Illuminating optical device and semiconductor device manufacturing method

An illuminating optical device comprises a light source for supplying light, and a condenser lens system for collecting the light from the light source and guiding the light onto an object to be illuminated. The condenser lens system has an optical element that has a refractive power, and that can be tilted or decentered with respect to the optical axis of the condenser lens system. By tilting or decentering the optical element, sloped illuminance distributions can be deliberately produced, which can cancel out uneven illuminance distributions having opposite slopes which originally exist in the system. Consequently, satisfactory uniform as well as desired specific non-uniform illuminance distributions can be achieved.

BACKGROUND OF THE INVENTION 
1. Field of Invention 
This invention relates to an illuminating optical device for uniformly 
illuminating an object, which is suitably used in exposure apparatuses for 
manufacturing highly integrated semiconductor circuits. 
2. Description of Related Art 
One example of conventional illuminating optical devices is shown in FIG. 
5, which is designed to uniformly illuminate objects. The light flux 
emitted from the light source 1 is shaped by the light shaping optical 
system so as to fit the fly-eye lens 3. The shaped light flux is divided 
into a plurality of light components by the fly-eye lens 3, and a 
plurality of secondary light-source images are formed in the vicinity of 
the exit plane of the fly-eye lens 3. An aperture stop 4 is positioned on 
or near the secondary light-source image plane in order to limit the light 
flux from the plurality of secondary light-source images. The light flux 
is collected by the condenser lens 5, and guided onto the mask 6 in such a 
manner that the fluxes from the multiple secondary light-source images 
overlap, thereby uniformly illuminating the pattern on the mask 6. The 
pattern image is projected onto the wafer surface 8 by the projection lens 
system 7. 
Because the light flux is divided into multiple components by the fly-eye 
lens 3, and because the condenser lens 5 guides these light components 
onto the mask 6 so that they overlap each other when they illuminate the 
pattern, the light intensity becomes satisfactorily uniform on the wafer 8 
even if the intensity distribution of the original light flux from the 
light source 1 is not perfectly uniform. 
Recently, a technique for varying the aperture pattern of the aperture stop 
4 in accordance with the mask pattern to be projected onto the wafer 8 has 
drawn a great deal of attention because this technique can further improve 
the resolution and the focal depth. This technique is called variable 
illumination. Some examples of aperture patterns of an aperture stop are 
illustrated in FIG. 4. 
However, it was found through various analyses and experiments that if the 
aperture pattern of the aperture stop 4 is changed during the illumination 
of an optical system, the illuminance becomes uneven on the wafer 8. This 
unevenness of illuminance causes the thickness of the circuit pattern 
image projected onto the wafer 8 to vary depending on the position on the 
wafer 8, which variance adversely affects the performance of the resultant 
semiconductor circuit. FIGS. 6 and 7 illustrate typical types of 
unevenness in illuminance. The illuminance distribution having uneven on 
wafer includes convex component as shown FIG. 6 (or concave component) and 
sloped component as shown FIG. 7. In FIG. 6, the illuminance distribution 
is convex, while, in FIG. 7, the illuminance distribution is sloped. There 
are many factors, which may combine with each other, which cause the 
uneven illuminance, for example, manufacturing error in the optical 
system, decentering of the aperture stop, non-uniform distribution of 
transmissivity of the optical system (due to the characteristic of the AR 
coat or dust), etc. 
SUMMARY OF THE INVENTION 
Therefore, it is an object of the invention to provide an illuminating 
optical device which can achieve satisfactorily uniform illuminance, or a 
desired illumination intensity distribution, by eliminating the sloped 
portion, the convex portion or the concave portion of the illuminance 
distribution. 
In order to achieve the object, in one aspect of the invention, an 
illuminating optical device that comprises a light source for supplying 
light and a condenser optical system for collecting the light supplied 
from the light source and guiding the light onto an object to be 
illuminated is provided. The condenser optical system includes an optical 
member that has a refractive power, and that can be decentered from the 
optical axis of the condenser optical system. In this context the term 
"decenter" implies both tilting the optical member with respect to the 
optical axis and shifting the optical member horizontally and/or 
vertically within a plane perpendicular to the optical axis. 
Because the condenser optical system includes an optical member that has a 
refractive power and can be decentered from the optical axis, the sloped 
component comprising the unevenness of the illuminance distribution can be 
canceled out by deliberately producing an opposite sloped component that 
compensates for the original sloped component of the illuminance. 
In the second aspect of the invention, an illuminating optical device, 
which comprises an optical integrator that forms a plurality of light 
sources and a condenser optical system for collecting the light from each 
of the light sources and guiding the light onto an object to be 
illuminated, is provided. The condenser optical system includes an optical 
member that has a refractive power, and can be decentered from the optical 
axis of the condenser optical system so as to adjust the illuminance 
distribution on the object being illuminated. 
The combination of the optical integrator and the condenser optical system 
that includes an optical member which has a refractive power and can be 
decentered can achieve illumination with a highly uniform illuminance by 
eliminating the uneven sloped component of the illuminance distribution. 
This illuminating optical device may further comprise a changing unit for 
varying the shape or the size of the plurality of light sources. In this 
case, the optical member is decentered from the optical axis of the 
condenser optical system in response to the change of the shape or the 
size of the plurality of light sources. 
The changing unit has a plurality of aperture stops, each having an 
aperture whose shape or size differs from the others, and one of the 
aperture stops is selected and positioned on or near a position where the 
plurality of light sources is formed by the optical integrator. 
This arrangement allows so-called variable illumination, in which the shape 
and the size of the light sources are adjusted according to the pattern on 
the mask. Consequently, the resolution and the focal depth can be 
improved. In addition, the optical member having a refractive power is 
decentered from the optical axis of the condenser optical system, in 
response to the change of the shape or the size of the light sources, so 
as to compensate for the sloped component of the uneven illuminance 
distribution caused by the variable illumination. 
The illuminating optical devices provided in the first and second aspects 
of the invention may further comprise an illuminance sensor for detecting 
the illuminance distribution on the object being illuminated. In this 
case, the optical member is decentered from the optical axis of the 
condenser optical system according to the illuminance distribution 
detected by the illuminance sensor. 
The decentering amount required for the optical member can be based on the 
measured illuminance distribution. 
The illuminating optical device of the second aspect of the invention may 
further comprise both an illuminance sensor for detecting the illuminance 
distribution on the object being illuminated, and a driving unit for 
decentering the optical member according to the illuminance distribution 
detected by the illuminance sensor. In this case, the illuminance 
distribution varies in response to the change of the shape or the size of 
the plurality of light sources. 
This illuminating optical device further comprises a decentering amount 
calculation unit for calculating the necessary amount of decentering of 
the optical member based on the detection result of the illuminance 
sensor. In this case, the driving unit is driven based on the calculated 
decentering amount. 
Because the illuminance distribution is detected every time the changing 
unit is activated, and because the driving unit can decenter the optical 
member according to the currently measured illuminance distribution, the 
unevenness of the illuminance due to the change of the shape or the size 
of the light sources can be appropriately compensated for. 
The condenser optical system may have a second optical member which is 
movable along the optical axis of the condenser optical system. 
By moving the second optical member along the optical axis of the condenser 
optical system, the uneven convex component of an illumination 
distribution can be canceled out by deliberately producing a concave 
component to compensate for the convex component. Thus, the movement of 
the second optical member along the optical axis of the condenser optical 
system is effective for correction of the convex component of an uneven 
convex illumination distribution, while decentering of the first optical 
member is effective for correction of the sloped component of an uneven 
sloped illumination distribution. 
The illuminating optical device further comprises a second driving unit for 
moving the second optical member along the optical axis of the condenser 
optical system according to the illuminance distribution detected by the 
illuminance sensor. In this case, the illuminating optical device has a 
decentering amount calculation unit that calculates the necessary amount 
of decentering of the optical member and the necessary amount of 
displacement of the second optical member along the optical axis based on 
the detection result of the illuminance sensor. Based on these calculation 
results, the optical member and the second optical member are 
appropriately driven. 
The second optical member is appropriately moved along the optical axis of 
the condenser optical system based on the calculated displacement amount, 
thereby effectively compensating for the convex component of an uneven 
illumination distribution. 
Preferably, the optical member has at least one refracting surface that has 
an refractive power of .O slashed. (mm.sup.-1) which lies within the range 
0.001&lt;.vertline..O slashed.&lt;0.1. 
This arrangement allows the distortion of the light flux which strikes the 
object being illuminated to be greatly reduced, while producing a 
compensatory sloped component of illuminance distribution sufficient to 
cancel out the unevenness of the illuminance. 
In still another aspect of the invention, a semiconductor device 
manufacturing method is provided. In this method, the illuminating optical 
device described above is used. Then, a mask, on which a predetermined 
pattern is formed, is prepared. Also, a photosensitive substrate is 
prepared. Then, the mask is illuminated using the illuminating optical 
device to form the pattern on the photosensitive substrate. 
Since the photosensitive substrate is exposed to uniform illumination 
light, and any uneven components of an uneven illumination distribution 
have been compensated for, high-quality semiconductor circuits can be 
manufactured, while the yield is increased.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The preferred embodiments of the invention will now be described in detail 
with reference to the attached drawings. The same numerical symbols 
indicate the same elements throughout the drawings. 
FIG. 1 illustrates the illuminating optical system according to the first 
embodiment of the invention. The light source 1 is, for example, an 
excimer laser. The light flux emitted from the light source 1 is shaped by 
a light shaping optical system 2 which includes a cylindrical lens. The 
shaped light flux strikes a fly-eye lens 3, which functions as an optical 
integrator and forms a plurality of secondary light sources. 
A condenser optical system 5 is positioned behind the fly-eye lens 3 in 
order to guide the light flux onto a mask (i.e., a reticle) 6. The light 
that has passed through the mask 6 enters the projection lens system 7 
which projects the pattern formed on the mask 6 onto a substrate 8 that is 
positioned on a plane conjugate with the mask 6. 
An aperture stop 4 is positioned on or near the secondary light source 
plane defined by the fly-eye lens 3. 
The condenser optical system 5 includes a front lens group 5a and a rear 
lens group 5b, both of which are optical members having refractive powers. 
The front lens group 5a is connected to a front group driving unit 11a, 
while the rear lens group 5b is connected to a rear group driving unit 
11b. The driving unit 11a and 11b are connected to a controller 10. 
An illuminance sensor 9 is positioned on the image plane of the projection 
lens system 7, which is aligned with the top surface of the substrate 8, 
in order to measure the illuminance on that plane. The illuminance sensor 
is also connected to the controller 10, and the measured illuminance 
values are input to the controller 10. 
The light flux emitted from the light source 1 is shaped by the light 
shaping optical system 2 so as to be suitable in size for the fly-eye lens 
3. The fly-eye lens 3 divides the shaped light flux into a plurality of 
components to form a plurality of secondary light sources in the vicinity 
of its exit plane. In other words the fly-eye lens as the optical 
integrator forms a plurality of light sources. 
The light fluxes from the secondary light-source images are limited by the 
aperture stop 4, collected by the condenser lens system 5, and guided onto 
the mask 6 in such a manner that the fluxes from the multiple secondary 
light-source images overlap. As a result, the pattern on the mask is 
illuminated uniformly by the overlapping light fluxes. This pattern image 
of mask 6 is projected onto the surface of the substrate (i.e., wafer) 8 
by the projection lens system 7. 
Even if the intensity distribution of the light flux emitted from the light 
source 1 is not satisfactorily uniform, the light intensity finally 
becomes substantially uniform on the wafer 8 by operation of the fly-eye 
lens 3 and the condenser optical system 5. In addition, the resolution and 
the focal depth of the system are improved by the variable illumination 
technique of changing the aperture pattern of the aperture stop 4 
according to the pattern which is to be projected onto the wafer 8. 
As has been indicated above, the condenser optical system 5 includes the 
front lens group 5a and the rear lens group 5b. The front lens group 5a is 
moved along the optical axis of the condenser optical system 5 by the 
driving unit 11a. If the front lens group 5a is moved, a concave or convex 
illuminance distribution can be produced deliberately depending on the 
direction in which the front lens group 5a is moved. FIG. 2 shows an 
example, in which the convex component of the illuminance distribution 
which is caused by changing the aperture pattern is compensated for by 
producing a concave component by moving the front lens group Sa. 
On the other hand, the rear lens group 5b is tilted by the driving unit 
11b. If the rear lens group 5b is tilted, a sloped illuminance 
distribution can be produced as shown in FIG. 3. In this tilting 
mechanism, there are two pivoting axes so that the rear lens group 5b can 
be tilted in either direction with respect to the optical axis of the 
condenser optical system 5. Alternatively, the rear lens group 5b may be 
designed so as to be shifted in horizontally and/or vertically within a 
given plane perpendicular to the optical axis, instead of being tilted. 
Thus can be achieved the same effect as with tilting. 
The refractive power arrangement of the condenser optical system 5 and the 
position of the pivoting axes are selected so that the change of the 
telecentricity of the wafer surface caused by the movements of the front 
and rear lens groups 5a and 5b does not significantly affect the system. 
Because, in this embodiment, unevenness of the illuminance distribution is 
corrected by adjusting the positions of the front lens group 5a and/or the 
rear lens group 5b, both of which are optical elements having refractive 
powers, there is no light-quantity loss, unlike the case in which the 
unevenness is corrected for by adjusting the transmissivity of the lens 
using, for example, a filter. 
The fly-eye lens 5 may be replaced with, for example, an optical rod which 
also functions as an optical integrator. In addition, although only one 
optical integrator is used in this embodiment, two optical integrators may 
be used to further improve the uniformity of the illuminance. 
FIG. 4 shows examples of aperture patterns used in the technique of 
variable illumination. FIG. 4(a) shows a round aperture having a 
relatively large diameter, FIG. 4(b) shows an annular (or zonal) aperture, 
FIG. 4(c) shows a round aperture having a relatively small diameter and 
FIG. 4(d) shows four small round apertures each positioned the same 
distance from the center of the aperture stop. Among these patterns, a 
suitable one is selected according to the pattern to be printed on the 
wafer. 
If the aperture pattern shown in FIG. 4(a) was selected first with a 
uniform illuminance distribution, and if this aperture pattern was changed 
to that shown in FIG. 4(b), then a slope component and a curved component 
of unevenness arise in the illuminance distribution. This can be caused by 
many factors, such as manufacturing errors in the optical systems, 
decentering of the aperture stop, a fluctuation in the transmissivity of 
the optical system due to the nature of the AR coat or dust. In general, 
if the aperture pattern of the aperture stop changes, the illuminance 
distribution inevitably becomes uneven. 
In order to correct for the uneven components of the illuminance, the front 
lens group 5a and the rear lens group 5b of the condenser optical system 5 
are adjusted in this embodiment. In particular, the front lens group 5a is 
moved along the optical axis of the condenser optical system 5 to 
compensate for any uneven curved component of an illuminance distribution, 
while the rear lens group 5b is tilted with respect to the optical axis to 
compensate for any uneven sloped component of an illuminance distribution, 
in order to keep the illuminance distribution substantially uniform. 
The degree of unevenness of the illuminance distribution is measured by the 
illuminance sensor 9. Based on the result of this measurement, the 
controller 10 calculates the appropriate amounts of displacement and tilt, 
respectively, of the front lens group 5a and the rear lens group 5b. The 
driving units 11a and 11b drive the front lens group 5a and the rear lens 
group 5b, respectively, to compensate for the uneven illuminance 
distribution. 
The measurement, calculation and driving are repeated until the uniformity 
of the illuminance distribution becomes satisfactory. In other words, 
these operations are repeated until the unevenness is reduced to within a 
predetermined acceptable range. 
Alternatively, optimum positions of the front lens group 5a and the rear 
lens group 5b may be decided and stored in advance in association with the 
corresponding aperture patterns. In this case, the front and rear lens 
groups 5a and 5b are moved directly to the optimum positions stored in the 
controller 10 in response to a change of the aperture pattern of the 
aperture stop 4. This can achieve quick adjustment as compared with the 
previous example (in which positioning of the lens groups 5a and 5b is 
repeated based on the measurement results of the illuminance sensor). 
However, if the unevenness pattern of the illuminance distribution has 
suddenly changed due to some previously unaccounted factors, the optimum 
positions must be set and stored again (i.e., the optimum positions must 
be stored in the controller 10 again). 
FIG. 9 illustrates the illuminating optical device according to the second 
embodiment of the invention. In this figure, the portion of the 
configuration from the fly-eye lens 3 (which functions as an optical 
integrator) to the mask 6 being illuminated is shown. The condenser 
optical system 5 includes a front lens 5a, which is positioned closer to 
the fly-eye lens 3, and a rear lens 5b, which is positioned closer to the 
mask 6. The rear lens 5b has a refractive power, and is tilted with 
respect to the optical axis of the condenser optical system 5. The rear 
lens 5b is connected to a driving unit 11b (not shown in FIG. 9) as in the 
first embodiment shown in FIG. 1. 
Suppose that the radius of curvature of one lens surface, the lens surface 
in the lens 5b, is r (mm), and that the incident refractive index and the 
exit refractive index in the lens surface in the lens 5b are n1 and n2, 
respectively, Then the refractive power .O slashed. (mm.sup.-1) of this 
lens surface is expressed as 
EQU .O slashed.=(n2-n1)/r (1) 
If the lens 5b has at least one refractive surface having a refractive 
power .O slashed. that lies within the range 0.001&lt;.vertline..O 
slashed..vertline.&lt;0.1, then a sufficient amount of sloped component whose 
slope is opposite in sign to the sloped component of the uneven 
illuminance distribution that was caused by changing the aperture pattern, 
can be produced by simply tilting the lens 5b. Consequently, distortion of 
the conical light flux that should converge on a certain point of the mask 
surface 6 is reduced to a minimum. This type of distortion is generally 
caused as a side effect of changing the aperture pattern. 
FIG. 9 illustrates the condenser lens system 5 of this embodiment. Although 
the lens 5a is a single lens whose surface has a refractive power .O 
slashed., the lens 5b may be designed as a lens group consisting of two or 
more lenses. In this case, any one of the lenses comprising the rear lens 
group 5b should have a refractive surface whose refractive power lies 
within the range 0.001&lt;.vertline..O slashed..vertline.&lt;0.1. 
FIG. 8 shows the actual parameter values of the illuminating optical device 
shown in FIG. 9. In this table, the radius of curvature and the distance 
between two adjacent lens surfaces are given in millimeters (mm). The 
abbreviation "inf" denotes infinity. S1 denotes the incident surface of 
the fly-eye lens 3, and S2 denotes the exit surface of the fly-eye lens 3. 
The fly-eye lens 3 consists of a 10.times.10 lens matrix, each lens having 
dimensions of 2 mm.times.2 mm. S3 denotes the aperture stop whose 
effective diameter is 20 mm. S4 through S7 denote the lens surfaces of the 
lenses 5a and 5b of the condenser optical system 5. S8 is the mask surface 
(i.e., the illuminated surface) 6. 
Each distance between two adjacent lens surfaces listed in this table is 
the length from the lens surface listed in the same row to the next lens 
surface. For example, the distance listed in the first row (for S1) 
indicates the length between S1 and S2. Each index of refraction 
corresponds to the distance listed in the same row, and indicates the 
index of refraction of the material that fills this distance. For example, 
the value "1.50000" cited in the first row denotes the index of refraction 
of the fly-eye lens 3 which is made of glass and has an on-axis distance 
of 12.0 mm between the incident surface S1 and the exit surface S2. 
From this data, the refractive powers of the two surfaces S6 and S7 of the 
lens 5b can be calculated from equation (1): 
EQU .O slashed.(.sub.S6)=(1.5-1.0)/100=0.005 
EQU .O slashed.(.sub.S7)=(1.0-1.5)/(-1000)=0.0005 
Surface S6 satisfies the condition 0.001&lt;.vertline..O 
slashed..vertline.&lt;0.1, while S7 does not. Since at least one surface of 
the lens 5b satisfies this condition, the lens 5b can produce a sufficient 
compensatory uneven slope component of an illuminance distribution. 
If the lens 5b is in the right position, without being tilted, in the 
illuminating optical device of FIG. 9, the illuminance distribution is 
symmetric as shown in FIG. 10. Then, if the lens 5b is tilted by 3A 
without changing the aperture pattern, the illuminance distribution 
becomes asymmetric as shown in FIG. 11. The higher the image height, the 
greater the illuminance. The illuminance difference between the image 
heights of 20 mm and -20 mm is as much as 3%. 
As has been explained, the lens (or the lens group) that is to be tilted 
must have at least one surface that has a certain degree of refractive 
power. If that surface has a large refractive power, a sufficient amount 
of compensatory unevenness can be produced with a small tilt. However, a 
large refractive power is likely to cause the conical light flux 
converging on the mask surface to deform as a side effect. Therefore, the 
preferred range of the refractive power is 0.001&lt;.vertline..O 
slashed..vertline.&lt;0.1. 
In this embodiment, the lens 5b that has a surface whose refractive power 
satisfies the condition 0.001&lt;.vertline..O slashed..vertline.&lt;0.1 is 
tilted with respect to the optical axis in order to compensate for the 
sloped component of an uneven illuminance distribution. However, as an 
alternative, this lens 5b may be moved within a given plane perpendicular 
to the optical axis of the condenser optical system 5, instead of being 
tilted. This can achieve the same effect as tilting, and effectively 
correct for the sloped component of the unevenness. 
After the illuminance distribution is corrected by the condenser optical 
system, the mask 6 is exposed to the illumination light in order to 
transfer the pattern onto the wafer. This process is called a 
photolithographing step. The mask 6 is positioned in the object plane of 
the projection lens system 7, while a wafer, that is, a photosensitive 
substrate 8 is positioned in the image plane of the projection lens system 
7. The image of the mask pattern is transferred onto the photosensitive 
substrate (the wafer coated with photoresist) through the projection 
optical system 7. The exposed portion becomes soluble in an etchant. 
After the photolithographing step, the wafer is developed, and the surface 
of the wafer is etched, while the portion that is still coated with a 
resist layer (i.e., that was not exposed to the illumination light) 
remains. After the etching step, the unnecessary resist layer is removed, 
whereby the wafer, on which a plurality of patterns are printed, is 
completed. In the next step (a dicing step) of the assembling process, the 
wafer is cut into chips so that each chip has a pattern. Then, each chip 
is provided with interconnections (in a bonding step), and packaged (in a 
packaging step), whereby a final semiconductor device, such as an LSI, is 
completed. 
In this example, semiconductor devices are manufactured by the 
photolithographing step using a projection-exposure apparatus that 
includes the illuminating optical device of the present invention. 
However, many other semiconductor devices, such as liquid crystal devices, 
thin-film magnetic heads, and image-pickup devices (CCDs) can also be 
manufactured using the illuminating optical device of the present 
invention. 
In the embodiment, the pattern of the aperture stop is changed in order to 
change the shape of the secondary light source in accordance with the 
pattern to be exposed. However, the invention is not limited to this 
example, but any methods that can change the shape of the secondary light 
source can be used. For example, the cross-sectional shape of the light 
flux striking the fly-eye lens 3 may be changed using a cone lens. 
Further, a super-high-pressure mercury-vapor lamp may be used as the light 
source, in place of the excimer laser. In this case, the light is 
corrected by an elliptical mirror and guided to the optical integrator 
(i.e., the fly-eye lens). 
As has been mentioned above, the rear lens 5b (or the rear lens 5b group if 
it includes multiple lenses) may be shifted within a plane perpendicular 
to the optical axis of the condenser optical system, instead of being 
tilted, depending on the structure of the entire optical system. This can 
achieve the same effect as tilting. 
In the case of shifting the rear lens group within a given plane, in order 
to reduce the change of the telecentricity due to the lens shift, it is 
preferable to design the optical system so that two or more lenses can be 
shifted in different directions. 
Although, in this embodiment, the illuminating optical device of the 
present invention is applied to projection-exposure apparatuses for 
projecting a pattern of a mask 6 onto a wafer 8, it is also applicable to 
contact-exposure apparatuses or proximity-exposure apparatuses. 
With this illuminating optical device, various types of uneven illuminance 
distributions due to, for example, changes in transmissivity of the 
optical system which occurs as time passes, or changes of the light 
source, or maintenance operations, can be compensated for. No matter what 
the cause is, uneven illuminance distribution can be effectively 
corrected. 
In this particular embodiment, the unevenness of the illuminance 
distribution on the wafer 8 is corrected in order to obtain uniform 
illuminance distribution. However, the present invention may also be 
applied to the case in which it is desired to make the illuminance higher 
or lower in the peripheral area of the wafer than in the central area 
depending on the mask pattern or other factors of the optical system. The 
illuminating optical device of the present invention can easily and 
precisely control the illuminance distribution, and produce a desired 
illuminance distribution simply by adjusting the front and rear lenses. 
Instead of moving the front lens along the optical axis and tilting or 
decentering the rear lens, the illuminating optical device may be designed 
so that the front lens is tilted or decentered and the rear lens is moved 
along the optical axis. 
In this way, according to the invention, very minute semiconductor-circuit 
patterns can be accurately transferred onto wafers by compensating for 
uneven components (such as sloped components or concave or convex 
components) of an illuminance distribution by tilting or decentering some 
or all of the lenses of the condenser optical system and by moving some or 
all of the lenses of the condenser optical system along the optical axis 
thereof. 
Although the invention has been described by way of exemplary embodiments, 
it should be understood that many changes and substitutions may be made by 
those skilled in the art without departing from the spirit and the scope 
of the invention which is defined only by the appended claims.