PhD student Benjamin Crockett in the laboratory. (Image: Yang Liu)

Weak optical signals are common in many science and technology applications. However, they are difficult to detect or process due to the incoherent noise that is inherently present in any system. PhD student Benjamin Crockett and colleagues, working under the supervision of Professor José Azaña of the Institut national de la recherche scientifique (INRS), have conceived a technique for the recovery of weak, noise-dominated optical signals. Their research was published in the journal Optica.

This achievement is relevant to various fields like telecommunications, bioimaging, and remote sensing. For example, there is considerable loss from long-distance propagation through optical fiber. In light-based biomedical imaging applications, there are limitations for the light power to avoid damaging the living tissue. Similarly, in LiDAR applications (laser remote sensing), high optical powers can pose a threat to the eyes of a passerby. In all these cases, the recovery of weak, noise-dominated signals remains a key challenge.

Lasers have enabled tremendous advances in so many fields of research. Yet the problem of sensitivity and noise eventually leads to an obstacle for further development.

Most common approaches are ill suited to retrieve a weak signal because they either further attenuate the signal or inject noise. The new method developed by the researchers uses passive amplification of the signal of interest over the noise, enabling access to signals that could not be recovered otherwise. The technique simultaneously increases the energy of the signal of interest while reducing its relative noise content.

To achieve this, the researchers exploit the Talbot self-imaging effect, which is observed when a periodic train of pulses propagates through a dispersive medium such as an optical fiber. It causes different frequency components of light (the different “colors” of light) to travel at different speeds. The Talbot effect was previously utilized to coherently “stack” or combine consecutive pulses in an incoming train, leading to a passive amplification of the pulses’ peak power.

Just like a physical lens can be used to focus a weak and large image into a narrower and more intense beam, the proposed system can be used to redistribute the energy of a weak signal into a series of high intensity pulses. This power focusing effect can be achieved without distorting the signal shape (carried information) and without increasing the noise along the signal.

The researchers believe this discovery opens many avenues for upcoming research lines. It could be possible to also adapt this technique for 2D or 3D spatial images, a feat that may have important applications in astronomy research, photography, and holography, among others. Furthermore, while the present demonstration focused on optical waveforms, such as the ones used in telecommunications, this technique could be adapted for different types of waves, including radio, microwave, plasma, acoustic, or even quantum waves.

For more information, contact Audrey-Maude Vézina at This email address is being protected from spambots. You need JavaScript enabled to view it..