Optical design

Figure 1 is a sketch of a notional prime focus telescope system designed for wide-field and coronagraphic imaging by a 16-meter class telescope. Light passes from the right to the left to reflect from the primary mirror, segmented primary mirror. The box shown just to the right of the prime focus is the prime focus instrument assembly (PFIA) whose diameter is 3 to 4 meters and length a few meters to hold prime focus instruments such as UV spectrometers, imagers, coronagraphs and wide-field cameras. The focal plane is shared (like HST and JWST) with several instruments contained within the PFIA.

Figure 1:

Shown is the schematic of a notional prime focus system. We selected a 16-m segmented diameter F/# = 1.5, with a 24-m focal length and a reverse Schwarzschild relay with a 20-cm segmented active mirror and a convex secondary. This system has a minification of 80 to be compared with the HST WF/PC2 value of ~200. Refractive correctors with internal baffles are used at the prime focus to increase the FOV for UV-Vis applications. There is a field stop at the prime focus. The circle on-axis at the right end of the optical system indicates the location of an instrument: spectrometer or coronagraph..

We select one example instrument, an imaging system, for discussion here. In our notional design, the prime focus is 24-m from the vertex of the primary. Light passes through a field lens and expands to fill the primary of an inverse Schwarzschild^{2 3}. This reimaging system is mounted just beyond prime focus. The field lens relays an image of each segment of the primary onto the 0.6-meter diameter active segmented first reflecting surface of the Schwarzschild. Primary mirror wavefront errors (tilt, piston and surface) caused by fabrication and time-dependent thermal, dynamics and structural effects are compensated for at the 60-cm diameter segmented active Schwarzschild primary mirror. Light reflects to the convex tertiary and then to the focal plane indicated by the circle or to a dispersive element in the case a spectrometer is chosen. The convex curvature on the tertiary combines with the concave powered mirrors 1 and 2 to provide a flat field at the focus. Adjusting the design of the Schwarzschild-relay controls the detector sampling frequency. For small fields of view such as those needed for exoplanet coronagraphy and high contrast imaging of stellar neighborhoods, the transparent field lens could be swung out of the way and replaced by a complex mask for unprecedented direct control of the unwanted radiation after the first reflection. There are no fold mirrors in the system, which will minimize polarization aberrations and their deleterious effect on the PSF^4,5.

Image quality & exoplanet applications

Breckinridge⁴ and Chipman⁵ showed that polarization accumulated by wavefronts as they propagate through an optical system has an important role in image quality. The polarization aberrations: diattenuation and retardance change the shape and intensity of the system PSF, in addition to causing a faint but important broad “skirt” or tapered plateau of light which is centered around the base of the PSF where exoplanets hide within the diffraction pattern. The intensity of this light increases as the square⁵ of the number of uncompensated reflections in the system. Coronagraphs designed for the LUVOIR and HabEx optical systems, which will characterize terrestrial exoplanets need to minimize the number of reflecting surfaces and balance or mitigate the polarization aberrations.

Wide field of View

High quality wide field imaging array at the prime focus is achieved using a two to four element refractive corrector. C. G. Wynne⁶ designed prime focus field correctors for the Blanco 4-meter telescope at Cerro Tololo (parabolic) and correctors. Near diffraction-limited fields of view up to 40 arc minutes have been achieved at a 4-meter telescope F/# = 2.7⁷. The dominant aberrations are coma and astigmatism both of which affect the symmetry of the PSF. If we use the structural aberration coefficients developed by Gardner⁸ and Sasian⁹ used by Breckinridge¹⁰ we find that coma increases linearly with the product of diameter times field angle and that astigmatism increases linearly with diameter times the square of the field angle. At wide fields astigmatism will dominate. Scaling we find that a 12-meter should have diffraction-limited performance over a 5-arc minute FOV. The 12-m EST diffraction spot size of 8 milliarcseconds at 400nm gives >10⁺⁹ independent Nyquist sampled resolution elements across the 5-arc minute FOV object space. Additional research into innovative optical designs specifically focused on increasing this field of view may double the FOV.

Radiation damage to glasses was extensively studied by the Kepler project, which uses a Schmidt transparent lens corrector. Glass types with the correct dispersion and index properties that also survive long duration in space have been studied¹¹, but additional work is needed.

Prime focus potential advantages

The potential advantages of prime focus space telescope that need further investigation are:

Further investigations are needed to explore possible other advantages of the prime focus such as: Free form optics - The diffraction limited FOV achievable with the inverse Schwarzschild, in the presence of the radiation-hard apochromatic prime-focus aspheric correctors will be better optimized using modern free-form optimization¹⁴. Polarization aberration balancing will be needed to optimize the coronagraph contrast. Telescope dynamics - Advantages of the two-body dynamics of the prime-focus (primary and instruments) compared to the three body (primary, secondary, instruments) dynamics if the instruments are behind the primary.

More optical surfaces than necessary

Each reflection and every dielectric surface in a space telescope/instrument system has several technical performance and financial costs associated with it. These are:

Clearly if we reduce the number of optical surfaces between the primary mirror and the science instrument focal plane, there is a very high probability that cost will be reduced. Assigning a specific cost to each of the items in the list above is not possible without a detailed design for the system. However we can take a different look at this problem and estimate costs.

The diameter of the telescope primary mirror determines the system angular resolution and the surface area encompassed by this diameter determines the amount of power, and thus SNR at the focal plane. If we constrain our argument to power at the focal plane, we obtain an estimate the of cost at the systems level based on the growth of the telescope aperture required to hold the focal plane flux constant (science SNR) in the presence of an increasing the number of mirror surfaces. The effective aperture of a telescope, A_e, for a system whose transmittance is τ is given by

where A_T is the light collecting area of the telescope. The cost of a telescope increases with aperture and large-aperture space-telescope engineers⁴ believe that the cost C increases as the 2.2 power of the aperture or

The entire optical system includes all mirrors and surfaces in both the instrument and the telescope. If we let R_i be the reflectivity of the i th mirror out of a total of k mirrors and S_j be the transmittance of the j th surface out of a total of l surfaces in the system, then the total intensity scalar transmittance τ of a telescope is given by

For this discussion, we consider the losses caused by reflections from the highly reflecting broadband metal coatings required to have a high-transmittance telescope.

Equations 4 through 6 enable us to assign an average cost factor per optical reflection to a telescope opto-mechanical design. Table 1 shows the growth of telescope diameter and cost required to hold the focal plane flux constant in the presence of an increasing the number of mirror surfaces used by the optical designer as a function of the average reflectivity of the mirrors within the optical system, assuming that cost increases as the 2.2 power. The number of reflections shown varies from 4 to 20. Telescope diameter and cost is shown for 98, 95 and 90 percent reflectivity for each mirror for the total number of optical system reflections between 4 and 20.

Table 1.

Growth of telescope diameter and cost required to maintain the focal plane flux constant in the presence of an increasing the number of mirror surfaces used by the designer within the optical path. Column 1 shows mirrors reflectivities of 98, 95 and 90 percent. Columns 2 through 5 give the diameter and cost factor increase needed for a 4, 8, 12, 16 and 20-meter aperture.

Table 1 shows that if we assume our end-to-end optical system has 8 reflections then in order to overcome those power losses incurred by using 98% reflectivity optics requires that we increase the diameter by 7% and the cost increases by 17%. The LUVOIR telescope system concepts range from 12 to 20-meter diameter aperture. We assume a baseline 16-meter aperture at a cost of $5B and calculate a cost increase to restore the power absorbed by the 8 mirrors. This cost is $850 million or about $100 million per mirror.

The 98% reflectivity per mirror we assumed in the above calculation is very optimistic. Mirrors are coated and then integrated into an optical system over a period of months. Even in a clean room mirror reflectivities typically degrade to about 96% or less before launch, to bring the cost, in terms of aperture up to well over $100 million for each reflection.

It would seem prudent to expend some technology dollars today to investigate innovative designs for imaging and spectrometer and integral field unit systems to

The Rowland circle spectrograph

Here we provide an example of how these functions are combined to provide the science community with the highest possible transmittance system for UV spectroscopy. Both are based on the principle of the Rowland circle. Figure 1 shows the simplest possible broad-band spectrometer. The entrance slit to the spectrograph extends normal to the sheet in Fig 1. It is located at the image plane of an imaging system. The light that converges to the mage plane where the slit is located is traveling right to left in this drawing. The slit is located near the center of curvature of the spherical diffraction grating. Light diverges after this slit to fill the spherical concave diffraction grating, which is shown to have radius r. The reflected light is quasimonochromatic and the spectrum of the source admitted to the spectrograph by the entrance slit dispersed onto a curved focal plane of radius r/2 shown in Fig 1 between λ₁ to λ₂.

Figure 1.

Sketch of the Rowland circle spectrograph. Light, travelling right to left enters the slit in the upper right and fills the concave grating of radius r. Light reflects from the grating and is focussed by the optical power onto the curved grating substrate onto a focal surface at radius of r/2 as shown in this figure. The slit length is extended normal to the page and the r/2 is the surface corrected for the sagittal image, which is also normal to the page.

While the classical Rowland circle spectrometer with a concave spherical mirror provides good spatial resolution on a curved surface in the (x-y) plane of the Rowland circle, the slit images suffer from a large amount of astigmatism in the out of plane (y-z) direction, leading to tall, curved slit images. This focal plane curvature can be adequately corrected^{22 23 24} by curving the grating grooves to produce a flat field, with some loss in resolution.

Figure 2, below shows how this spectrometer is used in a UV spectrometer telescope system.

Figure 2.

Optical configuration for a classic UV spectrometer. UV radiation enters the system from left to right, reflects from the primary mirror and object space is imaged onto the entrance slit of the spherical concave grating spectrograph. I the radius of curvature of the grating is r, then the radius of curvature of the aberration corrected field is r/2. This is a two-mirror prime focus telescope system.