer 24 is then fed through an amplifier 25 and on to the summer 26, the output of which drives the final optical driver. For K= 1, second order distortion products will be cancelled as was the case in Figure 1, but for K as follows:

the third order distortion products will cancel.

and the second order distortion products will be less if

The above condition generally always applied.

Again, one may choose to optimize between second and third order cancellation by setting K to have an intermediate value, preferably by means of practical experimentation.

WHAT WE CLAIM IS: 1. An optical transmitter having two parallel signal paths and comprising: signal dividing means connected to said first and second signal paths for coupling a first component of an electrical input signal to a first of said signal paths, and a second component of said input signal to a second of said signal paths; said first signal path including a first elec trical-tooptical converter optically coupled to optical-toelectrical converter; said second signal path providing a predetermined electrical delay; means providing the instantaneous difference between signals at the ends of said first and second signal paths; and a second electrical-to-optical converter connected to said means for converting said instantaneous difference into an optical output.

2. The optical transmitter according to claim 1, said first and second electrical-tooptical converters having similar electrical-tooptical transfer characteristics, and said delay provided by said second optical path being substantially equal to the total delay of said first signal path.

3. The optical transmitter according to claim 2, said first and second electrical-tooptical converter being semiconductor light emitting diodes, and said optical-toelectrical converter being a semiconductor photodiode.

4. The optical transmitter according to claim 3, said second signal path including means for adjusting the signal power therethrough.

5. The optical transmitter according to claims 1, 2 or 3, said first component of said input signal containing half the power con tained in said second component.

6. The optical transmitter according to claim 1, 2 or 3, said signals at the ends of said first and second signal paths containing signal powers in the ratio of (K + 1): G, G being the quotient of the power at the end of said first signal path by the power at its beginning, and K being a predetermined real number.

7. An optical transmitter substantially as described herein in conjunction with the accompanying drawings.

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (7)

**WARNING** start of CLMS field may overlap end of DESC **. and the second order distortion products will be less if The above condition generally always applied. Again, one may choose to optimize between second and third order cancellation by setting K to have an intermediate value, preferably by means of practical experimentation. WHAT WE CLAIM IS:

1. An optical transmitter having two parallel signal paths and comprising: signal dividing means connected to said first and second signal paths for coupling a first component of an electrical input signal to a first of said signal paths, and a second component of said input signal to a second of said signal paths; said first signal path including a first elec trical-tooptical converter optically coupled to optical-toelectrical converter; said second signal path providing a predetermined electrical delay; means providing the instantaneous difference between signals at the ends of said first and second signal paths; and a second electrical-to-optical converter connected to said means for converting said instantaneous difference into an optical output.

2. The optical transmitter according to claim 1, said first and second electrical-tooptical converters having similar electrical-tooptical transfer characteristics, and said delay provided by said second optical path being substantially equal to the total delay of said first signal path.

3. The optical transmitter according to claim 2, said first and second electrical-tooptical converter being semiconductor light emitting diodes, and said optical-toelectrical converter being a semiconductor photodiode.

4. The optical transmitter according to claim 3, said second signal path including means for adjusting the signal power therethrough.

5. The optical transmitter according to claims 1, 2 or 3, said first component of said input signal containing half the power con tained in said second component.

6. The optical transmitter according to claim 1, 2 or 3, said signals at the ends of said first and second signal paths containing signal powers in the ratio of (K + 1): G, G being the quotient of the power at the end of said first signal path by the power at its beginning, and K being a predetermined real number.

7. An optical transmitter substantially as described herein in conjunction with the accompanying drawings.