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GEOL7333-Seismic Wave and Ray Theory - Day2 08-27-2022-Part2
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00:00 Okay, so we were talking about previously off camera off recording how to
00:08 real data which uh coming out from instruments, which do not record displacement
00:16 though it shows displacement right here. is the equation, we call it
00:20 wave equation and it records displacement, that's not what our instruments record.
00:27 record our instruments record some combination uh and velocity and acceleration and strain and
00:35 so that you know whenever you look data on your workstation screen, you
00:41 wiggles. But there is never any on never, there's never a scale
00:47 your on your workstation. All that is the relative size of those various
00:57 . Because we really don't know. So let's see how we can apply
01:05 recognition of of uh physical reality to fact that this theoretical discussion was in
01:13 of displacing. Take this equation and differentiate both sides by with time.
01:24 sides of time. Okay, so we have three derivatives of of uh
01:30 with respect to time. Take one those three derivatives and and uh take
01:36 of those three derivatives and apply it to the displacement. And you get
01:41 velocity right? So after you've done you have the secondary to respect the
01:47 of the velocity. I'm sorry, it into presentation mode. Oh and
02:00 I should actually uh sit some screen . So okay, so let me
02:06 that again, we're going to differentiate sides of this is with respect to
02:13 to time. As a matter of , I'm gonna do it right now
02:18 front of you but I have to it this way back out of
02:21 So I'm gonna take here uh turn like so yeah. And then I'm
02:38 to um um take another derivative Excuse me, I'm gonna I'm gonna
03:02 okay, so I'm gonna take another on the left side and on the
03:14 side. Okay? And then I'm take this thing that I've just applied
03:29 I'm gonna move it inside here right . And I'm gonna do the same
03:37 over here. I'm gonna move it boots. 2nd. What I want
03:40 do is move this over here. the same thing over here.
04:03 now I'm gonna take this derivative one I just apply. I don't know
04:10 it's so difficult and I'm gonna move inside here and then I'm gonna recognize
04:30 story. Video is simply uh uh gonna call it uppercase V. So
04:41 is the the particle velocity, the of the displacement with respect to
04:48 Okay? And I've got the same over here, separate different going up
05:05 M. Component. Okay, now see this is an equation that looks
05:11 like the original equation but now it's equation for particle boss, same
05:17 same material properties, everything is is same. So uh we can add
05:23 together, right? We can um those two equations together, like so
05:57 a similar thing over here, add right sides together. We're gonna do
06:07 for the M. Component. And so now we have the same
06:15 for a combination of displacement and particle velocity, not wave velocity,
06:21 velocity. And then we can add functions on here. And so then
06:28 beginning to be more like the uh out of our of our instruments.
06:35 a combination of all these defamation And so that's why uh we can
06:44 the simple equation like we start off here um to our data is because
06:55 all that does is it changes. waiver waves are still propagating in the
07:02 way. So that's an excellent Here's an interesting point. And electro
07:10 , they do similar stuff. They have electromagnetic sources and they have electromagnetic
07:16 and the waves travel through the earth a very similar way, but not
07:21 the same because it's highly attentive. of our sensitive waves are weekly attended
07:27 it's highly dispersing. Uh Whereas our waves are weakly dispersing Stephanie. Do
07:34 know what I mean? By It means that the different frequencies travel
07:38 different philosophies. So uh aside from two differences, electromagnetic waves are very
07:46 like uh sound waves because of the generation. They don't travel as
07:52 So they're not as good for exploration most contexts but in some context they're
07:58 they're crucial. Um We don't talk that in this course because this is
08:03 cycling ways and but the electrostatic magnetic are very similar with this difference when
08:11 measure an electromagnetic wave, they know what they're measuring. Their measuring
08:18 And so uh when an electromagnetic uh makes uh looks at his data on
08:27 graph. He know he's got a on there, he knows it's volts
08:31 he knows the source was in volts now. Now our instruments are also
08:37 , but uh but we don't know translation between votes and displacement and
08:44 So we don't know that. So data doesn't have any scale on theirs
08:49 a definite scale. And so they do stuff like inversions. They can
08:54 they can directly invert their data for properties of the uh medium in
09:02 Whereas we have, what we call is not really inversion, it's really
09:07 uh integration. Uh They they can is is mathematical inversion. So they
09:16 do stuff like migration. They do . They do a mathematical inversion.
09:23 uh um those are all good It's important to remember that our wiggles
09:31 mean anything by themselves, but only relationship to other wiggles. Uh and
09:38 arrival time. Uh it compared with I think you captured all of that
09:55 your recording and on your zoom. now I'm going to get out of
10:05 without saving the changes. So final looks good. So I want to
10:31 this money, Which okay, so you still are you seeing this on
11:01 own? So the next topic is waves. So um Stephanie, oh
11:11 at the end of this afternoon you an exam and I will email you
11:17 an exam, just a quiz you tuning in um before Wednesday but also
11:29 gonna have a homework assignment which is write another um uh written question which
11:37 can hand into me next friday. it'll be concerning what we talked about
11:44 afternoon and maybe this morning if you . And if you want more than
11:47 question you can do that. And you're gonna grade, you're you're gonna
11:54 in the papers handing the quizzes, of your hand in the quizzes to
12:01 time before midnight on Wednesday you send to me and I'll have them graded
12:10 uh friday and we'll talk about it . Okay, so body waves uh
12:19 we have we now have a waiver and we have p wave solutions with
12:24 types and how uh we're gonna talk today, many types of solutions and
12:31 uh plane waves come naturally to this . And these can be some together
12:38 many ways to form a crucial, idea that they can form any solution
12:43 summing together plane waves. But if have a localized source, then the
12:49 waves radiate outwards from that source and no plane waves at all. Right
12:53 occurred waste. And so that makes a difference. And then finally we
12:59 to here, which is in the of this course waves and raise.
13:07 gonna talk about wave fronts and and and you'll see the differences and you
13:19 how both concepts are useful. In seismic exploration, we always have
13:29 of receivers and the receivers received the at different times. Obviously the near
13:39 receive it soon and the far ones it later. And the difference is
13:44 move Out. And we're gonna analyze . We're gonna talk about the content
13:51 wave interference that we talked about And then of course, uh the
14:01 equation admits shear wave solutions. And gonna be in our data, although
14:07 do our best to keep them out our p wave data. Uh still
14:11 leak in sometimes. And then, know, what I said about one
14:15 signal is um, another man's Maybe it's a good idea to actually
14:20 at those share waves instead of trying get rid of them. And then
14:25 converted weights. You probably think, know, how converted waves come
14:30 You definitely will know it by the of this afternoon. And then how
14:37 been a coordinated discussion what we call convolutional model of wave fabrication. It's
14:46 way of intuitively thinking about wave And then uh maybe we'll get a
14:53 and we'll get around to talking about seismic images. So we start with
14:59 p waves. So let's uh start and we'll talk about the scale a
15:11 equation um um where the unknown function the pressure and it's very in three
15:18 in time. The equation looks like . Okay, so let's um
15:28 Let's think first about uh motion only in the X- three directions. So
15:34 term is zero and this term is and we have only this. So
15:40 gonna do what we did before we gonna guess and then verify. So
15:45 we're gonna guess uh this solution and we're gonna verify. And how do
15:55 verify while we stick it into the ? So the left side of the
15:58 is uh this because we take the derivative of this thing here with respect
16:06 time and it brings down in front the it means one times one times
16:11 original function. And on the right of the equation, we start off
16:18 this, we uh we plug in all right, our guest here and
16:27 from these two uh g derivatives, get minus one over v square.
16:33 see the coefficient of Z up here minus 1/3. So do that twice
16:41 we get minus 1/3 squared. That from this derivative out in front.
16:46 got the v squared. That comes the equation. These two re squared
16:50 cancel each other. These two minuses each other and we get left over
16:55 this which is the same as Yeah. So we verified that this
17:01 works however, it's not a good . And so so I want you
17:09 tell me, Stephanie, tell me this is not a good solution.
17:22 I think this is a difficult So you talk you tell me why
17:29 is not a good solution. Here's answer. You can't have something like
17:48 in the new in the power and exponent. It's got to be dimension
17:55 . If it's not to mention this there's a big difference here is time
18:00 units of seconds or or or um or days or what whenever you have
18:10 an exponent, it's got to be list. So mm and there's another
18:23 which I didn't even think about unless have pressure. And on the right
18:26 have dimensional. So we're gonna put here a multiplication content but we still
18:31 this problem here in the um um . So we gotta fix it up
18:41 . All exponents must be dimensional. we have to multiply this by um
18:50 a factor which has dimensions one over . And so we're gonna call that
18:55 . That's gonna turn out to be angular frequency of the way. And
19:04 this um constantly that we just put previously that might depend on on omega
19:12 so uh let's check this out. go through the same kind of of
19:17 left side and right side and so . And we get, we conclude
19:22 uh the right side is equal to left side, It still works.
19:26 so is there still a problem? it's not the kind of solution we
19:35 , it's unstable at large. Um time goes to infinity And that large
19:44 goes to zero. So the way solve that is to make it a
19:57 by putting in I the square root -1 right there. So from uh
20:13 , if you remember your your junior , maybe a senior level course in
20:21 , we learned that the exponential to times a factor here is equal to
20:29 of that same factor plus i times sine of that same factor. And
20:36 so that's a fundamental result of complex and you might want to uh review
20:45 uh when I was your age, always bought a text book from the
20:53 at the beginning of every semester and I kept it. So the modern
20:58 do it that way, you buy and keep them. Yeah.
21:05 for example, in this course there's textbook uh Sheriff and Delfin is sort
21:11 a reference book and it's a good , but it's not a textbook.
21:16 text is basically the set of pdf , which I uh put on the
21:21 . So uh do you have something to that uh from your previous coursework
21:29 an undergraduate? Yeah, but the didn't use a textbook. Thank
21:56 Thanks. I'll tell you an embarrassing for my youth. I was about
22:04 years old and I was at a and I met one of the great
22:14 from the previous generation. You might the name Sir Harold Jeffreys, the
22:19 of Jeffrey's, they forget. So was the most highly respected geophysicist,
22:27 part of the 20th century call him Dean of Geophysics. He was a
22:37 at Cambridge, I think. And he was widely respected and made fundamental
22:44 . But he um, wow, didn't keep up with the ties late
22:57 his life, maybe after he Plate tectonics came along. And he
23:04 believe it because he had not believed in continental drift. And he uh
23:13 thank your comics And he lived a old age. He lived about 95
23:22 his dying day. He was fighting the stupidity of those. So I
23:33 him when I was a young man he was an old man and he
23:37 not in a mood to accept any from me about plate tectonics. So
23:43 didn't even try, but I did to shake the great man's hand.
23:48 uh um and then I made a for a social faux pas, Lady
24:00 was standing right there beside uh Harold she was not quite as old as
24:07 was 10 years younger. And so turned to her and I said,
24:11 , Lady Jeffries, what do you ? And she forgive me very kindly
24:19 my ignorance. Just an american She thought uh I am a
24:29 And so I should have known about famous textbook by Jeffrey's and Jeffrey's,
24:34 was the standard textbook and mathematical physics the UK. I should have
24:40 but I didn't. And uh she I am a mathematician. Anyway,
24:50 I immediately withdraw with you from the not wishing to expose my ignorance
24:58 And Sir Harold died a few years that. Still fighting the good fight
25:05 . Okay, so in your are your notes somewhere from your complex
25:12 course, you will have um known identity between this expert e to the
25:21 to the i phi it's exactly equal cosine of five plus i sine of
25:28 . And so this is a good uh to point out that uh
25:40 uh military solutions have both uh even odd parts and even parts of the
25:50 closer, closer minus time. Of the minus offset and the ipod,
25:57 parts have opposite signs. So the solution has both even an odd and
26:04 we could do is we could work everything using these two parts of it
26:11 . Um but it's much easier to to do it together in this form
26:17 uh figure out that at the end the process when we get to predicting
26:22 actual uh an actual observable. We're have both even in odd parts in
26:31 solution. And we will combine these parts of the exponential function in an
26:36 way. So sexually result is It won't have any imaginary component like
26:42 when we finally get to evaluating spectral . So now what we're gonna do
26:49 we're gonna put in i here and that it works in the same logic
26:54 we did it all we do is an I squared right here and then
26:58 squared right here and everything works. now the question is there's still a
27:04 , is this a physically reasonable careful of her after having disposed of
27:11 elementary mathematical issue. Is it physically ? Well, um right side is
27:25 with the left side. Especially, what we just talked about. So
27:32 a real number. This is a number. Don't worry about this.
27:36 may be confident that when we use initial conditions and boundary conditions to solve
27:42 particular problem, any particular problems resulting will be real. So just relax
27:48 that issue. No, this solution a one day solution going only in
28:00 vertical direction. But is it going or down? It's going in the
28:05 of positive Z. Since the phase constant at larger times. If Z
28:13 also larger. so if t is t is getting larger, uh this
28:20 will be the same if Z also larger in the right proportion. And
28:25 what that means is that the phase constant at larger, uh at larger
28:32 of Z plus Z, larger times going in the plus C direction.
28:38 furthermore that that's not the only thing want to have, we want to
28:41 having waves that move in the direction minus. So we just put in
28:46 plus or minus and you can verify this is going so I suppose you're
28:52 little bit surprised to see how many we have to make to this to
28:57 it into a good solution. Now got a good solution for plane
29:08 So now it's is it the only ? Well, you think that's an
29:14 family solution, so we can put here any frequency we want and we
29:19 have a different coefficient for every one them. So that's a family of
29:26 . As a matter of fact. in here, we have assumed we've
29:31 of implied as we've been working through that the velocity is a constant.
29:36 what if velocity is a function of ? It still works, you can
29:43 through it and prove to yourself that no point in proving that, at
29:48 point in verifying this, guess. we ever assume that the velocity is
29:54 of uh of time, it's actually of frequency no doctor about this
30:12 Since the wave equation is linear in some two more solutions with different values
30:20 frequency still works. That's also a that some, why do we call
30:28 plain ways? Well, it's because had no variation in the X and
30:35 directions only in the Z direction. it's like a plane. So that's
30:39 it's still hungry. No. Um is why they're so important. Fourier
30:52 that any physical function of time and may be represented as a sum of
30:56 waves and this is uh this is to Wikipedia so you can look up
31:02 you. Um So because of four work, it means that by finding
31:15 family a plane wave solutions that we found. We've already found all
31:19 All we have to do is find the coefficients and I add all the
31:23 together. These coefficients are called the and they're found by fitting initial conditions
31:30 boundary conditions. Now notice that this oscillates on forever and no matter how
31:39 time gets still oscillating back and forth and Cozzens not getting any bigger.
31:47 getting any smaller. And the same with position Z. Uh we don't
31:56 want that. We want to have solution which is localized in uh for
32:00 , if you have an impulsive we want to have a solution which
32:04 zero uh before the source goes off then dies away after, you
32:14 something dies away gradually after the source finishes however fourier during jesus that any
32:26 signal can be decomposed into a spectacular waves which combine constructively at short times
32:33 destructively of all times. So you , it's, it's okay, you
32:41 take these waves which are not localized time and we can construct a solution
32:48 is localized in time and localized in . Now that's all one day vertically
32:56 . So now let's talk about uh in any direction. And so the
33:04 has a solution like this with infinite of frequencies and all they have is
33:13 affect your product here instead of Uh you said K three times
33:20 We have K vector dot x, . And the relationship between this K
33:26 this omega is given right. And you can verify that this expression still
33:32 in three dimensions. Uh so The wave equation still satisfies the wave
33:39 this verification does require that we have relationship, remember here that it's about
33:48 length of the way back to the , not in its direction, socialization
34:07 we have developed, it is good any frequency in any direction. All
34:18 that was for the scalar wave So now let's consider the factual
34:26 The rich, I'm gonna make a assumption that uh solution looks like this
34:35 a vector, uh constant out It's not a constant. But when
34:41 say constant, I mean it doesn't with time or space, it might
34:44 with frequency. And so we verify this works same kind of logic as
34:53 . Now again for simplicity, we're consider one D. Propagation. But
35:00 from using the vector wave equation. so uh constant here is gonna be
35:06 vector pointing in the Z. This is a unit vector in the
35:12 . And so uh our guess is it's uh plane wave looks like
35:19 Yeah at a given place two different . The difference in phase at two
35:30 times is given by this. So is the phase of time to and
35:35 given positions. The finest the phase time, one at the same
35:43 And so that's uh the Z terms out. And you get only Omega
35:51 T 2 -51. Let's assume that two times correspond to two successive
35:58 So you're sitting at at uh placing Earth. You see a wave uh
36:05 see this wave go by and when axl um in the wave You mark
36:14 time. And then uh the next comes that is two successive peaks.
36:21 we call that a difference in phase two pi and so the difference in
36:27 is given by to pay over uh . And that's the definition of the
36:33 frequency and one over the frequency is period. And do the opposite
36:41 Look at two different places at the time. Go through the same kind
36:48 manipulation. And you find that for successive peaks, uh the wavelength separating
36:55 two peaks is given by the velocity the cycling frequency. Uh or in
37:01 of angular frequency extra fence or two . So now we can see why
37:07 call the velocity the velocity of the . We just found out that this
37:12 the definition of the wavelength and this the definition of the period. So
37:20 wavelength divided by the period. That's of the definition of the wave
37:28 So finally we understand why we identify as the wave. Oh,
37:40 Uh Is this true carefully and why it false? Mhm. We just
38:11 about this. It's false because these unstable. It's not a plane
38:17 It just at time equals infinity. thing gets to be infinity and uh
38:25 equals infinity. This gets to be . So what you need is the
38:29 hear you don't have the eye. now is um is this one
38:38 Well, this one couldn't be true this one doesn't have the eye
38:42 Right. And now we got the here. So now is this one
38:57 ? I think you said yes. uh that is so all we have
39:01 a bunch of terms here. Lots them. And they differ in their
39:11 . We know it's only true if link of this thing of this vector
39:23 . Is related to the velocity in right way. So that's not that's
39:30 assured here. So I don't say it's true with the caveat who was
39:36 a warning? Maybe not true unless have the right magnet. Yeah,
39:45 uh so here's a question about the . It's just one true. I
40:02 warn you. These are trick Remember that the condition between K and
40:22 is a scalar, this is affecting . So this is false because this
40:30 not what we approved and to convince of that, just go back to
40:34 scene. So this relationship between period , correct? Yeah, that's
40:52 Yeah, that one's true. now the only problem with all that
40:58 about plain ways, we never ever any plane waves in our data.
41:09 basically the reason is because our waves from sources and the sources are localized
41:16 . And so the waves spread out the sources and they're always curves.
41:22 they're never ever playing life. So way we deal with us, remember
41:39 is the in homogeneous wave equation for scalar case. And I'm gonna write
41:47 this way and i In the that's just another way of writing out
41:57 zero and it's got in here the of factors and it's got to be
42:08 arranged so that um it's dimensionally For example, this is gonna be
42:21 same VP as we have over here the left side. R zero is
42:26 to be some sort of reference distance we haven't defined yet. Put that
42:31 there to make sure that the whole is um dimensionally correct. And so
42:38 the way we didn't hear this make sure it's because it's got pressure
42:48 . And so um um you tie me let me turn to your
43:00 Is this thing dimensionally correct here? what it means is the right side
43:06 to have the same physical dimensions as left side. And just to remind
43:11 , we decided that these two terms the correct dimensions because uh this del
43:17 has the dimensions of one over distance and one over distance squared times distance
43:25 . Right by time squared leaves one times square. Which is the same
43:30 the physical dimensions here. Now can tell me uh existing have the correct
43:38 dimensions? Good job it's got to physical dimensions of pressure divided by times
43:52 . And here's the pressure. Why it not correct? Well maybe it's
44:20 . So that's why I'm asking you question. So if we write the
44:26 signature like instead of a zero like and have the time variation in
44:33 But meanwhile we put in these factors P squared at R zero. And
44:40 asking it uh considering all of this , is that got the correct physical
44:46 as the left hand side, beg ? Okay. So what we need
45:04 to have pressure divided by times square we got pressure here. So uh
45:11 and this and this better make up um um times square right one over
45:20 is great. So um so here have distance squared divided by times
45:30 And then distance here something distance cubed . Time squared. Okay, so
45:38 that's the physical dimension of times Um that's the physical dimensions of this
45:44 . So what are the physical dimensions delta? Hmm. What makes you
45:51 that? Uh the reason you said , I'll answer the question for
46:03 the reason you said that is because didn't go over it properly. So
46:08 we're gonna do is get out of file and we're gonna go to the
46:18 Cherie So am I still sharing properly zoom? Okay. So what we're
46:28 do now is look up delta. yeah look up the direct delta
46:34 Not not the del operator. Not one gonna go to direct delta
46:42 Well, I got here to do . Here's the direct delta function.
46:48 , this is in one day. . Now, so here's the definition
46:54 the direct delta function. This is we talked about before. It's infinite
46:58 Mexico zero and zero everywhere else. here's what we didn't talk about the
47:06 under this spike From - Infinity to . That integral is one. So
47:16 the spike and it goes up here infinity. But you fight take the
47:20 from here all the way over And that integral has to be
47:24 That's the definition of the dirac delta and one dimension. And so from
47:32 definition it follows that if you take integral of the direct delta function times
47:37 function gonna go over X. That gives the um the the value of
47:46 function at X equals zero. Because thing is zero everywhere. And at
47:52 at the location of zero, it's infinite. And what's the area underneath
47:59 infinite spike? It's it's got infinity the width of it is zero.
48:05 infinity times zero in this case is to be one. That's what it
48:12 here. So that's why when you delta times F you get f M
48:18 . Now that's all for one dimension three D. Very similar. This
48:31 what we were talking about in connection the seismic source. We've got delta
48:37 it's uh it's uh infinite at the zero elsewhere. And in addition we
48:43 this uh condition when you make a integral over all of space, That's
48:51 to be one. And when you a triple integral over all of
48:57 The delta times some function. What get is the value of the function
49:01 zero. Now look at this expression , that's part of the definition of
49:09 . Now you talk tell me what is the physical dimensions of delta?
49:26 correct. Not what you said earlier , you said its dimensions. Now
49:31 can see from this definition it's got dimension, it's got the physical dimensions
49:36 one over length to the Q Let's go back to the one dimensional
49:47 . So here uh the physical dimensions delta of act is 11 over
49:53 Right. And so uh so the dimensions of delta are are inverse um
50:03 square. Okay so now let us back to um here and now.
50:10 what we have here on the right side is pressure times uh X squared
50:16 time squared. And uh here's another of X. We have pressure times
50:25 cubed over time squared. And now dimensions of this are one over X
50:34 . So the dimensions of the whole are pressure over time squared, which
50:38 what it should be. And that's we uh renamed the source strength in
50:45 way to show the pressure explicitly and show um um we didn't have to
50:52 it the velocity this way but I that just for fun but I needed
50:58 additional um uh parameter whose value uh dimensions are the link. So that
51:06 uh huh So the physical dimensions work correctly. Okay now so uh we're
51:20 uh now uh so now we have different equation before we had a zero
51:31 , and we uh we're able to talk about solutions being plane waves,
51:35 now we've got a source, such different equation. So we're likely to
51:40 different solutions. And so what I'm to guess, here's what I'm going
51:44 guess is the solution is a sum plane waves, but also with some
51:51 normalization. Uh I'm gonna have one R here, and that's gonna give
51:56 geometrical spreading. And then to make to make the units right. I'm
52:02 multiply by that same quantity R. . So, uh this is
52:06 And then just for fun, I'm put in here this end where n
52:10 the number of terms in the um in the sun. So, and
52:17 be three, or it might be , or it might be 560 who
52:21 what it is, but it's gonna out. So, as I
52:24 down here, it's just a four decomposition with a guess about geometrical spreading
52:30 here. So, uh so then put that guess uh into the
52:42 So, in the in the uh the equation on the left hand
52:47 there appears to quantity um uh, operator times P. So, uh
52:55 on that guest that we just made laplace operator uh with fearful symmetry.
53:03 not talking about any variation with asthma anything like that. Uh uh if
53:10 work through the uh the application of spherical combustion operator which I gave you
53:18 , operating on the uh the uh uh uh term here, you're gonna
53:26 up with a term like this which uh familiar to you perhaps. But
53:32 here we have the uh operating on over R. And so without
53:46 I'm just going to tell you that the closing of the one over our
53:50 is the direct delta function where the sign. And you can see a
53:56 of that. Let's see here. , the proof of that is in
54:00 Gloucester. Okay, so putting this the wave equation, this is what
54:08 just did right there. Here's the of the wave equation. So we
54:13 on the left hand side, the with our guests in there, we
54:17 uh the same some uh and we minus omega N squared because this is
54:25 end uh something over in frequencies. for each term we gotta minus omega
54:34 . And then uh from the uh this term you get from the previous
54:39 , this quantity here, this is from the previous page. So we
54:44 terms. And so this left side it here, left side begins to
54:51 like this. And uh because this here, this vanishes. So the
55:02 side is just this thing here, came from the source term here,
55:20 only working on with the left side the wave equation. So we put
55:26 the left and the right sides. here is the right side uh showing
55:32 source term. And uh just cancel the common factors you're left with this
55:39 here, cancel common factors out of and left it here. And if
55:44 look uh this with a sharp eye by mr fourier, you see that
55:52 left side is just the fourier decomposition the pressure pulse. So this uh
56:02 actually is true, should have a mark here, which then I take
56:08 . But so what it means is guest for the solution is valid.
56:17 these are are radiating circular ways which geometrically according to one over R.
56:24 that's the guest that we put in that's the uh and we just
56:34 So what are these waves like? , they oscillate because of this thing
56:38 . And as they go out as increases, these waves decrease in amplitude
56:45 . For all frequencies Hugh medical spreading independent of frequency according to this
57:03 Let me think about this. I we could have our zero is a
57:10 of frequency that is not specified. Stephanie, is this true or phones
57:19 is our description of radiating waves radiating from the source at the origin.
57:30 you see it's got a sum of in terms have constants in here,
57:35 respectful constants. And uh there was plane wave But each uh each one
57:43 those is some of those decreases in according to one over r. Now
57:51 question is because of this one over active decay geometrical spreading is just like
57:58 gen u. Ation prove are That's a bit of an unfair question
58:07 we haven't talked about continuation. Uh It's it's a bit of
58:16 But you know the answer to that you look at seismic data. And
58:22 when when you look at seismic real data on a workstation and you
58:27 at long reflection time. So look the bottom of your screen. Is
58:31 uh the same frequency content or lower content? Or higher frequency content than
58:37 early arrivals? Yeah it's lower. why is it lower? It's because
58:48 high frequencies have been attenuated away. our first approximation the attenuation is the
58:56 for all frequencies evaluation per cycle. the high frequencies make more cycles per
59:04 . And the low frequencies. So attenuate more per second. But per
59:10 , they attenuate uh about the same per second they attenuate more. And
59:17 that's why the surviving frequencies at long times have lower frequencies. Well that's
59:24 true for this thing here here. geometrical spreading is the same for all
59:31 . So it's a bit of an question. But uh it's a you're
59:36 on your common sense. And on student level familiar familiarity same data and
59:47 got it right? F crush? , that one's true. So yeah
60:06 repeating the wave equation with the sorcerer I'm repeating our guests. And right
60:13 is a little potion operator and it that when the boston operator goes about
60:19 change this part of our gas that uh drag delta function. That's what
60:26 needed to match the source turns. that one is correct. Now.
60:34 . So here it appeals to your sense. If the source were vibrator
60:43 of an explosion, the equation would the same in the solution. Still
60:47 valid. True or false. Yeah course it's false because we assume um
60:59 assumed right here that it's uh radial in all directions. So uh the
61:06 is different. And the solution of would not be valid. Uh We
61:12 have the same hue. Medical spreading all directions for for a radio source
61:19 for a vibrator starts actually. I'm sure that's true. Hold on.
61:31 think that uh sow vibrator source is to be focusing the energy downloads.
61:40 I think that it uh decays geometrically one over r uh that same factor
61:48 vertically downwards and oblique. Thank Yeah the equation is uh not the
61:56 . So this statement is false like said. Okay. Yeah. Everything
62:04 been talking about is waves. So now let's talk about race first
62:11 all. Have you ever seen Have you ever heard or felt
62:19 pray and probably not. Have you seen a ray of light?
62:26 you haven't seen any ray of Look at a laser in a darkened
62:35 . If there's no dust floating in air, you don't see anything until
62:39 hits the opposite wall. The only you see the uh something that looks
62:44 a ray is, if there's dust air and the laser light is scattering
62:50 the dust ray, uh, without dust, there is uh nothing to
62:59 seen. You having your laser here , You see a spot on the
63:03 . It's all you see. You never seen a ray. You see
63:08 of wave fronts. Uh, I think you've seen seismic wave fronts,
63:15 when you throw a rock into a , you see the ripples. Uh
63:19 so that's away from right? And the wavefront is physical and the ray
63:26 a mathematical concept. Okay, so see how this uh, It
63:35 So here's one churn of the solution the scalar wave equation with a source
63:42 it
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