DE102022201069A1 - Electro-optical balun and system for generating a pseudo-differential signal, comprising such an electro-optical balun - Google Patents

Abstract

The invention relates to an electro-optical balun, the electro-optical balun having an input for an optical input signal (In(t)), the electro-optical balun further having a 1x2 multimode interferometer (1x2 MMI) and a phase shifter (Δϕ), the 1x2 multimode interferometer ( 1x2 MMI) can be supplied with the input signal during operation, the electro-optical balun further having a 2x4 multimode interferometer (2x4 MMI), the 2x4 multimode interferometer (2x4 MMI) being connected to the output arms of the 1x2 multimode interferometer (1x2 MMI), the phase shifter ( Δϕ) is arranged in an output arm of the 1x2 multimode interferometer (1x2 MMI), with a quasi-differential optical signal being present at two outputs (Eout,1(t), Eout,4(t)) of the 2x4 multimode interferometer (2x4 MMI) during operation, which can be converted into a DC-free electrical signal (Vout) by means of a respective photodiode (PD1, PD2) and a differential circuit.Furthermore, the invention relates to a system for generating a pseudo-differential signal, having an electro-optical balun and an optical beam splitter (OS ) and a dual output carrier injection Mach Zehnder modulator (MZM), where the optical beam splitter (OS) splits an input signal (IIN) into a first part (n) and a second part (1-n), the second part (1 -n) is fed as an input signal (Ein(t)) to the input of the electro-optical balun during operation, the first part (n) being fed to the dual output carrier injection Mach Zehnder modulator (MZM) as an input signal during operation, the quasi differential electrical signal (I1, I2) of the photodiodes (PD1, PD2) is used in operation to control the dual output carrier injection Mach Zehnder modulator (MZM) in push-pull configuration.

Description

The invention relates to an electro-optical balun and a system for generating a pseudo-differential signal having such an electro-optical balun.

background

Photodiodes can only generate electric currents that are proportional to the square of the absolute value of the electric field strength I _photo ∝ |E _IN | ² as already in "Analysis and Simulation of a Wireless Phased Array System with Optical Carrier Distribution and an Optical IQ. Return Path," by the authors S. Kruse, C. Kress, HG Kurz, T. Schneider, JC Scheytt in 2020 13th German Microwave Conference (GeMiC), March 2020, pages 1-4.

It is therefore not possible to generate a differential electrical signal directly by means of a photodiode PD. In addition, a parasitic dark current I _Dark flows through the individual photodiodes, so that I= _anode =I _Dark +I _Photo flows out of the anode, or I _cathode =I _Dark -I _Photo flows into the cathode (see also "Fully-differential , DC-coupled, self-biased, monolithically-integrated optical receiver in 0.25µm photonic BiCMOS Technology for multi-channel fiber links", authors S. Gudyriev, JC Scheytt, L. Yan, C. Meuer and L. Zimmennann,, published in 2017 IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM), Miami, FL, 2017, pp. 110-113). Thus, in addition to the desired signal current I _photo , there is an undesired current I _Dark , which corrupts the signal. If you apply a single optical input signal directly to the inputs of two photodiodes connected in parallel, it is therefore not possible to generate a differential signal without external circuitry.

From the prior art, e.g. B. from the book "Design of integrated circuits for optical communications", B. Razavi, McGraw-Hill, 2003, it is known after the transimpedance amplifier (English Transimpedance Amplifier abbreviated TIA), which generates a voltage from the photocurrent, to use an amplifier to create a differential signal. The second input of the differential amplifier is fed with the low-pass filtered signal of the transimpedance amplifier.

Another direct approach in which the photocurrent of the photodiode was tapped directly is from the article "High-speed receiver based on waveguide germanium photodetector wire-bonded to 90 nm SOI CMOS amplifier" by the authors Huapu Pan, Solomon Assefa, William M. J. Green, Daniel M. Kuchta, Clint L. Schow, Alexander V. Rylyakov, Benjamin G. Lee, Christian W. Baks, Steven M. Shank, and Yurii A. Vlasov published in Opt. Express 20, 18145-18155 (2012). Here, an AC coupling was provided between the photodiode and the differential transimpedance amplifier by means of capacitors.

However, this leads to increased noise, higher input capacitance, which limits the bandwidth, and a high area requirement. The high area requirement is due, among other things, to the fact that capacitors require a large amount of space. In addition, this approach is only suitable for bandpass signals.

In order to circumvent these problems, a DC-coupled transimpedance amplifier (TIA) presented.

However, this transimpedance amplifier has the disadvantage that the current through the photodiode never changes direction. Thus, the output of the transimpedance amplifier is non-differential, as is the photocurrent.

To solve the non-differential currents problem, a DC compensation unit could be used.

However, this compensation unit increases the complexity of the circuit, since a closed control loop is necessary.

Finally, the known systems are designed to work in cooperation with a transimpedance amplifier.

Proceeding from this, it is an object of the invention to provide a circuit that allows differential electrical currents to be generated by means of photodiodes.

The object is solved by a system with optical carrier distribution according to one of the independent claims. Advantageous configurations are the subject matter of the dependent claims, the description and the figures.

• 1 ein beispielhaftes Blockschaltbild eines optischen Baluns gemäß einer Ausführungsform der Erfindung,
• 2 ein beispielhaftes Blockschaltbild eines optischen Baluns gemäß einer Ausführungsform der Erfindung mittels einem 1x2 Multimodeninterferometers (MMI), eines optischen Phasenschiebers und einem 2x4 MMI,
• 3 ein beispielhaftes Blockschaltbild eines optischen Baluns gemäß einer Ausführungsform der Erfindung mittels drei 1x2 bzw. 2x1 MMIS, einem Phasenschieber und einem 2x4 MMI,
• 4 ein beispielhaftes Blockschaltbild eines optischen Baluns gemäß einer Ausführungsform der Erfindung mittels drei 1x2 bzw. 2x1 MMIS und einem 2x4 MMI, und
• 5 ein beispielhaftes System zur Generierung eines (pseudo-) differentiellen Signals, aufweisend einen elektrooptischen Balun gemäß einer Ausführungsform der Erfindung.

The invention is explained in more detail below with reference to the figures. In these shows:

• 1 an exemplary block diagram of an optical balun according to an embodiment of the invention,
• 2 an exemplary block diagram of an optical balun according to an embodiment of the invention using a 1x2 multimode interferometer (MMI), an optical phase shifter and a 2x4 MMI,
• 3 an exemplary block diagram of an optical balun according to an embodiment of the invention using three 1x2 or 2x1 MMIS, a phase shifter and a 2x4 MMI,
• 4 an exemplary block diagram of an optical balun according to an embodiment of the invention using three 1x2 or 2x1 MMIS and a 2x4 MMI, and
• 5 an exemplary system for generating a (pseudo) differential signal comprising an electro-optical balun according to an embodiment of the invention.

In the following the invention will be illustrated in more detail with reference to the figures. It should be noted that different aspects are described, which can be used individually or in combination. That is, each aspect can be used with different embodiments of the invention unless explicitly presented as purely alternative.

Furthermore, for the sake of simplicity, only one entity will generally be referred to below. Unless explicitly noted, however, the invention can also have several of the entities concerned. In this respect, the use of the words “a”, “an” and “an” is only to be understood as an indication that at least one entity is used in a simple embodiment.

Insofar as methods are described below, the individual steps of a method can be arranged and/or combined in any order, unless something different is explicitly stated in the context. Furthermore, the procedures can be combined with one another unless otherwise expressly indicated.

Specifications with numerical values are generally not to be understood as exact values, but also include a tolerance of +/- 1% to +/- 10%.

References to standards or specifications are to be understood as references to standards or specifications which are/were applicable at the time of filing and/or - if priority is claimed - at the time of priority filing. However, this is not to be understood as a general exclusion of applicability to subsequent or superseding standards or specifications.

Insofar as multimode interferometers are referred to below, the designations of the shape are to be understood merely as an indication that this is the desired configuration with regard to an effect. If, in principle, a multimode interferometer can do more, but if the effect according to the designation is caused, e.g. by suitable wiring/control, then this is of course also included in the spirit and claim of the invention.

In 1 1 is an exemplary block diagram of an optical balun according to an embodiment for generating differential currents in photodiodes. From an optical signal E _IN (t), the signal is interfered with itself in the optical balun, with a current I _PD1,2 α R|E _IN (t)| ² (I _DC ± I _Offset ) is generated. This means that an optical signal is generated, which is converted into a quasi-differential signal in the photodiode. Here R is the sensitivity of the photodiode, while I _DC and I _offset are two DC components that arise from constructive and destructive interference. Unlike the prior art, this current can be used in any differential circuit and is no longer tied to a transimpedance amplifier. The DC component can be filtered out in any suitable differential circuit, so that the effective current I _eff = 2R|E _IN (t)| ² (I _Offset ) is available.

The optical balun according to embodiments of the invention requires neither DC compensation nor AC coupling to generate a differential electrical signal. The output signal V _OUT or E _OUT,1 (t) and E _OUT,2 (t) can be used in any differential circuit and is not necessarily dependent on a transimpedance amplifier. Thus, when designing the system, you can do without extra chip area for capacitors and you don't have to invest any design effort in a stable control loop and no power loss is required in the control loop.

The optical balun can be implemented in different variants.

In an embodiment according to 2 the electro-optical balun has an input for an optical input signal E _in (t). Furthermore, the electro-optical balun has a 1x2 multimode interferometer 1x2 MMI and a phase shifter Δφ, with the 1x2 multimode interferometer 1x2 MMI being able to be supplied with the input signal during operation.

In addition, the electro-optical balun also has a 2x4 multimode interferometer 2x4 MMI, the 2x4 multimode interferometer 2x4 MMI being connected to the output arms of the 1x2 multimode interferometer 1x2 MMI, the Phase shifter Δϕ is arranged in an output arm of the 1x2 multimode interferometer 1x2 MMI. In principle, a multimode interferometer, in particular the 1x2 MMI, can be used to generate the optical output signal.

During operation, a quasi-differential optical signal is present at two outputs E _out,1 (t), E _out,4 (t) of the 2x4 multimode interferometer 2x4 MMI, which is converted into a DC by means of a respective photodiode PD ₁ , PD ₂ and a differential circuit -free electrical signal V _out can be transferred.

In one embodiment of the invention, the electrical balun is designed such that signals are picked up at two further outputs E _out,2 (t), E _out,3 (t) of the 2x4 multimode interferometer 2x4 MMI and fed to a control loop for optical phase adjustment can.

This embodiment of the electro-optical balun has the advantage that both outputs 1 and 4 of the 2x4 MMI can be used as inputs for the photodiodes PD1, PD2 and a control circuit for optical phase adjustment can be implemented with the other two outputs (outputs 2 and 3). . It can be shown mathematically that the greatest output power is in output 1 & 4 of the 2x4 MMi when the other two outputs no longer have any output power. Furthermore, an electro-optical balun can also be realized with the optical outputs 1-4 of the 2x4 MMI and four photodiodes by superposition of the four electric currents.

Another embodiment of the invention is 3 shown.

Again, the electro-optical balun has an input for an optical input signal E _in (t). Again, the electro-optical balun has a 1x2 multimode interferometer 1x2 MMI and a phase shifter Δφ, with the 1x2 multimode interferometer 1x2 MMI being able to be supplied with the input signal during operation.

In addition, the electro-optical balun has a 2x4 multimode interferometer 2x4 MMI, the 2x4 multimode interferometer 2x4 MMI being connected to the output arms of the 1x2 multimode interferometer 1x2 MMI, the phase shifter Δϕ being arranged in an output arm of the 1x2 multimode interferometer 1x2 MMI.

In contrast to the design of 2 two first output arms of the 2x4 multimode interferometer 2x4 MMI are now routed to a first 2x1 multimode interferometer 2x1 MMI in order to obtain a first optical output signal E _out,1 (t), and two second output arms of the 2x4 multimode interferometer 2x4 MMI to a second 2x1 multimode interferometer 2x1 MMI out to obtain a second optical output signal E _out,4 (t).

During operation, a quasi-differential optical signal is present at two outputs E _out,1 (t), E _out,4 (t) of the 2x4 multimode interferometer 2x4 MMI, which is converted into a DC by means of a respective photodiode PD ₁ , PD ₂ and a differential circuit -free electrical signal V _out can be transferred.

This embodiment of the electro-optical balun has the property that the maximum output power is delivered when the optical phase shift between the inputs of the 2x4 MMI is 90°. This can be realized compactly by accurate modeling of a broadened waveguide.

Furthermore, there are only two optical output signals which can be converted directly into differential currents in the photodiodes PD1, PD2.

Another embodiment of the invention is 4 shown.

The electro-optical balun in turn has an input for an optical input signal E _in (t) and a 1x2 multimode interferometer 1x2 MMI, with the 1x2 multimode interferometer 1x2 MMI being able to be supplied with the input signal during operation.

In contrast to the embodiments of 2 and 3 this embodiment has no phase shifter.

Furthermore, the electro-optical balun comprises a 2x4 multimode interferometer 2x4 MMI, the 2x4 multimode interferometer 2x4 MMI being connected to the output arms of the 2x1 multimode interferometer 1x2 MMI.

Two first output arms of the 2x4 multimode interferometer 2x4 MMI are routed to a first 2x1 multimode interferometer 2x1 MMI in order to obtain a first optical output signal E _out,1 (t), and two second output arms of the 2x4 multimode interferometer 2x4 MMI are routed to a second 2x1 multimode interferometer 2x1 MMI out to obtain a second optical output signal E _out,4 (t).

During operation, a quasi-differential optical signal is present at two outputs E _out,1 (t), E _out,4 (t) of the 2x4 multimode interferometer 2x4 MMI, which is generated by means of a respective photodiode (PD ₁ , PD ₂ ) and can be converted into a DC-free electrical signal V _out in a differential circuit.

This embodiment of the electro-optical balun has the property that the sensitivity of the circuit is significantly better (about twice as good) than that according to the embodiment 3 . As a result, in this circuit in particular, the provision of a (further) control algorithm can be dispensed with. In addition, there are only two optical output signals that can be converted directly into differential currents in the photodiodes PD1, PD2. Alternatively or additionally, these two signals can be distributed to other units using optical splitters.

One can the embodiments of 3 and 4 also describe to the effect that two outputs of the 2x4 multimode interferometer 2x4 MMI serve as inputs of the 2x1 multimode interferometer 2x1 MMI.

A use of the electro-optical balun according to the invention in a system for generating a (pseudo) differential signal is outlined below.

In an exemplary use in a system for generating a (pseudo) differential signal, an electro-optical balun, an optical beam splitter OS and a dual output electro-optical modulator, e.g. a dual output carrier injection Mach Zehnder modulator MZM, are connected.

An optical modulator in the form of a dual output carrier injection Mach-Zehnder modulator (MZM) is e.g. from the article "First demonstration of SiGe-based carrier-injection Mach-Zehnder modulator with enhanced plasma dispersion effect" by the authors Younghyun Kim, Junichi Fujikata, Shigeki Takahashi, Mitsuru Takenaka, and Shinichi Takagi, published in Opt. Express 24, 1979-1985 (2016).

The optional carrier injection MZMs are particularly suitable for this task, since the phase change in the phase shifters of the MZM is generated by currents.

As an alternative to this, however, other phase shifters can also be used which change their phase as a function of the current.

This means that no additional conversion of the current into voltage using a transimpedance amplifier is necessary.

The optical beam splitter OS divides an input signal I _IN into a first part n and a second part 1-n, the second part 1-n being fed as an input signal E _in (t) to the input of the electro-optical balun during operation, the first part n is fed to the dual output carrier injection Mach Zehnder modulator MZM in operation as an input signal, the quasi-differential electrical signal I1, I2 of the photodiodes PD ₁ , PD ₂ being used to control the dual output carrier injection Mach Zehnder modulator MZM in push pull configuration is used.

In an embodiment of the invention, the beam splitter OS is asymmetric, i.e. n<>1/2.

Thus, all components required for the system are available in commercial photonic IC technologies.

This allows the system to be integrated cost-effectively.

Furthermore, current injection phase shifters with a few 100 μm are very space-saving, which further reduces the overall price overall. The use of the push-pull configuration eliminates the modulation of the phase and the associated chirp.

The band-stop filters can be implemented both optically and, after conversion into electrical quantities, electrically. It should be noted that the output frequency of the invention is twice the input frequency.

However, since many wireless systems upconvert a carrier into a mm-wave band in the front ends, the invention can save another stage.

Claims (6)

Electro-optical balun, • wherein the electro-optical balun has an input for an optical input signal (E _in (t)), • wherein the electro-optical balun further comprises a 1x2 multimode interferometer (1x2 MMI) and a phase shifter (Δϕ), the 1x2 multimode interferometer (1x2 MMI) can be supplied with the input signal during operation, • the electro-optical balun also has a 2x4 multimode interferometer (2x4 MMI), the one 2x4 multimode interferometer (2x4 MMI) being connected to the output arms of the 1x2 multimode interferometer (1x2 MMI), the phase shifter (Δϕ) is arranged in an output arm of the 1x2 multimode interferometer (1x2 MMI), • in operation at two outputs (E _out,1 (t), E _out,4 (t)) of the 2x4 multimode interferometer (2x4 MMI) a quasi-differential optical signal applied by means of a respective photodiode (PD ₁ , PD ₂ ) and a differential circuit in a DC-free electrical signal (V _out ) can be transferred. Electro-optical balun after claim 1 , characterized in that signals are picked up at two further outputs (E _out,2 (t), E _out,3 (t)) of the 2x4 multimode interferometer (2x4 MMI), which can be supplied to a control loop for optical phase adjustment. Electro-optical balun, • wherein the electro-optical balun has an input for an optical input signal (E _in (t)), • wherein the electro-optical balun further comprises a 1x2 multimode interferometer (1x2 MMI) and a phase shifter (Δϕ), the 1x2 multimode interferometer (1x2 MMI) can be supplied with the input signal during operation, • the electro-optical balun also having a 2x4 multimode interferometer (2x4 MMI), the 2x4 multimode interferometer (2x4 MMI) being connected to the output arms of the 1x2 multimode interferometer (1x2 MMI), the phase shifter ( Δϕ) is arranged in an output arm of the 1x2 multimode interferometer (1x2 MMI), • whereby two first output arms of the 2x4 multimode interferometer (2x4 MMI) are routed to a first 2x1 multimode interferometer (2x1 MMI) in order to generate a first optical output signal )E _out,1 ( t)), and where two second output arms of the 2x4 multimode interferometer (2x4 MMI) are led to a second 2x1 multimode interferometer (2x1 MMI) to obtain a second optical output signal )E _out,4 (t)), • where im Operation at two outputs (E _out,1 (t), E _out,4 (t)) of the 2x4 multimode interferometer (2x4 MMI) a quasi-differential optical signal is applied, which means of a respective photodiode (PD ₁ , PD ₂ ) and a differential Circuit in a DC-free electrical signal (V _out ) can be converted. Electro-optical balun, • wherein the electro-optical balun has an input for an optical input signal (E _in (t)), • wherein the electro-optical balun further comprises a 1x2 multimode interferometer (1x2 MMI), wherein the 1x2 multimode interferometer (1x2 MMI) with the input signal im operation can be supplied, • wherein the electro-optical balun further comprises a 2x4 multimode interferometer (2x4 MMI), wherein the 2x4 multimode interferometer (2x4 MMI) is connected to the output arms of the 1x2 multimode interferometer (1x2 MMI), • wherein two first output arms of the 2x4 multimode interferometer (2x4 MMI) are routed to a first 2x1 multimode interferometer (2x1 MMI) to obtain a first optical output signal (E _out,1 (t)), and two second output arms of the 2x4 multimode interferometer (2x4 MMI) are routed to a second 2x1 multimode interferometer (2x1 MMI) are guided to obtain a second optical output signal E _out,4 (t)), • wherein during operation at two outputs (E _out,1 (t), E _out,4 (t)) of the 2x4 multimode interferometer (2x4 MMI) a quasi-differential optical signal is present, which can be converted into a DC-free electrical signal (V _out ) by means of a respective photodiode (PD ₁ , PD ₂ ) and a differential circuit. System for generating a pseudo-differential signal, having an electro-optical balun according to one of the preceding claims and an optical beam splitter (OS) and a dual output carrier injection Mach Zehnder modulator (MZM), the optical beam splitter (OS) an input signal (I _IN ) in a first part (n) and a second part (1-n), the second part (1-n) being fed as an input signal (E _in (t)) to the input of the electro-optical balun during operation, the first part (n) is fed to the dual output carrier injection Mach Zehnder modulator (MZM) as an input signal during operation, with the quasi-differential electrical signal (I ₁ , I ₂ ) of the photodiodes (PD ₁ , PD ₂ ) being used during operation to control the dual output carrier injection Mach Zehnder Modulator (MZM) in push-pull configuration is used. system after claim 5 , characterized in that the beam splitter (OS) is asymmetrical.

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