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Problem I.
-4
1) Speed of sound in PTZ - SH n 4560 Ms . L = Iz = ¥ = 452=9
.Ixion
2×2.5×106
⇒ L = 0.9 mm
2) element #4 : 2- y = ✓ ¥2 = ) 4-624 = 68 mm44 = Z=f§ymoI%
=
4.42×155s
element # 3 .. Zz = ) ¥2 = JUST = 67.08 mm
es - ZI -- ffjf.omm.my,
=
4.35×55s
element # 2.
- Zz - -✓ ¥82 = ✓ 438-4 = 66 . 21 mm
ez - - ZZ - - bfj7.IT#m,
=4.30×155selement # 5 : Zs = J
¥42=) # = 68.96 mm
es = Z{- = g = 4 . 48×155 s
Dtc = ITs - Ey1=0.06 x toS
= o .6×156
S = 0.6 µs
µe , yes . ↳I = o . ,z× , £5 = , ,3× if s = , .rs µ ,DEZ = Its -
Tz I = o . 18×155 = 1.8×156 S = 1.8 µs
3) FD -- DIG = = Ditz - - 41%143%3=6.49 mm
chime the transducer is not circularly symmetric, I will accept
any dimension you chose LD .
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Problem 2 .
• Cosine aperture
tdvantage : the first side lobe is at about - 23 dB
disadvantage : the main lobe is wider .
• Rect aperture
quantage i the main lobe is tighter at -3 dB .
disadvantage : the first side lobe appears at - 13 dB
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Problem 3 .
I .
2. A common compression A use
is : calm ( imam, varying ⇐ will compress the
image .
3.
Come up aieh a function that will weigh the top rows heavily
compared * the deeper
rows . An example would be let weigh each row as : flu ) = K x
*÷ :
comparethis A the o . z - 0.8
image in port 2 . You can see
thetop rows in this one better .
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4.
the point of this problem is to show that higher frequencies
don't make is to the deeperlayers .
As you can see in the frequency spectrum , at deeper layers (
orange ) high frequency
components are vanished .
