Abstract
Microwave photonics has adopted a number of important concepts and technologies over the recent pasts, including photonic integration, versatile programmability, and techniques for enhancing key radio frequency performance metrics such as the noise figure and the dynamic range. However, to date, these aspects have not been achieved simultaneously in a single circuit. Here, we report a multi-functional photonic integrated circuit that enables programmable filtering functions with record-high performance. We demonstrate reconfigurable filter functions with record-low noise figure and a RF notch filter with ultra-high dynamic range. We achieve this unique feature using versatile complex spectrum tailoring enabled by an all integrated modulation transformer and a double injection ring resonator as a multi-function optical filtering component. Our work breaks the conventional and fragmented approach of integration, functionality and performance that currently prevents the adoption of integrated MWP systems in real applications.
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Introduction
As radio frequency (RF) and microwave systems are moving forward into cognitive operation, reconfigurable filter will become a key component to enable the full potential of these systems' performance1,2,3. This filter can intelligently operate to differentiate the RF signal of interest from the interferers4,5,6. There is a need of developing reconfigurable filter for modern RF systems to address the challenges impeding the use of active electronically scanned array (AESA) that operate at a wide range of frequencies in dense RF environment7. The filter is aimed to make the array in AESA more resistant to interference before signal processing8. Integrated microwave photonic (MWP) can offer significant advantages to realize advanced concepts of reconfigurable filter for multi-band, all spectrum communications9 and broadband programmable front-ends10, which are important for modern RF communications (i.e. cognitive radio). To play a key role in modern RF applications, integrated MWP circuits need to simultaneously show advanced programmability and exceptional performance in terms of low losses, low noise figure, and high dynamic range in a reduced footprint11,12,13,14,15. In recent pasts, a number of programmable integrated MWP filters have widely been demonstrated16,17,18,19,20. Typically, these filters were achieved in application-specific circuits, and the measured RF metrics were only sparsely reported. The values of the RF gain, noise figure (NF), and spurious-free dynamic range (SFDR) in these circuits are usually far-off from the requirements for practical RF systems.
Recently, new ways of building a programmable integrated MWP circuit have been extensively explored, for example, through mesh circuit that can synthesize a large number of functionalities through programming21,22,23,24. While versatile, the typical functional performance of these circuits, such as filter extinction, or passband quality and the RF metrics were significantly lower than that of application-specific circuits25,26,27,28. Thus, at present, the unique and well-sought combination of high integration density, versatile programmability and high RF performance remains elusive. A versatile modulation transformer (MT) that can tailor the phases and amplitudes of optical carrier and RF sidebands has recently been identified as a key element for enhancement of dynamic range29,30,31,32. On the other hand, a programmable resonator such as a double-injected ring resonator (DI-RR)33 can provide a large number of filtering functions. However, there remains a bottleneck in co-integrating components that support NF reduction and linearization with components that provide functionalities.
In this work, we demonstrate a programmable integrated MWP circuit with a unique combination of a versatile MT device and a DI-RR, realized in a low-loss silicon nitride platform. With this circuit, we show an array of RF filters in three different scenarios simultaneously with record-low NF for RF notch and RF bandpass filter, achieved using low-biasing technique25,26 in an intensity modulator (IM)-based system, and ultra-high dynamic range for RF notch filter, achieved using on-chip linearization in a phase modulator (PM)-based system. The capability of the proposed reconfigurable filter is expected to improve the system performance across S-band through Ku-band (i.e. 2 GHz to 18 GHz) frequency range and play a key role for the realization of practical programmable integrated MWP circuit that can operate in congested RF environment.
Results
Programmable microwave photonics
The concept of ultrahigh dynamic range and low NF programmable integrated MWP filter explored here is illustrated in Fig. 1. The MT shapes the input modulated signal from an optical modulator to the desired modulation format that is suited for the targeted filtering function. The spectral shaping can equally provide a basis for creating bespoke phase and amplitude distribution of the optical carrier and sidebands, leading to linearization and NF reduction. The DI-RR is used as a reconfigurable spectral filtering element that can provide notch or bandpass filtering. In this way, high dynamic range and programmable filtering can be achieved simultaneously.
The MT is implemented as an asymmetric Mach-Zehnder interferometer (aMZI) loaded with 3 ring resonators as a spectral de-interleaver29,34, combined with a tunable attenuator and a phase shifter (see Supplementary Information A). The DI-RR is an add-drop ring resonator that is double-injected from single input, hence capable of synthesizing a large number of responses (see Supplementary information B). The schematic of the entire circuit overlaid on a photograph of the fabricated silicon nitride chip is shown in Fig. 2a. The waveguide propagation loss in the circuit is 0.1 dB/cm and the fiber-to-chip coupling loss is 1.1 dB/facet.
We demonstrate the programmability of our circuit by showing the conversion of modulation formats, as well as the flexible switching among various filtering functions. We exemplify the intensity modulation-to-phase modulation (IM-PM) conversion by inverting the phase of one sideband by π, which leads to sideband cancellation with 62 dB extinction in direct photodetection (Fig. 2b). Conversely, with a phase modulator input, the circuit can achieve PM-IM conversion with an increase in the extinction of up to 64 dB (Fig. 2c). The DI-RR, on the other hand, can synthesize a variety of responses from a single output port, including notch filter, bandpass filter, Fano-like response, and an all-pass response35, as shown in Fig. 2d–g. Benefiting from the low propagation loss of the silicon nitride waveguide, a fine spectral resolution of around 400 MHz in the filtering function can be achieved with 20 GHz free spectral range (FSR).
High gain and low noise figure MWP filter
We carried out a series of MWP filtering experiments with a setup diagrammed in Fig. 3a. A high power optical source is sent to a low-biased IM. We then configure our MT to shape the IM spectrum into a dedicated output spectrum suitable for the filtering tasks provided by the DI-RR. In particular, we synthesized two RF filters, namely RF notch filter and RF bandpass filter with simultaneously high RF performance metrics (see Supplementary Information C for details of the extended experimental scenarios).
Figure 3b shows the measured RF notch filter with 58 dB rejection and 3-dB bandwidth of 400 MHz. The high rejection in the filter was achieved through phase cancellation16,36 enabled by adjusting the phase and amplitude of the isolated sideband in intensity modulation-to-asymmetric dual sidebands modulation (IM-aDSB) conversion. Through low biasing of the IM, we then achieved an optimum measured RF gain of 10 dB and a lowest measured NF of 15 dB (Fig. 3c). These high gain and low noise figure translated into a high SFDR of 116 dB Hz2/3 when we performed a two-tone test at the frequency of 1 GHz (Fig. 3d). It can be seen that the third-order input intercept ponts (IIP3) can be estimated to be +16 dBm with the measured noise power spectral density (PSD) of −149 dBm/Hz. These results represent the best RF gain, noise figure, and SFDR combination for an MWP notch filter. The RF notch filter central frequency can be tuned from 5 to 20 GHz (Fig. 3b) with a maximum RF gain of more than 0 dB over the frequency range (see Supplementary Information D).
We then program the MT and the DI-RR to exhibit RF bandpass filter with 20 dB rejection, with up to 15 GHz tuning range (from 5 GHz to 20 GHz) (Fig. 3e), limited by the roll-off and the dispersion of the spectral de-interleaver, notably at the transition band (see Supplementary Information A). This tuning range can be feasibly increased using an improved design of (de)-interleaver with faster roll-off and a larger FSR. We measured RF gain of 1.2 dB and NF of 21.8 dB (Fig. 3f). Taking into account the measured noise PSD of −151 dBm/Hz, the SFDR at 7 GHz is 112 dB Hz2/3 and the IIP3 can be estimated to be +16 dBm (Fig. 3g). The versatility of the MT allows for the combination of low biasing and single-sideband (SSB)-based RF bandpass filtering, which would have not been possible only with an IM or a dual-parallel Mach–Zehnder modulator (DPMZM). As a result, we can demonstrate the best combination of measured NF and SFDR for an RF bandpass filter. Importantly, these results were achieved without using any electrical amplification in the system.
On-chip linearization for ultrahigh dynamic range
Applications of MWP systems usually require ultra-high SFDR of beyond 120 dB Hz2/315. Although such a metric can be achieved through linearization of the modulator transfer function37,38,39,40, it remains challenging to achieve linearization simultaneously with functionalities. Here, we demonstrate simultaneous RF notch filter and linearization by using the combination of MT and DI-RR circuits in the same photonic chip.
We implement third-order intermodulation distortion (IMD3) cancellation technique using complex multi-order sidebands spectral shaping as we previously reported31,41,42 (see Supplementary Information E and F). In this experiment, light is sent to a phase modulator (PM) (Fig. 4a) that generates the optical carrier and first and higher order sidebands. The MT is used to convert the PM to aDSB modulation format, and to shape the amplitudes and phases of the optical carrier and multi-order sidebands yielding to IMD3 suppression. The DI-RR is then used to filter the first order sideband to create a phase cancellation RF notch filter. In this way, simultaneous RF notch filter and linearization can be achieved, leading to a significant SFDR enhancement (see Supplementary Information E and F).
A standard SSB RF notch filter without any linearization was used as a benchmark for the proposed linearized RF notch filter. Figure 4b shows the proposed linearized RF notch filter with >45 dB rejection improvement compared to the standard SSB RF notch filter. With the linearization, we achieved 29 dB of IMD3 suppression (Fig. 4c) and 20 dB SFDR improvement (Fig. 4d). With a noise PSD of −164.5 dBm/Hz and estimated IIP3 of +15 dBm, the standard SSB RF notch filter shows an SFDR of 103 dB Hz2/3, while the linearized RF notch filter exhibits a record-high SFDR of 123 dB Hz4/5. It is clear from the slope of the measured IMD3 powers that the fifth-order distortion becomes the dominant factor due to cancellation of the third-order distortion. Similar record-high SFDR also can be observed in different frequencies (see Supplementary Information G). These results marked the highest SFDR simultaneously achieved with on-chip signal functionality.
DISCUSSION
Table 1 summarizes the performance comparison of existing reconfigurable filter circuits. The route to largest number of functions is still provided through MZI-mesh circuits22. Virtually all demonstrations, except the application specific RF notch filter reported in ref. [25], show relatively low RF performance, notably characterized by very high NF (>25 dB) and low SFDR (<100 dB Hz2/3). These results highlight the challenge in creating multifunctional and high-performance MWP circuits. Our results overcome this challenge by delivering high level of reconfigurability with a variety of functions in combination with high gain, low NF, and ultrahigh SFDR. Importantly, in the context of functional circuits, our demonstrations represent record-low NF and record-high SFDR to date.
At present, our approach enables NF reduction through low biasing of MZM intensity modulator. This translates into moderate SFDR enhancement as seen in Table 1. Our linearization method, on the other hand, is working for PM-based MWP filter where maximum IMD3 suppression is achieved when the optical carrier is partially suppressed (See Supplementary Information D). Due to the limitation in maximum optical amplification in our experimental setup, the measured ultra-high SFDR is still accompanied by relatively low link gain and high NF (Table 1). Achieving the gain, NF, and SFDR advantages simultaneously is feasible in the PM link when higher optical amplification and higher power handling components are used. Because the current linearization method only works in PM-based MWP notch filter, a similar strategy development is desirable for low-biased IM-based MWP filters.
At the current state, the positive RF gain in both IM-based MWP filters is achieved using two external erbium-doped fiber amplifiers (EDFAs). The recent advances in low-noise amplification using erbium-doped waveguide amplifiers in silicon nitride43 can offer a high-performance integrated MWP system with low weight and reduced footprint.
In summary, we have designed, fabricated, and experimentally demonstrated programmable integrated MWP circuit based on a unique combination of versatile MT and equally versatile DI-RR. We reconfigure the circuit to synthesize an array of RF filtering functions with high RF gain, low NF, and ultrahigh SFDR concurrently. This work opens a new paradigm and an important step to realize programmable integrated MWP circuits with versatile functions, low NF, and ultra-high dynamic range suited for real-life applications.
Methods
Silicon nitride circuit fabrication
The waveguides in our circuit are fabricated using LioniX standard TriPleX Asymmetric Double-Stripe (ADS) geometry44,45. First, a SiO2 layer is grown from wet thermal oxidation of single-crystal silicon substrate with temperatures equal to or above 1000 ∘C. Then, low-pressure chemical vapor deposition (LPCVD) is used for the Si3N4 layers and together with the gas tetraethylorthosilicate (TEOS) for the intermediate SiO2 layer. Next, the waveguides are patterned using contact lithography, and processed with dry etching. Last, the waveguides are covered with an additional SiO2 layer through LPCVD TEOS. Because typical top cladding thickness cannot be achieved only by LPCVD TEOS, plasma-enhanced chemical vapor deposition (PECVD) is used to increase the SiO2 top cladding thickness to a total of 8 μm. Thicker layers can be achieved because of the stress in PECVD SiO2 layers is much less than LPCVD layers.
Details of programmable microwave photonics experiments
A laser (Pure Photonics PPCL550) with low relative-intensity noise (RIN) of -155 dB/Hz is amplified with a low-noise erbium-doped fiber amplifier (EDFA, Amonics). Then, the output of amplified optical carrier is modulated using a MZM (Thorlabs, LNLVL-IM-Z 40 GHz, Vπ,RF of 2.2 V at 1 GHz and 3.5 V at 20 GHz) with bias point set at quadrature (θB = π/2). The MZM is driven by an RF signal from a vector network analyzer (VNA, Keysight P5007A). The output of the MZM then sent to another low-noise EDFA (Amonics) before being injected into a programmable silicon nitride chip (LioniX International BV) fabricated using low-loss TriPleX (Si3N4/SiO2) technology44,45 with propagation loss of the optical waveguide at 0.1 dB/cm. The chip is tuned using thermo-optic tuning and a custom-made heater controller software, while being stabilized by a thermoelectric cooler (TEC) controller. The processed optical signal is sent to a photodetector (PD, APIC 40 GHz) and the converted RF signal is measured with a VNA, while the RF spectrum analyzer (RFSA, Keysight N9000B) is used to measure the RF filter’s noise and linearity.
Details of linearization experiments
A low RIN laser (Pure Photonics PPCL550) is modulated using a PM (EOSpace 20 GHz) using a sweeping RF signal with −3 dBm power from VNA (Keysight P5007A) for RF notch filter experiment. For the IMD3 suppression experiment, the two-tone RF signal with a power of −0.5 dBm, centered at 9 GHz with a space of 10 MHz from signal generators (Wiltron 69147A and Rohde-Schwarz SMP02) is used to drive the PM. The modulated signal is then amplified by a low-noise EDFA (Amonics), before coupling to a programmable silicon nitride chip (LioniX International BV). The chip is tuned using thermo-optic elements and stabilized by a TEC controller. The processed optical spectrum is sent to a PD (APIC 40 GHz) to retrieve the RF signal and measured using the VNA for the filter’s response, and the RFSA (Keysight N9000B) for linearity.
Data availability
The data that support the plots within this paper and the supplementary materials are available at https://doi.org/10.4121/21207662.
References
Naglich, E. J., Lee, J., Peroulis, D. & Chappell, W. J. A tunable bandpass-to-bandstop reconfigurable filter with independent bandwidths and tunable response shape. IEEE Trans. Microw. Theory Tech. 58, 3770–3779 (2010).
Lee, J., Naglich, E. J., Sigmarsson, H. H., Peroulis, D. & Chappell, W. J. New bandstop filter circuit topology and its application to design of a bandstop-to-bandpass switchable filter. IEEE Trans. Microw. Theory Tech. 61, 1114–1123 (2013).
Yang, T. & Rebeiz, G. M. Bandpass-to-bandstop reconfigurable tunable filters with frequency and bandwidth controls. IEEE Trans. Microw. Theory Tech. 65, 2288–2297 (2017).
Chiou, Y.-C. & Rebeiz, G. M. A tunable three-pole 1.5-2.2-GHz bandpass filter with bandwidth and transmission zero control. IEEE Trans. Microw. Theory Tech. 59, 2872–2878 (2011).
Naglich, E. J., Lee, J., Peroulis, D. & Chappell, W. J. Switchless tunable bandstop-to-all-pass reconfigurable filter. IEEE Trans. Microw. Theory Tech. 60, 1258–1265 (2012).
Fan, M., Song, K., Zhu, Y. & Fan, Y. Compact bandpass-to-bandstop reconfigurable filter with wide tuning range. IEEE Microw. Wirel. Compon. Lett. 29, 198–200 (2019).
Defense Advance Research Project Agency. Coffee program jump-starts integrable filtering for wideband superiority. https://www.darpa.mil/news-events/2022-06-01. Accessed September 2022.
Advance Research Project Agency. Filtering out interference for next-generation wideband arrays. https://www.darpa.mil/news-events/2021-06-10. Accessed September 2022.
Akyildiz, I. F., Kak, A. & Nie, S. 6g and beyond: the future of wireless communications systems. IEEE Access 8, 133995–134030 (2020).
Chappell, W. J., Naglich, E. J., Maxey, C. & Guyette, A. C. Putting the radio in “software-defined radio”: Hardware developments for adaptable rf systems. Proc. IEEE 102, 307–320 (2014).
Capmany, J. & Novak, D. Microwave photonics combines two worlds. Nat. Photonics 1, 319 (2007).
Yao, J. Microwave photonics. J. Lightwave Technol. 27, 314–335 (2009).
Capmany, J. et al. Microwave photonic signal processing. J. Light. Technol. 31, 571–586 (2012).
Marpaung, D. et al. Integrated microwave photonics. Laser Photonics Rev. 7, 506–538 (2013).
Marpaung, D., Yao, J. & Capmany, J. Integrated microwave photonics. Nat. Photonics 13, 80–90 (2019).
Marpaung, D. et al. Si3n4 ring resonator-based microwave photonic notch filter with an ultrahigh peak rejection. Opt. Express 21, 23286–23294 (2013).
Shahnia, S., Pagani, M., Morrison, B., Eggleton, B. J. & Marpaung, D. Independent manipulation of the phase and amplitude of optical sidebands in a highly-stable rf photonic filter. Opt. Express 23, 23278–23286 (2015).
Fandiño, J. S., Muñoz, P., Doménech, D. & Capmany, J. A monolithic integrated photonic microwave filter. Nat. Photonics 11, 124–129 (2017).
Liu, Y., Choudhary, A., Marpaung, D. & Eggleton, B. J. Integrated microwave photonic filters. Adv. Opt. Photonics 12, 485–555 (2020).
Tao, Y. et al. Hybrid-integrated high-performance microwave photonic filter with switchable response. Photonics Res. 9, 1569–1580 (2021).
Zhuang, L., Roeloffzen, C. G., Hoekman, M., Boller, K.-J. & Lowery, A. J. Programmable photonic signal processor chip for radiofrequency applications. Optica 2, 854–859 (2015).
Pérez, D. et al. Multipurpose silicon photonics signal processor core. Nat. Commun. 8, 1–9 (2017).
Pérez, D., Lopez, A., DasMahapatra, P. & Capmany, J. Multipurpose self-configuration of programmable photonic circuits. Nat. Commun. 11, 1–11 (2020).
Bogaerts, W. et al. Programmable photonic circuits. Nature 586, 207–216 (2020).
Liu, Y., Hotten, J., Choudhary, A., Eggleton, B. J. & Marpaung, D. All-optimized integrated rf photonic notch filter. Opt. Lett. 42, 4631–4634 (2017).
Liu, Y., Marpaung, D., Choudhary, A., Hotten, J. & Eggleton, B. J. Link performance optimization of chip-based si3n4 microwave photonic filters. J. Lightwave Technol. 36, 4361–4370 (2018).
Zhu, Z. et al. Positive link gain microwave photonic bandpass filter using si3n4-ring-enabled sideband filtering and carrier suppression. Opt. Express 27, 31727–31740 (2019).
Daulay, O., Liu, G. & Marpaung, D. Microwave photonic notch filter with integrated phase-to-intensity modulation transformation and optical carrier suppression. Opt. Lett. 46, 488–491 (2021).
Guo, X. et al. Versatile silicon microwave photonic spectral shaper. APL Photonics 6, 036106 (2021).
Daulay, O., Liu, G., Guo, X., Eijkel, M. & Marpaung, D. A tutorial on integrated microwave photonic spectral shaping. J. Light. Technol. 39, 700–711 (2021).
Liu, G. et al. Integrated microwave photonic spectral shaping for linearization and spurious-free dynamic range enhancement. J. Light. Technol. 39, 7551–7562 (2021).
Daulay, O. et al. Programmable integrated microwave photonic filter using a modulation transformer and a double-injection ring resonator. In: 2021 European Conference on Optical Communication (ECOC), 1–4 (IEEE, Bordeaux, France, 2021).
Cohen, R., Amrani, O. & Ruschin, S. Response shaping with a silicon ring resonator via double injection. Nat. Photonics 12, 706–712 (2018).
Luo, L.-W. et al. High bandwidth on-chip silicon photonic interleaver. Opt. Express 18, 23079–23087 (2010).
Daulay, O. et al. Reconfigurable double-injection ring resonator for integrated microwave photonic signal processing. In: 2021 International Topical Meeting on Microwave Photonics (MWP), 1–4 (IEEE, Pisa, Italy, 2021).
Marpaung, D. et al. Low-power, chip-based stimulated Brillouin scattering microwave photonic filter with ultrahigh selectivity. Optica 2, 76–83 (2015).
Zhang, C., Morton, P. A., Khurgin, J. B., Peters, J. D. & Bowers, J. E. Ultralinear heterogeneously integrated ring-assisted Mach-Zehnder interferometer modulator on silicon. Optica 3, 1483–1488 (2016).
Zhang, Q. et al. High linearity silicon modulator capable of actively compensating input distortion. Opt. Lett. 45, 3785–3788 (2020).
Morton, P. A., Khurgin, J. B. & Morton, M. J. All-optical linearized Mach-Zehnder modulator. Opt. Express 29, 37302–37313 (2021).
Feng, H. et al. Ultra-high-linearity integrated lithium niobate electro-optic modulators. Photonics Res. 10, 2366–2373 (2022).
Liu, G., Daulay, O., Tan, Q., Yu, H. & Marpaung, D. Linearized phase modulated microwave photonic link based on integrated ring resonators. Opt. Express 28, 38603–38615 (2020).
Liu, G. et al. Simultaneous notch filtering and linearization in an integrated microwave photonic circuit. In: 2021 International Topical Meeting on Microwave Photonics (MWP), 1–4 (IEEE, Pisa, Italy, 2021).
Liu, Y. et al. A photonic integrated circuit-based erbium-doped amplifier. Science 376, 1309–1313 (2022).
Worhoff, K., Heideman, R. G., Leinse, A. & Hoekman, M. Triplex: a versatile dielectric photonic platform. Adv. Opt. Technol. 4, 189–207 (2015).
Roeloffzen, C. G. et al. Low-loss si3n4 triplex optical waveguides: technology and applications overview. IEEE J. Sel. Top. quantum Electron. 24, 1–21 (2018).
Georgescu, B., Finvers, I. G. & Ghannouchi, F. 2 GHz q-enhanced active filter with low passband distortion and high dynamic range. IEEE J. Solid State Circuits 41, 2029–2039 (2006).
Gao, Z., Ma, J., Yu, M. & Ye, Y. A fully integrated CMOS active bandpass filter for multiband RF front-ends. IEEE Trans. Circuits Syst.—II: Express Briefs 55, 718–722 (2008).
Zhang, W. & Yao, J. On-chip silicon photonic integrated frequency-tunable bandpass microwave photonic filter. Opt. Lett. 43, 3622–3625 (2018).
Yang, Z., Psychogiou, D. & Peroulis, D. Design and optimization of tunable silicon-integrated evanescent-mode bandpass filters. Trans. Microw. Theory Tech. 66, 1790–1803 (2018).
Chang, J. et al. High performance, continuously tunable microwave filters using mems devices with very large, controlled, out-of-plane actuation. J. Microelectromech. Syst. 27, 1135–1147 (2018).
Liu, Y. et al. Integration of Brillouin and passive circuits for enhanced radio-frequency photonic filtering. APL Photonics 4, 106103-1-106103-12 (2019).
Zou, X. et al. A multifunctional photonic integrated circuit for diverse microwave signal generation, transmission, and processing. Laser Photonics Rev. 13, 1800240 (2019).
Gertler, S., Kittlaus, E. A., Otterstrom, N. T. & Rakich, P. T. Tunable microwave-photonic filtering with high out-of-band rejection in silicon. APL Photonics 5, 096103 (2020).
Daulay, O., Botter, R. & Marpaung, D. On-chip programmable microwave photonic filter with an integrated optical carrier processor. OSA Contin. 3, 2166–2174 (2020).
Garret, M. et al. Ultra-deep multi-notch microwave photonic filter utilising on-chip Brillouin processing and microring resonators. In: 2021 Conference on Laser and Electro-Optics (CLEO) Europe, 1 (IEEE, Munich, Germany, 2021).
Li, J., Yang, S., Chen, H. & Chen, M. Hybrid microwave photonic receiver based on integrated tunable bandpass filters. Opt. Express 29, 11084–11093 (2021).
Acknowledgements
This work was supported by Netherlands Organisation for Scientific Research NWO Vidi (15702) and NWO Start Up (740.018.021).
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O.D. and G.L. contributed equally to this work. O.D., G.L., and D.M. developed the concept and proposed the physical system. O.D. designed the photonic circuits, O.D. and G.L. developed and performed numerical simulations. O.D. and G.L. performed the experiments with input from K.Y., R.B., and Y.K. E.K., M.H., and C.R. layout, developed, and fabricated the silicon nitride circuits. D.M., O.D., and G.L. wrote the manuscript with input from Q.T., H.Y. and Y.L. D.M. led and supervised the entire project.
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Daulay, O., Liu, G., Ye, K. et al. Ultrahigh dynamic range and low noise figure programmable integrated microwave photonic filter. Nat Commun 13, 7798 (2022). https://doi.org/10.1038/s41467-022-35485-x
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DOI: https://doi.org/10.1038/s41467-022-35485-x
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