II.

INTRODUCTION:

The SPace Infrared telescope for Cosmology and Astrophysics (SPICA) mission was selected in October 2007 as a candidate M-class mission for the European Space Agency (ESA) Cosmic Vision 2015-2025 Plan, with the character of “mission of opportunity” [1]. SPICA is led by the Japanese Aerospace Exploration Agency (JAXA) with ESA as a mission partner. It is one of the next generation of large actively cooled cryogenic Space telescopes that will perform observations in the mid and Far Infra Red (FIR) wavelength range. It builds directly on the success of the ESA Herschel telescope and provides spectral overlap in observation capability between Herschel and the forthcoming James Web Space Telescope.

The intended contribution of ESA to the SPICA mission, subject to the Cosmic Vision 2015-2025 down-selection process, includes the procurement of the SPICA Telescope Assembly (STA), the interface management to JAXA of the European instrument SAFARI, collaboration on science operations and possible contributions to the mission ground segment. The SAFARI instrument itself is to be procured by ESA from an European Consortium.

The STA is a 3-meter class Ritchey-Chrétien design which is optimized for the 5 to 210 μm spectral range and operating at a very low cryogenic temperature to ensure sensitivity for very faint Infra Red (IR) sources, and such that FIR instrument performance is limited only by the background radiation from the sky itself. The secondary mirror is foreseen to have refocusing capabilities. Fig. 1 shows the optical configuration for the STA.

Fig. 1.

STA optical design configuration and ray trace sketch. For clarity only on-axis rays are shown.

The physical diameter of the primary mirror (M1) of the STA was originally foreseen to be 3.5 meters. Following a cost reduction exercise an alternative launcher was selected. The new launcher fairing volume does not allow a primary mirror larger than 3.2 meters and necessitates a reduction in the primary mirror (M1) to secondary mirror (M2) spacing. The purpose of the work presented here was to define and assess the theoretical performances of alternative designs implementing the reduction in size of M1 and allowing the integration of several Focal Plane Instruments (FPI) sharing the Field Of View (FOV) of the STA. Furthermore, the question of the position of the STA exit pupil was also studied. Finally, as an outcome of the study, an optical design for the STA was defined as baseline for further study.

III.

DESIGN OF THE TELESCOPE:

A.

Design methodology

The design constraints given in Table 1 are used for the design. The 3^rd order aberrations equations governing the Ritchey-Chrétien telescope combination [2] are used to derive the main parameters (radius of curvature and conic constant) defining the shape of the optical surface of the mirrors M1 and M2. From these parameters are derived the Back Focal Length (BFL) of the STA and radius of curvature (R_focal) of the STA focal surface. However, the values of the parameters obtained with the equations in [2] only accounts for the correction of aberrations up to the 3^rd order. Thus, in order to minimize the Wave Front Error (WFE) over the entire field of view, the conic constants of the mirrors and R_focal are optimized with the commercial software ZEMAX^®. The optimization process has an impact on R_focal but not on the BFL. As shown in Fig. 1, the range of the M1 focal length (f1) is limited only by the BFL range. The allowable values for f1 are respectively between 3180.22 mm and 3238.45 mm, the limits being fixed by the maximum allowable volume for the STA and the minimum value of the BFL (898 mm) needed to accommodate the FPI SAFARI.

Fig. 2.

BFL and R_focal vs. the focal length of the primary mirror.

Table 1.

STA design constraints

Maximum Back Focal Length (BFLmax)	1128 mm
Minimum Back Focal Length (BFLmin)	898 mm
Focal surface radius of curvature (Rfocal)	> 688.5 mm
Focal surface conic constant	-1
M1 maximum clear aperture diameter (M1 CAD)	3.1 m
M1 maximum outer physical diameter	3.2 m (M1 CAD + 100 mm margin)
Mirrors spacing	2511 mm
Spectral range	5 μm to 210 μm
Field of view (FOV) without vignetting	±15 arcmin
Imaging quality	Diffraction limited at 5μm over ±5 arcminDiffraction limited at 30 μm over ±10 arcmin
Focal length	16200 mm

IV.

RESULTS AND DISCUSSION:

The values obtained for the four different cases are summarized in Table 3. The four optical prescriptions of the STA are shown in Table 4.

Table 3.

Summary of the performance metrics. λ is the wavelength.

Table 4.

Optical systems prescription for all cases of study.

For all cases the calculated RMS WFEs are lower than the limit given by the Marechal’s criterion for diffraction limited optical systems. At a wavelength λ = 5 μm the limit is 373 nm RMS and for λ = 30 μm the limit is 2236 μm. Also for all cases, the derived PSF FWHM is smaller than the FWHM calculated directly from the theoretical on-axis Airy pattern. This because the amplitude of the 2D Gaussian function used for the fit is not fixed to the maximum value of the PSF thus leading to a small bias in the FWHM. This bias has no impact on the conclusions.

The comparison of Case 1 with Cases 2 and 3 shows that the reduction of M1 size results mainly in an increase of the OF and a smaller EPD. The others performance metrics are not significantly changed except for the PSF FWHM; this is expected, since the f-number of the STA is larger in Case 1 than in Cases 2 and 3. Fig. 3 shows the optical configuration differences between Case 1 and Case 3.

Fig. 3.

Ray trace on-axis (left) and on-axis beam footprint on M1 (right) for Case 1 (blue) and 3 (red).

When comparing the Cases 2 and 3, we can deduce that the increase of the BFL has little or no impact on either the imaging quality of the STA or the mirrors manufacturability. The main effects are a 13% increase of the OF, due to an increase of the M2 CAD, and an increase of R_focal. For large values of the BFL, the increase of R_focal may ease the design of the FPIs and their alignment with respect to the STA but at the cost of an increase of the EPD obscuration.

The change of the stop position in Case 4 with respect to Case 3 has almost no impact on either the imaging quality or the mirrors manufacturability. A slight increase in the OF is seen and the EPD is also increased. In contrast to Cases 1, 2 and 3, the STA exit pupil is not physically accessible and can not be used by the FPIs as a “cold stop”.

V.

CONCLUSIONS:

Four different optical designs for the STA were studied and their performance metrics assessed.

From the results of this study it can be concluded that the primary impact of the reduction of the M1 physical diameter from 3.5 m to 3.2 m is a reduction by 18.5% (in worst case, but excluding additional obscuration due to the M2 mounts and spiders) of the STA unobstructed entrance pupil area. The total throughput of the STA is thus reduced by the same amount. The manufacturability of the mirrors is marginally affected. Furthermore, a shorter inter-mirror spacing and smaller M1 diameter is advantageous for the mechanical response of the STA to vibrations and shock loads.

For a given M1 CAD, an increase of the BFL results in larger values for R_focal and in larger M2 CAD hence an increase in the M2 mass and of the OF. It is thus recommended to have a BFL as small as possible.

Finally, the position of the stop has little or no impact on the performance metrics. In Case 4 the exit pupil is not physically accessible and this makes the straylight and mirrors thermal self emission more difficult to baffle. The STA stop is therefore chosen to be located on M2. In view of the results of this study, the STA optical design for Case 3 is the new baseline for further study.