Inter-satellite communication links and laser communication terminals face challenges that could be solved with new photonics technologies i.e., photonic integrated circuits (PIC) and integrated microwave photonics. In general, these challenges are the need for higher data-rate, and reduced Size, Weight and Power Consumption (SWaP). In this paper we present the potential of integrated microwave photonics for intra-satellite communication links and photonic integration for laser communication terminals by demonstrating latest progress of Antwerp Space Q/V-band Electro-Photonic Frequency Convertor (EPFCV2) and Photonic Lantern Reciever (PLR).
Silicon-based integrated microwave photonics presents an interesting platform for broadband microwave applications, offering high-speed modulation and a broad selection of devices. We propose and experimentally demonstrate an effective Mach-Zehnder modulator design to generate frequency-multiplied microwave signals. Using a continuous-wave laser signal modulated by an external microwave signal, we demonstrate that by filtering two non-adjacent frequency comb lines, the detected frequency-doubled signal can be improved considerably by suppressing the carrier frequency and unwanted side-band contributions. The demonstrated designs use a 12-GHz and a 21-GHz external driving signal to generate respectively a 24-GHz and a 42-GHz frequency doubled MW signals.
Due to the exponential growth of the bandwidth requirement for wireless communication systems, new frequency bands need to be utilized. For future 5G wireless networks, frequencies of 30 GHz to 90 GHz are considered, while for satellite and aircraft communications the sub-terahertz frequencies are considered. However, with increasing millimeter-wave frequencies (30 GHz – 300 GHz), high-speed electronic solutions become energy-inefficient, and alternative solutions are required.
Photonics offers the bandwidth and a potentially seamless integration with the fiber-wireless technology (Fi-Wi) for 5G communications. Commercially available terahertz generators are often based on photonics, i.e., lasers, too. One particularly promising technique to generate the microwave or sub-terahertz signal is to use the comb generated by modulating a continuous-wave laser signal. By filtering two non-adjacent comb lines, a beat signal is generated that has a frequency that is an integer multiple of the electrical modulator driving signal. In this way, frequency multiplication is achieved using microwave photonics. Photodetectors and/or photomixers can then be used to convert the beat signal to a millimeter-wave. However, the energy-efficiency of these techniques – and how they compare to all-electronic solutions – has not been analyzed yet.
In this paper we will present this energy-efficiency analysis, based on a silicon photonics implementation. Silicon photonics has the potential to miniaturize such systems, for ubiquitous and low-cost implementation. Silicon-based modulators, however, are not ideal phase modulators, and simulation tools need to incorporate this. The regimes, in terms of signal power and frequency, where photonics compares favorably over electronics, will be discussed.
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