3.1. How many Earths could fit under the prominence?  (Earth’s diameter = 12,756 km) 

3.2.  Compare these two graphs. What is different? What is the same? What is the distance in pixels between the apparent edge of the prominence in the image and the edge shown on the graph?

Using Angles to Measure Size: The Small Angle Approximation

The angle covered by an object depends on both its actual size and the distance to the object. Consider the diagram at right that shows a circle with radius (r) representing the distance between the observer and an object. The  width (or size) of the object is D, and θ is the angle subtended by the object. The arc length subtended by the object is s. The arc length of a full circle is the circumference (2πr). The angle θ may be expressed in degrees, which most people are familiar with. But another unit of angle is the radian. The angle θ is one radian when arc length s = radius r, or s = r. 

Since 360°  = 2π radians, that means
      1°   = 2π/360 radians = 0.017 radians
        and conversely,
          1 radian = 57.3° = 206,265”

The relationship between s and r can be written more generally in terms of any angle θ that is measured in radians:

Small Angle Approximation: For very small angles s ≈ D and the angle in radians is roughly equal to the ratio of the width of the object to its distance away

As θ becomes smaller, the arc length s has less curvature and can therefore be approximated by a straight line of length D. When θ is much less than 1 radian, the lengths of D and s become almost equal, which gives us the Small Angle Approximation:


where r is the distance away from the object, D is the size of the object in the same units as r, and θ is the angle in radians.

 
You need to be very careful to keep your units of measurement straight when working with plate scales and the Small Angle Approximation. In order to measure sizes of the objects on CCD images, there are four steps:

1)  Measure the number of pixels covered by the object.
2)  Use the plate scale for the image to calculate the actual angle in the sky covered by the object.
3)  Convert this angle to radians.
4)  Use the Small Angle Approximation to calculate the size of the object given its angle in radians and distance away.

Find Plate Scale of eclipse1

In the image eclipse1 of a solar eclipse in 1991, the angle covered in the sky by both the Sun and the Moon is 1/2°. 
   
a. Use cursor readings in the yellow Status bar or use Plot Profile under the Analyze menu to measure the number of pixels across the width of the Moon in the image.

b. Calculate the ratio of the angle covered by the Moon in the sky when looking at it with your naked eyes to the number of pixels covered by the Moon in the image. This is the plate scale of this image in units of degrees per pixel.

c.  Plate scales of CCD images are commonly expressed in arcsecs/pixel. Use the conversion factor, 1 degree = 3600” (A double quotation mark, “, is the common symbol for arc seconds) to calculate the plate scale of the image of the eclipse in arcsecs/pixel. 

III.  Measuring Size on a CCD Image

Open image hemma.png or hemma.gif.

The image is of Hemma, an HOU student/assistant, sitting at her computer. You can use the Rotate option under Process to make the image right side up. If your computer is slow, rotating it may take a few minutes.

Astronomers usually look at astronomical images where you can’t tell which way is sideways. For this Earthly image, you may want to use the rotate function of your Image Processing software...or not.

a. Use cursor readings in the Pixel Coordinates to determine the number of pixels in the width of the screen on Hemma’s computer.

b. Given the following data:

The height of the active area of Hemma’s screen = 9.5 inches

The distance of the camera from the screen = 36 inches

...use the Small Angle Approximation to calculate the angle covered by Hemma’s screen as observed by the camera.  (See the Measuring Size with Images Discussion Sheet for an explanation of the Small Angle Approximation). This angle is rather large for the Small Angle Approximation but will suffice for this activity.   

c. Calculate the plate scale of the hemma image in arcsecs/pixel. (1 radian = 206,265”)

IV.  Measuring the Size of Astronomical Objects

In this activity, you may first need to do some image processing (using the brightness/contrast/Min/Max adjustment) to make sure you are measuring the entire width of the object. 

Open the following images one at a time and
a. find the object width or length in pixels
b. use the plate scale to calculate the angle in arcseconds
c. use the distance to find the actual size, assuming small angle approximation applies.

A. moon.fts  Object: any one of the craters
Plate Scale:  0.45”/pixel
Distance to the Moon:  3.84 x 10⁸ m

B. jup1.fts    Object:  Jupiter
Plate scale = 0.45”/pixel
Average distance to Jupiter = 7.8 x 10¹¹ m

C. eclipse1.fts    Object:  Sun
Plate scale = 3.0”/pixel
Average distance to the Sun = 1.5 x 10¹¹ m

D. ringnebula.fts    Object: the Ring Nebula M57
       (a planetary nebula; gas from a dying star)
    Plate scale = 0.63”/pixel
    Distance = 2,300 light years (ly)
You need to convert the distance to the Ring Nebula from light years to meters:
1 ly = 9.5 x 10¹⁵ m.

E. m51.fts    Object: M51, a spiral galaxy
    Plate scale = 0.99”/pixel
    Distance to the galaxy M51 = 30 million ly

Extra Challenge:
Determine the field of view for one of the images used in this section (IV). The field of view is the angle covered by the entire image.