2 Working principle

In addition to the liquid crystal material, the working principle of this phase type device is the same as the amplitude type device^{[Reference Heebner, Borden, Miller, Stolz, Suratwala, Wegner, Hermann, Henesian, Haynam, Hunter, Christensen, Wong, Seppala, Brunton, Tse, Awwal, Franks, Marley, Williams, Scanlan, Budge, Monticelli, Walmer, Dixit, Widmayer, Wolfe, Bude, McCarty and DiNicola11–Reference Huang, Fan, Zhang, Li, Tang, Guo, Li and Lin14]}. Because of the photoconductive effect of BSO ( $\text{Bi}_{12}\text{SiO}_{20}$ ) crystal, the voltage on the crystal will change when the projected blue light intensity changes. It will also lead to the change of voltage on the liquid crystal layer. Different modes of the liquid crystal result in different kinds of modulators. The amplitude-type device usually adopts the twisted nematic mode, while the phase-type device usually adopts the nematic mode. For the phase-type modulator in this paper, different voltages on the liquid crystal layer will lead to different phase delays. This means that the phase delay will change when the blue light intensity on the modulator changes. As a result, we can control the wavefront of 1053 nm laser beam if the blue light intensity distribution can be adjusted precisely.

Figure 4. (a) The gray bitmap, (b) the measured phase distribution, and (c) the relationship of both when $G_{0}=0$ .

Figure 5. The relationships of gray level and measured phase delay when the parameter $G_{0}$ is (a) 0.1, (b) 0.2, (c) 0.3, (d) 0.4, (e) 0.5, and (f) 0.6, respectively.

Figure 6. The gray-phase curves obtained from experiments when the parameter $G_{0}$ is different.

Both the device and its working principle have been shown in Figure 1. Bitmapped blue light from the LCOS modulator is projected onto the photoconductive BSO layer. As a result, we can control the intensity distribution of blue light by setting corresponding bitmaps. The high-definition multimedia interface (HDMI) port in Figure 1(a) is connected to the computer which can adjust the bitmap setting in the internal LCOS modulator. This means that the wavefront of 1053 nm laser beam will be controlled by the computer. The maximum effective area is about $15~\text{mm}\times 15~\text{mm}$ , which can be divided into $768~\text{pixel}\times 768~\text{pixel}$ . Its maximum transmittance is about 90% for 1053 nm wavelength and the damage threshold of this device is estimated to be $200~\text{mJ}/\text{cm}^{2}$ for 12 ns@1 Hz laser pulse.

3 Measurement and verification of the gray-phase curve

The optical setup has been shown in Figure 2. The wavefront sensor SID4-HR from Phasics is located on the image plane of the modulator. To demonstrate the phase modulation capability of this device, we set the special phase distribution with the shape ‘

Based on the result mentioned above, the device can generate different phase modulations by loading the corresponding bitmap. As a result, in order to accurately control the phase distribution, we must know the relationship between the gray level of bitmap and the phase delay of the device. Since the wavefront sensor can only measure the phase distribution, not the absolute value of the phase, we design the method as described below.

The loaded bitmap is set according to the formula

(1) $$\begin{eqnarray}G(r)=G_{0}+(1-G_{0})\frac{r^{2}}{r_{0}^{2}}.\end{eqnarray}$$

The two-dimensional distribution when $G_{0}=0$ has been shown in Figure 4(a). Figure 4(b) shows the corresponding phase delay distribution measured with the wavefront sensor. According to these two figures, we can get the relationship between gray level and phase delay as shown in Figure 4(c).

Figure 7. One-dimensional comparisons of designed phase distribution and measured phase distribution when the parameter $T$ is (a) 1.86 mm, (b) 3.72 mm, and (c) 5.58 mm, respectively.

In order to verify the accuracy of the curve shown in Figure 4(c), we set different bitmaps and measure the corresponding phase delay distributions, according to which we can get some other gray-phase curves. The two-dimensional gray distributions will be set according to Equation (1), but the parameter $G_{0}$ will be different. When the parameter $G_{0}$ changes, the phase difference between the edge and the central region will change. Different parameter $G_{0}$ means different range of gray level in the gray-phase curve. Theoretically, when the parameter $G_{0}$ increases, the range of the gray-phase curve will become shorter, but it should always be part of the curve shown in Figure 4(c). Different results have been shown in Figure 5 when the parameter $G_{0}$ is 0.1, 0.2, 0.3, 0.4, 0.5 and 0.6, respectively.

Figure 6 shows the gray-phase curves in one picture obtained from experiments when the parameter $G_{0}$ is different. These curves are basically coincident, which fully proves the accuracy of the gray-phase curve shown in Figure 4. As a result, this device can generate the desired phase distribution according to the green curve in Figure 6, which is also the curve in Figure 4(c).

4 Realization of special phase distribution

Two-dimensional phase distribution will be designed according to the formula

(2) $$\begin{eqnarray}P(r)=\text{sin}^{2}\left(\unicode[STIX]{x03C0}\cdot \frac{r}{T}\right).\end{eqnarray}$$

Designed and measured phase distributions in three cases with different parameter $T$ have been shown in Figure 7. The results show that the actual loaded phase is basically consistent with the setting value.