2.1. Hartmann–Shack wavefront sensor

The Hartmann–Shack wavefront sensor is mainly composed of a micro-lens array and a CCD camera (Figure 1). The focal spot array of an ideal plane wave is used as the reference pattern when a deformed wavefront is measured, and the focal spots of the deformed wavefront shift from that of the reference beam. The spot deviation of $\def \xmlpi #1{}\def \mathsfbi #1{\boldsymbol {\mathsf {#1}}}\let \le =\leqslant \let \leq =\leqslant \let \ge =\geqslant \let \geq =\geqslant \def \Pr {\mathit {Pr}}\def \Fr {\mathit {Fr}}\def \Rey {\mathit {Re}}\Delta y$ in the $y$ direction is related to the slope of the deformed wavefront:

(1)$$\begin{equation} \label {eq1} \frac {{\Delta y}}{{f}}=\frac {{\partial W(x,y)}}{{\partial y}}, \end{equation}$$

where $f$ is the focal length of the lenslet. In this way, the wavefront distortion is converted to the spot offsets at the CCD sensor plane, and the phase map of the wavefront can be generated by integrating the calculated slope.

The most remarkable advantages of the Hartmann–Shack sensor are its simple structure and rapid data processing; these merits allow the use of the sensor in measurement of dynamic wavefronts^{[Reference Brennan and Wittich8]}, evaluation of laser beam quality, and realization of closed-loop wavefront control in combination with adaptive optics^{[Reference Saad and Martin9]}. However, given its limited number of micro-lenses, low resolution is an inherent disadvantage of the Hartmann–Shack sensor. Most commercial Hartmann–Shack sensors have a limited number of micro-lenses. As such, only the low frequency components of the wavefront can be measured, which results in low accuracy measurements.

In OMEGA EP system, a Hartmann–Shack sensor of $133 \times 133$ lenslets is applied to set up a focal spot diagnostic (FSD) system to measure a lower energy sample of the main beam that is attenuated and down-collimated to a more convenient beam size ($12\ \mathrm{mm}\times 12\ \mathrm{mm}$). Stretched pulses (250 mJ, 8 nm square spectrum, 5 Hz) are amplified using a multipass Nd:glass amplifier and compressed by a tiled-grating compressor, then 99.5% of the compressed pulse energy is reflected by a diagnostic pickoff mirror and the remainder is transmitted as a sample beam for the laser diagnostics package. The Hartmann–Shack sensor is positioned at an image plane conjugate to the fourth compressor grating, as shown in Figure 2. A local wavefront gradient as high as 15 mrad can be measured^{[Reference Bromage, Bahk, Irwin, Kwiatkowski, Pruyne, Millecchia, Moore and Zuegel10]}. The FSD is qualified using a sequence of experiments designed to compare measurements made by the FSD and focal-spot microscope (FSM). Figure 3 shows some of the measurement results of the FSD wavefront sensor in these experiments; wave-plate throttles are set so that $400\, \mu \mathrm{J}$ of the 100 mJ front end is focused in the target chamber, which provides enough energy for the FSD wavefront sensor and is not too high for the FSM. The image plane for this sensor is the last of the four tiled gratings inside the compressor. Figure 3(a) illustrates the raw data of the Hartmann–Shack sensor, Figure 3(b) shows the measured fluence of the near-field, and Figure 3(c) shows the corresponding measured wavefront. The performance of this system is evaluated by comparing its measurement results with those of the FSM system, which can be assumed to be correct. Figures 4(a) and (b) indicate the distributions of the focal spot measured using the FSD and FSM systems, respectively. Given the finite spatial resolution of the FSD wavefront sensor ($133\times 133$ lenslets), the wavefront cannot be captured accurately and the fine details of the focal spot cannot be faithfully represented; however, the encircled energies of these two measurements show good agreement. Figures 4(d) and (e) show the spot distributions in logarithmic scales to demonstrate their difference more clearly.

The Hartmann–Shack sensor is also used at National Ignition Facility (NIF)^{[Reference Zacharias, Beer, Bliss, Burkhart, Cohen, Sutton, Van Atta, Winters, Salmon, Latta, Stolz, Pigg and Arnold2]} for phase measurements, where the beam passes though a micro-lens array and is focused on a CCD. A hexagonal lens array of 77 micro-lenses is used to form the focal spot array and a measurement accuracy of $0.1\lambda $ is achieved at 1.053 mm in the offline test.

In most cases, measurements obtained using the Hartmann–Shack sensor present the closest real wavefront, but the resolution and accuracy of this technique are significantly lower than those obtained from interferometry.

Figure 6. Designed and measured surfaces of a CPP with 380 mm diameter (from Ref. [Reference Wen, Shi, Yan, Zhang, Yang and Wang18]).

2.2. Interferometry

2.3. Knife-edge test method

2.3.1. Traditional Foucault method

The knife-edge method was proposed by Foucault in 1858^{[Reference Malacara13]}. The geometric principle of the knife-edge test is shown in Figure 7, where $\mathit{AA}'$ is an ideal spherical surface with center $o$. When a point source is placed at $o$, the light from $o$ to $\mathit{AA}'$ coincides with the normal direction of the corresponding surface element and the reflected light returns to $o$. When the knife-edge cuts the reflected beam from right to left, the mirror is observed behind the knife-edge. When the knife-edge is located at position 1, the shadow on $\mathit{AA}'$ darkens from right to left, i.e., the shadow and knife-edge move in the same direction. The entire field is bright if the knife-edge has not met point $o$ and when the knife-edge is located at position 2, which is at the center of the sphere; $\mathit{AA}'$ darkens immediately when the knife-edge first cuts through point $o$. When the knife-edge cuts the light at position 3, the shadow on $\mathit{AA}'$ darkens from left to right, which is opposite to the moving direction of the knife-edge. This method is sensitive to slopes rather than heights, and only one direction can be measured at a single orientation of the knife-edge.

Figure 7. Geometric principle of the knife-edge test.

Given that only qualitative measurements can be realized by the traditional Foucault test method, a digitized Foucault tester (Figure 8) is used for quantitative measurements.

Figure 8. Principle of a digitized Foucault tester.

When a point source is located at the center of a spherical mirror, the returning beam focuses on the same position as the point source if the mirror under testing possesses an ideal spherical surface. When defects are present on the surface of the mirror, the returning beam deviates from the focal point and reaches a new location. The angle by which it departs from the ideal position can be calculated as follows:

(2)$$\begin{equation} \label {seq2} \varphi _{x}=-\frac {1}{n}\left [\frac {\partial \Delta \omega (x,y)}{\partial x}\right ], \end{equation}$$

where $n$ is the refractive index of air and $\Delta \omega (x,y)$ is the wave aberration. The deviation of the returning beam from the ideal position $E_{x}$ and $E_{y}$ can be calculated from the location of the knife-edge, and the wave aberration of the mirror can be obtained using

(3)$$\begin{equation} \label {seq3} \Delta \mathrm {OPD}_{\mathrm {waves}}=\iint E(x,y)\mathrm {d}x\mathrm {d}y, \end{equation}$$

where $E_{x}=R\varphi _{x}$, $E_{y}=R\varphi _{y}$, and $R$ is the radius of curvature.

The performance of the digitized Foucault test method has been compared with that of interferometry^{[Reference Vandenberg, Humbel and Wertheimer24, Reference Yuan and Wu25]}; when the air turbulence is totally eliminated, the precision of the former is comparable with that of the latter. Foucault testers have been used in nonlinear measurement of wavefront sensorless adaptive optics systems^{[Reference Song, Vdovin, Fraanje, Schitter and Verhaegen26]} as well as in measurements of mid-frequency surface errors in ICF^{[Reference Xuan, Li, Song and Xie27]}. However, given that the Foucault tester has strict testing environment requirements, even slight turbulence in the optical path may cause remarkable image distortion and affect the final test results. Thus, significant improvements are needed to enable the use of this method in high power laser applications.

3.1. Development of CDI

CDI is a phase-retrieval method based on computer iterative calculations. The original purpose of CDI is imaging of the wave phase using X-rays and electron beams when high quality optics are unavailable. Given its outstanding advantages, which include simple setup, compact structure, and low environmental requirements, CDI has been used in high power laser systems to measure wavefronts and predict focus.

The principle of CDI was first developed by Hoppe in the 1970s and then improved by Fienup. The main theories include the Gerchberg–Saxton (G–S) algorithm, the error-reduction algorithm, and the input–output algorithm^{[Reference Fienup28]}. These algorithms have been widely used in X-ray and electron imaging^{[Reference Zuo, Vartanyants, Gao, Zhang and Nagahara29, Reference Williams, Quiney, Dhal, Tran, Nugent, Peele, Paterson and de Jonge30]}. The traditional CDI method suffers from disadvantages with respect to viewing field, convergence speed, and reliability. To overcome these disadvantages, Rodenburg^{[Reference Rodenburg and Faulkner31]} proposed an improved phase retrieval algorithm called PIE, which used a Wegener filter-like algorithm to reconstruct images iteratively from a set of diffraction patterns and extended it to an extended PIE (ePIE) algorithm to obtain an accurate model of the illumination and specimen functions simultaneously. PIE and ePIE are promising algorithms for imaging using X-rays^{[Reference Weierstall, Chen, Spence, Howells, Isaacson and Panepucci32, Reference Chapman33]}, electron beams^{[Reference Hüe, Rodenburg, Maiden, Sweeney and Midgley34, Reference Humphry, Kraus, Hurst, Maiden and Rodenburg35]}, and visible light^{[Reference Osherovich, Shechtman, Szameit, Sidorenko, Bullkich, Gazit, Shoham, Kley, Zibulevsky, Yavneh, Eldar, Cohen and Segev36, Reference Szameit, Shechtman, Osherovich, Bullkich, Sidorenko, Dana, Steiner, Kley, Gazit, Cohen-Hyams, Shoham, Zibulevsky, Yavneh, Eldar, Cohen and Segev37]}. Given that the CDI algorithms can directly measure the phase distribution of a laser beam from the recorded diffraction intensity, they are often used in various high power laser applications, including wavefront detection, large optical element measurement, and FSDs.

3.2. Applications of traditional CDI

The wavefront of a high power laser system is easily distorted because of the high complexity of the system, which contains thousands of optical elements. The wavefront of the laser beam is difficult to control because it involves routing tasks of all of the ICF facilities. However, most of the commonly used measurement techniques do not satisfy the requirements for accurate online measurement because of the compact structure and limited inner space of CDI. In 2000, CDI was first used to measure the phase of high power laser beams^{[Reference Matsuoka and Yamakawa38]}. The intensity of the laser beam at two different planes vertical to the optical axis were recorded, and the Fresnel phase-retrieval algorithm based on the G–S algorithm and the Fienup phase-retrieval algorithm was used to reconstruct the complex amplitudes of these two recording planes. Figure 9 shows the experimental results, where the first two images from the left of each row indicate the laser intensities at the two recording planes; the third image provides the measured phase distribution of the laser beam.

Figure 9. Measured intensity distributions (image 1 and image 2) and reconstructed wavefronts of 100 fs pulses at different output power levels (from Ref. [Reference Matsuoka and Yamakawa38]).

Figure 10. Experimental arrangement used for phase retrieval measurements (from Ref. [Reference Brady and Fienup39]).

In 2006 Brady and Fienup^{[Reference Brady and Fienup39]} measured a concave spherical mirror using the CDI method (setup shown in Figure 10), where a He–Ne laser was filtered by a microscope objective and a pinhole placed near the center of curvature of the concave spherical mirror was used as the illumination beam; the intensity distributions of the resulting diffraction spots were measured using a CCD mounted on a computer-controlled translation stage, which could accurately shift along the optical axis. The measurement results are shown in Figure 11, where the images in the top row are the recorded diffraction intensities and the images in the bottom row are the obtained surface shapes. However, the accuracy of these results is not ensured because the element is not measured independently using an instrument with sufficient accuracy. The diameter of the optical elements used in the high power laser system is up to half a meter, and numerous optical elements possess large surface curvatures. Given that the common interferometer or Hartmann–Shack sensor is incapable of measuring large phase slopes, the measurement of the complex reflectance or transmittance of these large elements is fairly challenging, but CDI method can be used to solve this problem.

Knowledge of the focus is important in conducting physical experiments. The focal spots of a high power laser system can be highly structured because of the complexity of the facility, which contains hundreds of optical surfaces. However, measurement of the focus field varies significantly^{[Reference Zacharias, Beer, Bliss, Burkhart, Cohen, Sutton, Van Atta, Winters, Salmon, Latta, Stolz, Pigg and Arnold2, Reference Kessler, Bunkenburg, Huang, Kozlov and Meyerhofer40]} because direct measurement of the focus is impossible at extreme intensities. Multiple focal-plane spatial phase retrieval for a chirped-pulse-amplification laser was demonstrated by Bahk in 2008^{[Reference Bahk, Bromage, Zuegel and Fienup41, Reference Bahk, Bromage, Begishev, Mileham, Stoeckl, Storm and Zuegel42]}. The wavefront measured by phase retrieval is used to predict focal spots at high energies via separate measurement of the differential wavefront changes. Comparison of the measured and the predicted focal spots is shown in Figure 12, where the directly measured focal spot is shown in Figure 12(a); this spot agrees well morphologically with the predicted focal spot shown in Figure 12(b). The application of phase retrieval helps to extend the capability of FSDs for high intensity lasers beyond conventional direct wavefront measurements.

In 2010, the CDI algorithm was used to form a FSD to predict the focus of an OMEGA EP laser at the University of Rochester’s Laboratory for Laser Energetics^{[Reference Kruschwitz, Bahk, Bromage, Irwin, Moore, Waxer, Zuegel and Kelly43]}. The short-pulse diagnostic package contained a FSD which received a sampled beam downstream and a far-field CCD camera imaging the far-field intensity of the sample beam. The phase was initially retrieved from the sample beam to remove the differential piston uncertainty. Using a dense quasi-Newton downhill search algorithm to modify the optimization parameters for the subsequent iterations, the FSD prediction improved significantly compared with the initial FSD prediction, with the correlations for the diagnostic and target beams increased from $0.87\pm 0.04$ and $0.82\pm 0.04$ to $0.96\pm 0.01$ and $0.87\pm 0.02$, respectively. The error in the transfer wavefront measurement was then measured by CDI using the data recorded in the FSM. The correlation between the FSD prediction and the direct FSM measurement was improved to $0.93\pm 0.02$ using the corrected transfer wavefront. Using the measured complex amplitude and transfer function, the focal spot of the main laser beam inside the chamber could be accurately predicted.

This diagnostic method was evaluated on the OMEGA EP laser beam over a population of 175 shots to illustrate its reliability and stability; the evaluation was conducted for approximately 18 months from 2010 to 2012^{[Reference Kruschwitz, Bahk, Bromage and Irwin44]}. Figure 13(a) shows the frequency of cross-correlation values between the FSD and the far-field CCD. A significant improvement in performance was obtained after the phase-retrieved corrections were applied; the mean cross-correlation increased from 0.83 to 0.96. Figure 13(b) shows the results of more stringent testing of the FSD measurement accuracy; the cross-correlation values (reliability ${>} 0.9$ with ${>}95{\%}$ probability) between the measurements of FSD and FSM are also indicated. These diagnostics are used as a key tool for focal spot checking in the OMEGA EP laser.

Figure 11. Recovered phases obtained by Brady and Fienup (from Ref. [Reference Brady and Fienup39]).

Figure 12. Linear scale comparison of the directly measured focal spot (a) in the presence of an aberrator with the focal spots calculated with and without the use ((b) and (c), respectively) of the transfer wavefront obtained from phase retrieval (from Ref. [Reference Bahk, Bromage, Begishev, Mileham, Stoeckl, Storm and Zuegel42]).

Figure 13. Histograms illustrating the effects of phase-retrieval improvements on a large population of measurements. (a) Sample beam focal-spot accuracy showing cross-correlation between the FSD prediction and the far-field CCD measurement. (b) Main-beam focal-spot accuracy showing cross-correlation between the FSD prediction and the FSM measurement (from Ref. [Reference Kruschwitz, Bahk, Bromage and Irwin44]).

4.1. Basic principles

For clarity, the principles of PIE and ePIE are outlined in Figure 14; details can be found in the relevant literature^{[Reference Rodenburg and Faulkner31, Reference Faulkner and Rodenburg45]}. The object $O$(x, y) under the illumination $P$(x, y) can accurately shift across the optical axis; a set of diffraction patterns $I_{\mathrm{n}}$(x, y) is recorded by the CCD downstream of the object when the object is scanned to a series of positions (Figure 15). Iterative calculations are performed between the object and the recording planes to retrieve the complex transmittance of the object and the complex amplitude of the illumination via the following procedure.

(1) The exit field at the current position $R_{i}$ is calculated with two random guesses for $P_{n,g} \left (r \right )$ and $O_{n,g} \left ({r-R_{i}}\right )$

(4)$$\begin{equation} \label {eq2} \Psi _{n,g} (r, R_{i}) = P_{n,g}(r)\cdot O_{n,g}(r-R_{i}), \end{equation}$$

where the subscript $n$ represents the $n$th iteration.

(2) The wavefunction in the data recording plane is calculated from the Fourier transform of $\Psi _{n,g} \left ({r,R_{i}}\right )$:

(5)$$\begin{equation} \label {eq3} \Psi _{g,n} (k, R_{i})=\Im [{\Psi _{g,n} (r, R_{i})}]=| {\Psi _{g,n}({k, R_{i}})} |e^{i\theta _{n} ({k, R_{i}})}. \end{equation}$$

(3) The amplitude of $\Psi _{n,g}({r,R_{i} })$ is replaced by the square root of $I_{n}(x, y)$:

(6)$$\begin{equation} \label {eq4} \Psi _{c,n}({k, R_{i}})=\sqrt {I_{n} } e^{i\theta _{n} ({k, R_{i}})}. \end{equation}$$

(4) The guess is updated at the exit field by inverse Fourier transform:

(7)$$\begin{equation} \label {eq5} \Psi _{c,n}({r, R_{i}})=\Im ^{-1}[{\Psi _{c,n}({k, R_{i}})}]. \end{equation}$$

(5) The functions $P(r)$ and $O(r, R_{i})$ are updated with the following formulas:

(8)$$\begin{eqnarray} \label {eq6} O_{\mathrm {new}}(r,R_{i}) &=& O_{g,n} (r,R_{i}) + \frac {|P_{n}(r)|}{|P_{n}(r)|_{\max }} \frac {P_{n}^{\ast }(r)}{[|P_{n}(r)|^{2}+\alpha ]} \\ && \times \, [{\Psi _{c,n} ({r, R_{i} } )-P_{n}(r)\cdot O({r,R_{i}})} ],\end{eqnarray}$$

(9)$$\begin{eqnarray} P_{\mathrm {new}}(r) &=& P(r)+\frac {|{O({r,R_{i} } )}|}{| {O({r,R_{i}})}|_{\max } }\frac {O^{\ast }({r,R_{i}})}{[{|{O({r,R_{i} })}|^{2}+\alpha }]} \\ && \times \,[{\Psi _{c,n} (r, R_{i})-P_{n}(r )\cdot O(r,R_{i})}]. \end{eqnarray}$$

Steps 1 to 5 are repeated until satisfactory images are generated.

Figure 14. Principles of PIE and ePIE (from Ref. [Reference Wang, Liu and Veetil46]).

Figure 15. Diffraction patterns with the illumination beam in overlapping positions.

Figure 16. Experimental setup of the phase detection for large-aperture optical elements.

Figure 17. (a) Manufactured CPP, (b) CPP design value, (c) measurement result of a Zygo interferometer, (d) wrapped phase of the measured modulation function, (e) unwrapped phase of the measured modulation function, and (f) the measured result and designed value along the horizontal lines of (b) and (e) (from Ref. [Reference Wang, Liu and Veetil46]).

4.2. Measurement of the transmittance of a large optical element with the use of ePIE

Illumination on the specimen in Figure 16 can be measured with the use of ePIE, and this property provides a new method for measuring the complex transmittance of large optical elements used in high power laser applications^{[Reference Wang, Liu and Veetil46]}. Practical measurement was conducted to illustrate the feasibility of this method by CPP, which is a key element in ICF systems that smoothens the laser beam to ensure an ideal focal spot with a highly irregular surface profile^{[Reference Haynam, Wegner, Auerbach, Bowers, Dixit, Erbert, Heestand, Henesian, Hermann and Jancaitis47, Reference Neauport, Ribeyre, Daurios, Valla, Lavergne, Beau and Videau48]}. The optical setup used is shown in Figure 16. The wavefront $\varphi _{0}(x, y)$ of the light leaving the convergent lens can be measured using the ePIE algorithm when the CPP is removed (Figure 16); the wavefront $\varphi _{1}(x,y)$ of the light leaving the CPP can also be measured. By subtracting $\varphi _{0}{(x,y)}$ from $\varphi _{1}{(x, y)}$, the PM of the CPP is obtained.

Figure 17(a) shows a photograph of the manufactured CPP plate with approximately 31 cm diameter. Figure 17(b) shows the design value of the surface profile. Figure 17(c) shows the measurement result obtained using a Zygo interferometer, where the black areas indicate invalid measurements. The slope of the surface profile is very steep at these black areas and the interference fringes are too dense to resolve, resulting in the existence of these immeasurable areas. As such, the measurement result cannot indicate the real surface profile of the CPP. Figure 17(d) shows the wrapped phase of the measured PM function and Figure 17(e) shows the corresponding unwrapped phase distribution. The aperture of the measurement is 28 cm, which is decided by the parallel beam illuminating the CPP. The values along the vertical lines in Figures 17(b) and (e) are plotted in Figure 17(f), and the maximum difference between the measured and designed values is approximately 2.1 rad. This research illustrates that ePIE is a promising technique for measuring large optical elements.

Figure 18. Schematic of the PM technique. (a) Basic principle and (b) experimental setup.

Figure 19. Experimental results of PM. (a) Reconstructed phase, (b) reconstructed modulus, (c) predicted focal spot with the PM technique, and (d) the measured focal spot.

4.3. PM technique and its potential application

The data acquisition time of ePIE is several minutes; thus, it cannot be used to measure dynamic wavefronts. To overcome this disadvantage, Zhang proposed the PM method^{[Reference Zhang and Rodenburg49]}. The basic principle and the experimental setup of the phase modulation technique are shown in Figures 18(a) and (b).

The modulator with a designed transmission function is located between the entrance and detector domains, while the entrance plane is the focal plane of the incident wave to be measured. As one frame of the diffraction pattern is recorded, the illumination on the modulator plane can be iteratively reconstructed at high accuracy. This method features a very simple structure and short data acquisition time; thus, it is suitable for FSDs and laser plasma imaging, where the laser beam is pulsed and most of the common techniques do not work well. Proof of concept is demonstrated by measuring a seriously distorted convergent He–Ne laser beam; Figures 19(a) and (b) show the reconstructed phase and modulus of the field incident on the phase modulator. Figures 19(c) and (d) show the predicted and measured focal spots; the difference between the two focal spots is difficult to distinguish with the naked eye. The details of this research will be reported in a separate paper.