2.1. CMOS detector C10158DK

The Hamamatsu Photonics C10158DK detector (Table 1) adopts the active-pixel-type CMOS image sensor, which is equipped with amplifiers in each pixel so that the output signal is resistant to readout noise (Yagi & Inoue, 2007). The phosphor layer, composed of a 150 µm-thick columnar CsI(Tl) crystal, is directly deposited on the CMOS image sensor for improvement of spatial resolution. Since there is no high-density substrate at the surface of the phosphor layer, the sensitivity for long-wavelength X-rays has been improved (Yagi et al., 2004). For short-wavelength X-rays, a 150 µm-thick CsI(Tl) is very advantageous because of its high absorption (e.g. 97% for a wavelength of 0.8 Å).

The CMOS sensor of C10158DK is so large that the active area of 117.6 × 117.6 mm can be covered by a single CMOS sensor. This enables direct coupling with phosphor and the CMOS image sensor without demagnification, and means it is free from issues such as attenuation of fluorescence intensity and distortion of diffraction images caused by demagnification devices such as a fibre optics taper.

The C10158DK is not equipped with a cooling system to reduce dark-current noise, because the active-pixel CMOS image sensor with directly deposited phosphor would be expected to increase the S/N sufficiently and a short exposure time would be expected to decrease the influence of the dark current. This simple detector architecture makes it compact and reduces the cost of manufacturing.

The readout sequence of the CMOS sensor in C10158DK is as follows. First, a horizontal pixel array is simultaneously processed in 14 µs. In this step, all signals in the horizontal pixel array are converted into a voltage signal and transferred to the hold-capacitors located at one edge of the sensor. Then, the signals in the hold-capacitors are sequentially read out in 140 µs. The photodiodes can immediately accumulate the signals following completion of the signal transfer to the hold-capacitors. Therefore, the effective dead time is only 14 µs, which is negligible compared with typical, current exposure times per diffraction image. The readout of horizontal lines proceeds sequentially from the first to the last line and there is a time lag of 140 µs between neighbouring lines. The readout of the entire image is completed in 0.333 s, and a maximum frame rate of 3 frames s⁻¹ is available with this detector.

2.2. Experimental setup

Experiments for evaluation of the new shutterless continuous rotation method using the X-ray CMOS detector were performed at SPring-8 (Hyogo, Japan). The linearity and uniformity of the detector were examined at the SPring-8 beamline BL41XU to make use of the highly intense X-rays from the undulator. A comparison between the conventional oscillation method using a Quantum 210 CCD detector (Q210; ADSC, California, USA) and the continuous rotation method using the CMOS detector was conducted at the SPring-8 beamline BL38B1. Data collection for the structure determination of proteins using multi- (MAD) and single-wavelength anomalous diffraction (SAD) phasing was carried out at the SPring-8 beamline BL44B2.

BL41XU is an undulator beamline, which provides intense X-rays with a photon flux of 1 × 10¹² photons s⁻¹ at 1 Å with a beam size of 50 × 50 µm (FWHM). BL38B1 is a bending-magnet beamline, with a photon flux of 8 × 10¹⁰ photons s⁻¹ at 1 Å and 9 × 10¹⁰ photons s⁻¹ at 0.8 Å with a beam size of 210 × 140 µm (FWHM). BL44B2 is also a bending-magnet beamline, with a photon flux of 1 × 10¹¹ photons s⁻¹ at 1 Å with a beam size of 200 × 200 µm (FWHM).

The detector was operated at room temperature (297 K) with the following setup. Digitized diffraction images were transferred to the detector control PC and captured by a frame grabber board (IMAQ PCI-1424; National Instruments, Texas, USA). The frame rate of the CMOS detector was controlled by an external trigger pulse generated by a function generator (DG535; Stanford Research, California, USA).

2.3. Evaluation of the basic performance of the CMOS detector

The dark current and readout noise were evaluated by measuring successive blank images (100 in all) recorded at various accumulation times. The linearity of the detector was verified using the powder diffraction pattern of CaSO₄·2H₂O recorded with various photon fluxes of the incident 1 Å wavelength X-rays. The incident X-ray intensity was attenuated stepwise by changing the thickness of an aluminium attenuator with an exposure time of 0.5 s. The photon flux of the incident beam was measured using an Si PIN photodiode at each step. For flat-field measurement, the detector was uniformly illuminated with fluorescence X-rays of 0.96 Å wavelength from a saturated NaBr solution that was sealed in a glass capillary. Flat-field images were recorded with 1 s exposure time. The detector was placed at 460 mm distance and 90° to the incident-beam direction i.e. perpendicular.

2.4. Comparison with the conventional oscillation method using a CCD detector

The performance of the continuous rotation method using the CMOS detector was compared with the conventional oscillation method using a CCD detector, the Q210. Here we focused on the difference of the dynamic range and sensitivity in both detectors; thus the experiment was performed with various intensities and wavelengths of incident X-rays under the following three conditions: (i) a low intensity suitable for the CMOS detector at 1 Å X-ray wavelength, (ii) a high intensity suitable for the CCD detector at 1 Å X-ray wavelength and (iii) a low intensity suitable for the CMOS detector at 0.8 Å X-ray wavelength. The detector distance in all data sets was 75 mm. The Q210 was operated in nonbinning mode to set the pixel size comparable to that of the CMOS detector. All data sets were processed with the XDS/XSCALE software package (Kabsch, 1993, 2001) except where stated otherwise.

2.5. Evaluation of the continuous rotation method with fine φ slicing

Two series of data sets were collected in order to (i) compare the influence of the slicing rotation step on data accuracy between the continuous rotation method using the CMOS detector and the oscillation method using the CCD detector, and (ii) examine the performance of the continuous rotation method using the CMOS detector combined with the fine φ slicing data collection.

2.6. Structure determination by the continuous rotation method

Diffraction data were collected using three protein crystals to evaluate the performance of the shutterless continuous rotation method using the CMOS detector. One was a mercury derivative of a hen egg white lysozyme crystal in the tetragonal form, which was prepared by soaking crystals in 5 mM p-chloromercuribenzene sulfonic acid solution for 10 h (Blake et al., 1965). The other two proteins were a putative cobalt transport ATP-binding protein ST1066 from Sulfolobus tokodaii [NCBI accession No. NP_376986, Protein Data Bank (PDB) code 2PJZ] and a thioredoxin-like protein TTHA0593 from Thermus thermophilus HB8 (NCBI accession No. YP_143859, PDB code 2CVB). The mercury derivative of hen egg white lysozyme and two selenomethionine proteins ST1066 and TTHA0593 were used for MAD and SAD experiments.

3.1. Basic performance of C10158DK

The basic performance of the detector such as dark current, readout noise, linearity and non-uniformity was evaluated first, because this evaluation was necessary for diffraction image correction.

3.1.1. Dark current and readout noise

Figs. 1(a) and 1(b) show a dark-current image and a raw diffraction image of a hen egg white lysozyme crystal recorded with a 1 s exposure time and a 1 s accumulation time, respectively. The vertical stripe pattern on the images is caused by the output offset between the 18-channel amplifier arrays located at the bottom edge of the sensor. About ten defect lines were observed in the image as white or black lines running horizontally or vertically.

Figure 1 (a) Dark-current image recorded using C10158DK with a 1 s accumulation time. (b) Raw diffraction image of hen egg white lysozyme recorded with a 1 s exposure. (c) Diffraction image obtained by subtracting the dark current from the raw diffraction image shown in (b). (d) Diffraction image obtained by applying a defect line correction to the image in (c).

The mean dark current (〈I_dark〉) calculated by averaging the dark levels over all pixels is plotted against accumulation time in Fig. 2(a). The defect pixels were excluded from the calculation. The 〈I_dark〉 value increased by 190 analog-to-digital converter units (ADU) per second in proportion to the accumulation time. Extrapolating 〈I_dark〉 to 0 s accumulation time led to the offset of 243 ADU. The 〈I_dark〉 at 1 s accumulation was 430 ADU, whereas it became 2125 ADU at 10 s accumulation, which is one-eighth of the saturation level (14 bits).

Figure 2 (a) Average dark current (〈Idark〉) plotted against accumulation time. (b) Total detector noise (σall), which is composed of the readout noise (σreadout) and fluctuation of dark current (σdark), also plotted against accumulation time.

The fluctuations of dark current (σ_dark) and the readout noise (σ_readout) were estimated as follows. First, the standard deviation of the dark current in the 100 successively recorded dark-current images was calculated at each pixel. Then, the standard deviations were averaged over all pixels (σ_all), which is the total detector noise composed of σ_dark and σ_readout. Fig. 2(b) is a plot of σ_all against accumulation time, which showed that σ_all increased in proportion to the accumulation time. The increase of σ_all was due to an increase of σ_dark, because σ_readout is independent of the accumulation time. Therefore, extrapolation of σ_all to 0 s accumulation time yielded a σ_readout estimate of 3.37 ± 0.27 ADU (mean ± standard deviation). σ_dark is estimated as (σ_all² − σ_readout²)^1/2 based on the law of propagation of errors. σ_dark at 1 s accumulation is calculated as 1.6 ADU.

3.1.2. Linearity and uniformity

The linearity of the detector was evaluated by plotting the diffraction intensity for a CaSO₄·2H₂O powder sample against the photon flux of the incident X-ray beam (Fig. 3a). The minimum and maximum intensities were 4 and 15 725 ADU, respectively, and the R² value of the regression line was 0.9998. This result indicates that the linearity of C10158DK is maintained over the output data range of 14 bits, or 16 383 ADU.

Figure 3 (a) Linearity of C10158DK. After averaging five diffraction images of a CaSO4·2H2O powder pattern to improve S/N, the dark current was subtracted. The intensity of one pixel for the 020 reflection was plotted against the photon flux of the incident X-ray beam. (b) Horizontal profile of the flat-field image. After averaging 100 raw images, the dark-current image was subtracted. Average profiles of the central 264 rows are shown. The incident X-rays travelled from the left side to the right side in this figure. A gradual change in intensity with the pixel position can be explained by the absorption of the incident X-rays and fluorescence X-rays by the NaBr solution; the fluorescence X-rays emitted from different points on the incident-beam path decrease gradually along with the incident beam because the incident X-ray is reduced by absorption. In addition, the intensity of the fluorescence X-ray is asymmetrically attenuated by the absorption and has a different intensity depending on the direction, unless it was emitted from the centre of the capillary. Therefore, convolution of the intensity of fluorescent X-rays emitted from multiple points generates an asymmetrically gradually changing profile. Calculation of the intensity profile considering the effect of absorption generates almost the same profile (data not shown).

The horizontal profile of the flat-field image is shown in Fig. 3(b). It shows a small difference in sensitivity among the 18 readout segments. The maximum difference between the neighbouring segments was 3% of the average intensity of these segments. The profile also shows a gradual non-uniformity along the horizontal position. In order to verify whether the gradual change was due to an uneven response of the detector or the non-uniformity of the flat-field X-ray, five flat-field images were recorded by changing the horizontal position of the detector by 30 mm. Superposition of the horizontal profiles of these images with a horizontal offset of 30 mm (or 600 pixels) per image showed that the profiles were well fitted to each other. This indicated that the gradual change might be caused by the non-uniformity of the flat-field X-ray illumination.

3.1.3. Image correction

The use of a short exposure time gives a small 〈I_dark〉 and maximizes the effective dynamic range. Moreover, the fluctuation of dark current is so small that the effect of dark current can be corrected only by subtracting a pre-recorded dark-current image. The effectiveness of dark-current subtraction is shown in Fig. 4, where a horizontal profile of a dark-current image and a difference intensity profile of two dark-current images are compared. The dark-current images for correction were recorded just before starting a series of data-collection images with the same exposure time. The corrected diffraction image in Fig. 1(c) was obtained by applying dark-current corrections to the raw diffraction image in Fig. 1(b). The diffraction spots that were obscure in the raw image were clearly observed. The readout noise and fluctuation of the dark-current image were reduced by averaging multiple dark-current images.

Figure 4 (a) Intensity profile of the 1000th row of a dark-current image recorded with an accumulation time of 1 s. (b) A difference profile between two dark-current images recorded with a 1 s accumulation time. The standard deviation of the difference profile is 5.1 ADU which is comparable to convolution of the σall values of the two images.

Another treatment was a defect line correction. Some defect pixels had a different output offset and different conversion gains from those of normal pixels, and the other defect pixels output no signal. The intensity of all of these defect pixels was padded with the average value of the neighbouring pixels. The diffraction image in Fig. 1(d) was obtained by applying the defect line correction to the diffraction image in Fig. 1(c).

3.2. Comparison with the conventional oscillation method using the CCD detector

3.2.1. A relatively low intensity condition suitable for the CMOS detector at 1 Å X-ray wavelength

R_merge and 〈I/σ(I)〉 are plotted against resolution shell in Figs. 5(a) and 5(b). The statistics of the first and the third data sets collected by the CCD detector showed almost the same results, which means that the sample radiation damage was negligible. R_merge and 〈I/σ(I)〉 of the CMOS data were slightly better than those for the CCD data.

Figure 5 Rmerge and 〈I/σ(I)〉 plotted against resolution shells. Statistics of CCD and CMOS data are plotted as open circles and open triangles, respectively. Open rectangles represent the CCD data collected to examine the effect of radiation damage. The open diamonds shown in (c) and (d) represent CMOS data collected with a rotation step of 0.1° frame−1; the other data were collected with a rotation step of 0.5° frame−1. The differences in the measurement conditions in (a), (b) and (c), (d) are the size of the crystal and the attenuator thickness; the diffraction intensity of data (c), (d) is stronger than that of data (a), (b). The data-set names in the graph legends are composed of the detector type, CCD or CMOS, and the data-collection sequence – for example, CMOS2 is the second data set recorded with the CMOS detector. This nomenclature is also used in Figs. 6–8.

3.2.3. A relatively low intensity condition suitable for the CMOS detector at 0.8 Å X-ray wavelength

The comparison was also made using a 0.8 Å X-ray wavelength. R_merge and 〈I/σ(I)〉 are compared in Figs. 6(a) and 6(b), which show that the data accuracy in the high-resolution shells of the CMOS data was better than that of the CCD data.

Figure 6 Rmerge and 〈I/σ(I)〉 plotted against resolution shell. Statistics of CCD and CMOS data are plotted as open circles and open triangles, respectively. Open rectangles represent CCD data collected to examine the effect of sample radiation damage.

3.3. Evaluation of the continuous rotation method with fine φ slicing

3.3.1. Comparison of slicing rotation step between the two data-collection methods

Figs. 7(a) and 7(b) show R_merge versus resolution plots that compare statistics among data sets collected with 1.0, 0.5 and 0.25° frame⁻¹ steps. The R_merge of the CCD data at the highest-resolution shells increased from 34.6 to 53.5% as the oscillation step got smaller, as shown in Fig. 7(a). The R_merge values of the CMOS data collected with 1.0, 0.5 and 0.25° frame⁻¹ were 34.4, 34.2 and 37.8%, respectively, in the highest-resolution shell (Fig. 7b), and are almost comparable to those of the CCD data collected with 1° frame⁻¹. The CCD data were also processed using MOSFLM (Leslie, 1992) and SCALA (Evans, 1993) in order to compare the R_merge of fully recorded reflections among these data sets (Table 2). This shows that the redundancy-independent R_merge values for fully recorded reflections are comparable between CCD data, indicating that the decrease of CCD data accuracy was due to the influence of partially recorded reflections.

Table 2 Statistics of data recorded with an ADSC Q210 with 1.0, 0.5 and 0.25° frame−1 oscillation steps MOSFLM and SCALA were used for processing. Rfull is the Rmerge of fully recorded reflections. Rmeans_full is the redundancy-independent Rmerge of fully recorded reflections (Diederichs & Karplus, 1997; Weiss & Hilgenfeld, 1997; Weiss, 2001). The statistics at the highest-resolution shells are shown in parentheses.   CCD1 CCD2 CCD3   Δφ = 1.0 (° frame−1) Δφ = 0.5 (° frame−1) Δφ = 0.25 (° frame−1) Resolution (Å) 25–1.6 (1.69–1.6)     No. of reflections 110066 (15698) 109671 (15786) 106144 (14921) Full reflection 57558 18923 0 Partial reflection 52508 90748 106144 No. of unique reflections 15051 (2205) 14988 (2179) 14799 (2127) Rmerge (%) 6.5 (33.2) 7.2 (38.8) 8.0 (46.1) Rfull (%) 5.8 (28.3) 5.1 (26.5)   Rmeans_full (%) 6.4 (31.4) 6.2 (32.7)

Figure 7 The effect of rotation (oscillation) step volume compared for the CCD and the CMOS data. (a) and (b) show Rmerge versus resolution plots for the CCD and the CMOS data, respectively. (c) and (d) are 〈I/σ(I)〉 versus resolution plots of the CCD and the CMOS data, respectively. Red, green and blue represent data sets collected with the rotation steps of 1.0, 0.5 and 0.25° frame−1, respectively. Brown in (a), (c) corresponds to the last data set collected to examine the effect of sample radiation damage.

Figs. 7(c) and 7(d) give the 〈I/σ(I)〉 versus resolution plots of the CCD data and CMOS data, respectively. Fig. 7(c) shows that 〈I/σ(I)〉 of the CCD data became smaller as the rotation step decreased in all resolution shells. This result means that the smaller rotation step causes a deterioration in the S/N of the diffraction intensities. On the other hand, 〈I/σ(I)〉 of the CMOS data became larger as the rotation steps got smaller up to 2 Å resolution, and had almost the same value at higher than 2 Å resolution. This means that the S/N of strong reflections up to 2 Å resolution was improved by more finely slicing the rotation step. However, there was no improvement for weak reflections above 2 Å.

3.3.2. Effects of fine φ slicing

As described above, the finer slicing of the rotation step improved the data accuracy of the CMOS data for the strong reflections in the low-resolution shells. This indicates that the use of a smaller rotation step would improve data accuracy further if the diffraction intensity was stronger. In order to verify this, experiments using rotation steps of 0.1, 0.2, 0.4 and 1.0° frame⁻¹ were performed under conditions that provided a stronger diffraction intensity: there were a couple of saturated spots per image for the 0.1° frame⁻¹ data set, and about 25 saturated spots per one image of 1.0° frame⁻¹ data sets.

Figs. 8(a) and 8(b) show the R_merge versus resolution plots and an 〈I/σ(I)〉 versus resolution plot of the data sets collected with the rotation steps of 0.1, 0.2, 0.4, 1.0 and 0.1° frame⁻¹. Both statistics show that the accuracy improved as the rotation step got smaller. The R_merge values of the first and the last data sets were 28.6 and 31.0%, respectively, at the highest-resolution shell, indicating that the crystal was damaged by radiation. Therefore, the difference between the first and the other data sets included the effect of sample radiation damage as well as the effect of changing the rotation step. The R_merge values of the data sets collected with a 0.4 and 1.0° frame⁻¹ step were 34.9 and 37.2%, respectively, in the highest-resolution shell, and those values were larger than that of the last data set collected with a 0.1° frame⁻¹. These results show that the accuracy of data collected by the continuous rotation method using the CMOS detector was improved by using fine φ slicing data collection under conditions that provide strong diffraction intensities.

Figure 8 (a) Rmerge versus resolution plot and (b) 〈I/σ(I)〉 versus resolution plot for five data sets collected with 0.1, 0.2, 0.4, 1.0 and 0.1° frame−1 by using the continuous rotation method using the CMOS detector.

3.4. Structure determination of proteins

We successfully solved the structures of three proteins, a mercury derivative of hen egg white lysozyme and two selenomethionine proteins ST1066 and TTHA0593, using anomalous dispersion, and confirmed therefore the applicability of the continuous rotation method using the CMOS detector. The structures of lysozyme and ST1066 were determined by MAD phasing using the Hg and Se atoms, respectively, as anomalous scattering atoms. The structure of TTHA0593 was solved by SAD phasing using Se atoms. The initial phases of all structures were calculated by SOLVE (Terwilliger & Berendzen, 1999) and improved by density modification with RESOLVE (Terwilliger, 2000). Most residues were automatically built using ARP/wARP (Perrakis et al., 1999), and the rest of the residues were manually built using COOT (Emsley & Cowtan, 2004). The protein structure models were refined with REFMAC (Murshudov et al., 1997) in the CCP4 package (Collaborative Computational Project, Number 4, 1994). The final refinement R factor and free R factor decreased to less than 21 and 25%, respectively. The data statistics and refinement statistics are summarized in Table 3.¹ Fig. 9(a) shows the σ_A-weighted 2 electron-density map (Read, 1986) of lysozyme after refinement, showing the clear electron density of the protein and solvent molecules. Fig. 9(b) is the electron-density map of TTHA0593 calculated with the phases obtained by improving the initial phases using density modification. It clearly shows the electron density of the protein main and side chains.

Figure 9 (a) σA-weighted 2Fo-Fc electron-density map of lysozyme Hg derivative calculated at 1.7 Å resolution. Contour level is 1.5 r.m.s. A molecular model after crystal structure refinement is superimposed on it. (b) Electron-density map of TTHA0593 calculated at 1.9 Å resolution. Phases were improved by density modification after SAD phasing was used. Contour level is 1.5 r.m.s. A refined structure model is also shown.

4.1. Characteristics of the CMOS detector

Conventional opinion has been that the CMOS detector is not suitable for diffraction data collection because of the large dark-current noise and the narrow dynamic range. Indeed, the dark current of the detector increases in proportion to the exposure time and the effective dynamic range decreases by the dark-current effect. However, our study shows that the dark current was so stable that it could be accurately corrected by simply subtracting pre-recorded dark-current images from raw diffraction images. Moreover, a continuous readout with a high frame rate keeps the dark current at a low level. Therefore, we suppose that the dark current of the CMOS detector is not a serious problem in a high-frame-rate experiment. The evaluation of linearity showed that the linearity was maintained over an output range of 14 bits. The evaluation of the uniformity from flat-field images showed a maximum deviation of a few percent among the 18 readout segments. The data statistics of the CMOS data processed without a non-uniformity correction were comparable to the CCD data; we then processed all diffraction data sets without a non-uniformity correction. The detailed examination of the non-uniformity could be applied for improving the data statistics of the CMOS data in the next step. The intensity of the defect lines was approximated by averaging the signal intensity of neighbouring pixels. Even though this is an ineffectual estimate for the centre of the peak of diffraction spots, the intensities of pixels located at the side of a reflection profile are well approximated by this correction. This defect line correction significantly improved the data statistics. If the redundancy of the data is high, the influence of defect pixels will be small.

These results show that the CMOS detector is reasonably applicable as a two-dimensional detector for diffraction intensity measurement.

4.2. Feasibility and advantage of the shutterless continuous rotation method using the CMOS detector

As the results in §3.2 show, the new continuous rotation method using the CMOS detector is applicable for protein crystallography. The diffraction data recorded by the new method were successfully processed and the data statistics of the intensity data were comparable to those obtained by the conventional oscillation method. Furthermore, the slightly better data statistics of the CMOS data compared with the conventional oscillation method show the potential of the continuous rotation method (Figs. 5a and 5b).

The narrow dynamic range of the CMOS detector, another potential difficulty as mentioned above, could be overcome by fine φ slicing. Moreover, the data statistics of the CMOS data in Fig. 7 indicate the potential for improving the data quality by the continuous rotation method with fine φ slicing.

The source of data improvement in fine φ slicing has already been discussed by Hülsen et al. (2006), who showed that the continuous rotation method using a PILATUS detector improved data accuracy in fine φ slicing mode versus the conventional oscillation method using a CCD detector which results in a deterioration of data accuracy. From that comparison, Hülsen et al. (2006) concluded that the improved accuracy of the PILATUS data was due to there being no readout noise of the PILATUS detector. On the other hand, Pflugrath (1999) pointed out that, theoretically, deviation from the proper synchronization can affect the accuracy of partially recorded reflection intensities and the influence is more serious for data collected with a small rotation step. Our result supports the latter opinion experimentally, because the data improvement is also observed in the continuous rotation method using the CMOS detector, which has some readout noise, and the comparison of data statistics among CCD data described in §3.3.1 demonstrates deterioration of the accuracy of partially recorded reflections by fine φ slicing. These results indicate the importance of the `shutterless' mode for the fine φ slicing data collection.

The reduction of the overhead time between two successive diffraction images is critical when a fine φ step is used. If the total exposure time of one data set is kept identical, the data-collection time of the continuous rotation method using the CMOS detector does not change, regardless of the rotation step. On the other hand, the data-collection time of the oscillation method using the CCD detector increases as the oscillation step decreases. The simulated data-collection time at various rotation steps is shown in Table 4. Therefore, use of the new method has a significant advantage, in terms of the data-collection time, with regard to the use of fine φ slicing.

4.3. Future prospects for the continuous rotation method using the CMOS detector

Our results show that the continuous rotation method using the CMOS detector C10158DK can be successfully applied to collecting diffraction data at protein crystallography beamlines. However, some improvements to the detector and data-processing software will make the new method even more useful.

One improvement to the detector is the size of the detector area; the detector area of C10158DK is 117.6 × 117.6 mm, which is smaller than that of the CCD detectors currently used in protein crystallography. The size can be increased by aligning multiple CMOS sensors in a matrix or developing a large-format CMOS sensor. The simple architecture of the CMOS detector will make this easy.

The result in §3.2.3 demonstrated the advantage of the CMOS detector for short wavelengths, which is due to the fact that the 150 µm-thickness CsI has a very high absorption of X-rays at short wavelengths (e.g. 97% for a wavelength of 0.8 Å). Thus, this makes the detector suitable for very short (0.5 Å) and ultra-short (0.3 Å) X-ray wavelengths, whose potential benefit was pointed out by Helliwell et al. (1993) for `ideal accuracy' data. On the other hand, the use of C10158DK for longer wavelengths is limited, because the C10158DK uses a carbon fibre plate of 1 mm thickness as a detector window, which absorbs 58% of 1.5 Å wavelength X-rays and more for a longer wavelength. Our preliminary experiments revealed that the removal of the detector window caused a twofold improvement in the data statistics at a 1.5 Å X-ray wavelength. Modification of the window material will make the detector applicable for a very wide range of X-ray wavelengths.

The other points warranting useful effort would be to further increase sensitivity, and to reduce readout noise and dark current. As described in §3.3.1, and exemplified by Fig. 7(d), the smaller rotation steps for the CMOS case only improved the S/N of the strong reflections between 40 and 2 Å for lysozyme but there was no improvement for weak reflections. This is counter intuitive as there should be an improvement for weak reflections especially. This suggests the possibility of a threshold effect of the detector sensitivity disadvantaging the weaker reflection intensities. Although CCD detectors also have such a threshold effect, the accuracy of weak reflection intensities can be improved by elongating the exposure time or increasing the intensity of the incident X-ray. On the other hand, the dark current and the narrow dynamic range make it difficult for the CMOS detector to use these approaches. Therefore, an increase of sensitivity, a reduction of detector noise or a reduction of dark current would be necessary for the X-ray CMOS detector to collect weak reflection intensities more accurately.

Development of data-processing software suitable for the continuous rotation method using the CMOS detector will increase the data accuracy further. The difficulty in processing the CMOS data is due to the difference of the readout timing from the top to the bottom lines of the detector, resulting in gradual changes of the rotation angle in one image. However, no serious problem occurred in the processing of CMOS images with the XDS/XSCALE package; the reason for this may be that the mosaic spread of the crystals was larger than the maximum angular difference. The fastest angular speed of 0.25° s⁻¹ used in this work makes an angular difference of 0.083°. Development of data-processing software taking account of such an angular difference will be required for smaller mosaic crystals, e.g. as exemplified in the finest, most perfect crystal limit of Snell et al. (1995).