Přepis řeči - EFFICIENCY EVALUATION AND ORTHOGONAL BASIS DETERMINATION IN FUNCTIONAL HRTF MODELING

0:00:13	you
0:00:14	a fine
0:00:15	we work
0:00:17	uh in which he that issue
0:00:19	oh well will be C i E
0:00:22	oh a function of
0:00:23	yeah
0:00:24	mean
0:00:26	oh what
0:00:27	we action
0:00:28	a a yeah for had a
0:00:31	a function
0:00:32	oh would you that of a function i three
0:00:36	oh the future it actual P in a total of not
0:00:41	it's a a a a single the issue and uh it's all those a you know because
0:00:46	uh one thing to have a different difference
0:00:49	oh it's was five so you know have and total
0:00:52	um
0:00:54	it's not yeah
0:00:55	um can be a change just you three five regiment
0:00:58	oh
0:00:59	of of of a should a shot yeah
0:01:02	i i but is only
0:01:04	um
0:01:05	a response and
0:01:07	uh sum
0:01:08	some
0:01:09	they uh some spatial position and
0:01:12	the whole procedure is
0:01:14	oh we see time as you me
0:01:17	so you want to have a but and uh
0:01:20	can you model to recreate then
0:01:22	in we a charge yeah
0:01:24	oh but a higher order to C
0:01:27	yeah
0:01:28	i'm going to uh uh and for the use the three D five you
0:01:32	a a continuous hrtf model
0:01:35	uh
0:01:36	here's the
0:01:37	a a a a reference
0:01:38	with with the house
0:01:40	uh that's we can see that
0:01:42	um in the model
0:01:44	model of is the frequency components to from
0:01:48	spatial component
0:01:49	and because call it so that the you know
0:01:52	oh function
0:01:53	and it
0:01:54	a a very easy to reconstruct a shot yeah
0:01:57	at a at a a a three that they shouldn't and in the and
0:02:01	a and G O frequency point
0:02:05	a
0:02:05	we have
0:02:06	to question is for this model
0:02:08	oh well as to how should
0:02:10	it this model
0:02:12	and the seconds
0:02:13	i also and that's if you are are also if representation is that we
0:02:19	to here
0:02:21	oh oh one of this question
0:02:23	oh first the we you can have a you know that he man to match to they should be and
0:02:29	then oh we use the true
0:02:31	a he met to evaluate the function able
0:02:36	there are very
0:02:37	oh we have you
0:02:39	a random or it can be expressed as a linear combination
0:02:43	oh on it and then no determined that
0:02:47	deterministic all normal functions is weighted a random variables
0:02:51	oh the um that C functions are orthonormal with
0:02:56	read that to and in a product
0:02:59	in fact is
0:03:00	we use a rate be free small approximate this is
0:03:04	using a an it's number of of the old normal function
0:03:08	then and O
0:03:10	the expected value of the squared norm of error of the phoenix representation
0:03:16	can be given by these uh by prominent a two
0:03:20	where a is the random process
0:03:22	and has a a it
0:03:25	representation of the random four
0:03:28	uh the core work if they don't be
0:03:31	also also no expansion the or
0:03:35	so that he man
0:03:37	a now we focus on a team for at least for illustration
0:03:42	but we have a a random you find on them
0:03:46	and that interval with zero mean and and in in the G
0:03:50	you can handle
0:03:52	um all normal compression be in a four inches rule that
0:03:59	um
0:04:00	the random draw that can be right yeah
0:04:03	um
0:04:04	and the
0:04:06	you combination or you know
0:04:09	uh uh another
0:04:12	uh
0:04:13	or in finance
0:04:14	uh
0:04:15	the complete
0:04:17	a basis
0:04:18	and way by a very well is a random variable is given by the end of all that so at
0:04:24	the end
0:04:25	the complete basis
0:04:28	and the truncation
0:04:30	um
0:04:31	for for five
0:04:32	or shows the arrow for uh
0:04:36	oh of in a representation
0:04:39	and the fact that the right along
0:04:43	oh oh error
0:04:45	a we a good a part of um that thing and so we can see that
0:04:50	that was that so will change
0:04:52	and and it you can do
0:04:55	oh in that that is all of the
0:04:57	a a representation
0:04:59	so to the meeting my the that have that
0:05:02	oh oh we need to make my
0:05:04	uh the second time
0:05:07	now
0:05:07	oh you got a a a a a second term you take
0:05:12	that second so
0:05:14	that second so um
0:05:15	a a you know by
0:05:17	a by a far
0:05:19	as as useful we a random variable is
0:05:22	uh a given by a
0:05:24	you know but that so at the end i T so from the calculation
0:05:29	uh
0:05:31	they
0:05:34	they fire
0:05:35	a can be right yeah
0:05:38	a a problem that
0:05:40	uh where yeah
0:05:41	see the autocorrelation function of the random process
0:05:46	and
0:05:47	the uh a a a at the one change
0:05:50	so
0:05:51	we can say that
0:05:52	a a a a a a a mean it's on the choice of the complete a base
0:05:59	okay
0:06:00	but to
0:06:01	uh uh any a complete or normal because can be used
0:06:05	so we have a question which is a that
0:06:08	now a a a a a just five C
0:06:11	uh uh i i think of of the for
0:06:14	in will in creation with for no
0:06:17	the also correlation function of the random drug that's
0:06:20	and then we use each
0:06:23	um i think function
0:06:24	uh to we spend the random for that
0:06:28	at the formal or the and and the
0:06:30	oh random for a random variable
0:06:33	a a is given by you inner product of that
0:06:36	and the and the these
0:06:38	oh i can function
0:06:41	now
0:06:42	oh
0:06:43	compute
0:06:44	a a screen play five
0:06:47	from the calculation we can see that
0:06:50	oh okay "'cause" i was to
0:06:53	uh that some model
0:06:54	a a a a and i i is the eigenvalue
0:06:58	and we know that
0:07:00	a a a that was to i can function account
0:07:03	i well as i my of error a uh variability of the random process at was able
0:07:10	so we
0:07:11	we say that
0:07:12	we a a "'cause" i have three
0:07:15	you or greater than that you buy out the
0:07:18	a a complete basis
0:07:22	and
0:07:23	then all with a a a a that can be a a a a similar if then a long uh
0:07:29	i can function
0:07:31	but
0:07:32	quite well and the distribution of property in the random i thought
0:07:37	i a i don't know all too complicated to be described as think they
0:07:42	all in close to form
0:07:44	so at to read about it
0:07:46	extremely you can go to find a
0:07:48	oh okay L expression for the random problem
0:07:53	i
0:07:54	uh
0:07:54	given a a a a a set of real i they shouldn't of of the random process
0:07:59	oh
0:08:00	and it's and i three are all normal be we can calculate
0:08:05	uh the random error
0:08:06	oh variable able for each realisation
0:08:09	and then we apply that there
0:08:11	random variable and use
0:08:13	a a of various to the them that so
0:08:17	the that the energy of the random or
0:08:20	and then the ah
0:08:22	a a a a a a hell of a a a is a random variable so are part
0:08:27	uh
0:08:27	screen a five in
0:08:29	we know that it's of ones that are then
0:08:32	a a sign which is given by a
0:08:34	oh of to more expansion
0:08:38	so we
0:08:39	for a T max
0:08:40	oh which is that um well
0:08:43	and i think the sample variance
0:08:45	are are among random variable
0:08:47	oh which is
0:08:48	involved in the model
0:08:52	now still we use the
0:08:53	i um i don't five three made to evaluate
0:08:57	the function model
0:09:00	i
0:09:00	oh the kl expansion is unavailable
0:09:04	oh
0:09:05	there are two seconds to is are and a consideration
0:09:09	oh the
0:09:10	uh the
0:09:11	representation is not offer more
0:09:14	redundant you must at this to the in the mall then
0:09:18	how do we measure the redundancy or equivalence is the H E
0:09:24	i we know that is small so in the
0:09:27	oh model uh imply that error of the representation is a there is a trade-off efficient the end and ri
0:09:36	uh
0:09:38	you can uh uh uh and six fashion
0:09:40	oh we can calculate a very is for and coefficient
0:09:45	then
0:09:46	we find that
0:09:47	only only
0:09:48	uh
0:09:51	or i coefficients are a very small which used
0:09:56	the corresponding sounds to be removed them from the model
0:10:00	that's in a large than the error
0:10:02	and i
0:10:03	so only uh and i a uh so that the model
0:10:08	and uh
0:10:11	a so uh we can you to me
0:10:14	the efficiency of the model in terms of that so
0:10:18	which are given by a and the it
0:10:23	then uh
0:10:24	that i is one is
0:10:26	oh there are many a point is all orthonormal basis
0:10:31	so will which one is a bass
0:10:34	oh
0:10:36	and uh
0:10:37	oh we know that a human
0:10:39	uh well i think that all of normal basis we can calculate a
0:10:43	oh but and all coefficients
0:10:46	and
0:10:47	a i
0:10:48	screen a a
0:10:49	i friends
0:10:51	so we compare them at all three play
0:10:55	then the lack of that bad has so um
0:10:58	the well known be up by thing a like to create a a a a is the best choice
0:11:07	okay
0:11:08	oh
0:11:09	we use the uh
0:11:11	proposed a map to be evaluate to each you yeah no
0:11:15	for the efficiency in
0:11:18	a a spatial component is there's
0:11:22	in
0:11:23	a a a there is an um
0:11:25	each each they show the spatial components it
0:11:28	a a a a a a a very low the harmonic
0:11:32	and uh a a i i the
0:11:34	coefficients still we hold
0:11:37	spherical harmonic
0:11:38	uh coefficients
0:11:39	which is a given by a
0:11:41	of the you know what are so it not yeah a and a very money
0:11:46	and uh
0:11:48	we might not be way and have to a a and is given by a
0:11:53	uh
0:11:55	uh right
0:11:56	um
0:11:57	and
0:11:58	it is a need to me by a a a a wave number of K
0:12:04	okay and not a
0:12:06	oh
0:12:08	oh of for that model we have
0:12:10	oh have they have a
0:12:12	capital and coefficient
0:12:15	then oh we can do
0:12:17	the are there the whole
0:12:19	all these there will have money
0:12:21	oh oh coefficient
0:12:23	oh we find that
0:12:25	and right oh okay efficient
0:12:28	a a a a a nine one nine then
0:12:31	of the total energy
0:12:33	so uh for me looking and
0:12:36	uh we define the H I T N as the initial efficient the a a and the whole key
0:12:44	oh i shows
0:12:46	um um
0:12:47	the uh very is all all their a harmonic
0:12:51	coefficients for the frequency and
0:12:53	for a you know that
0:12:54	and with C
0:12:56	that
0:12:57	the was the C coefficients of hand
0:13:00	oh most of the energy
0:13:03	and then uh
0:13:04	think of be shows that the speaking a at
0:13:09	okay so and and the capital and wrong
0:13:12	calculate and in these oh to try to go and O
0:13:17	a a and one the red
0:13:19	a down
0:13:21	and a problem if we should both he we can
0:13:25	uh as you can be a the of they show of component expansion is a wrong
0:13:31	seventeen then
0:13:33	and then
0:13:34	a a a a think good shows a migration
0:13:37	a model the man
0:13:38	a H I yeah the blue one
0:13:41	and then
0:13:42	a a a a a a a one in a a a a we constructed
0:13:46	each each yeah using
0:13:48	and and for a capital and to themselves
0:13:50	spherical a a harmonic
0:13:53	and that really one still
0:13:55	uh
0:13:56	the reconstructed hrtf
0:13:59	oh using and trying in terms of spherical
0:14:02	harmonic
0:14:04	that we want to different this speaking writing one and right one is
0:14:08	oh or wrong to one percent
0:14:12	i
0:14:13	oh let's say which are normal with select uh a base it is that a frequency components there is
0:14:22	a a a a a a in it is a three D uh hrtf model
0:14:28	we use
0:14:28	uh
0:14:29	spherical be L to expend the of frequency component
0:14:34	and uh
0:14:36	i
0:14:37	i is that there will be a more efficient of which is given by be formula
0:14:44	i still we have a other classes
0:14:47	that's a
0:14:47	a complex exponentials
0:14:50	oh and agenda probably and T V share on a because
0:14:54	uh are they are all you can have but it's in expanding of frequency components use or on the in
0:15:01	term
0:15:03	and uh
0:15:04	collocation can be given by
0:15:06	oh these three
0:15:08	you cliche
0:15:09	respectively
0:15:10	then
0:15:11	a here it would treat the and the
0:15:14	a property of H T of components
0:15:17	oh models using
0:15:18	these four sets of orthonormal basis
0:15:21	and
0:15:24	but that and so on i shows the screen play
0:15:29	and we can see that
0:15:31	a a a a new value
0:15:32	for for a a a a a uh
0:15:34	according to compress C spun that actually is quite close
0:15:38	to that there will be a function
0:15:40	but still we model the
0:15:42	note that
0:15:44	uh i think he said all
0:15:46	a a will be out in a sample
0:15:49	and i with and still of the total energy of we're
0:15:53	oh while uh i think in a comp simple and now shows only a have for three presents no the
0:16:01	oh
0:16:02	and G
0:16:03	so
0:16:03	with i
0:16:04	here are
0:16:06	spread will be found at most and is the passage voice C
0:16:10	it's yeah frequency expansion
0:16:14	okay
0:16:15	uh motion
0:16:16	uh and i right know we a a a a set the question
0:16:19	how to we if they really the efficiency of a and
0:16:23	oh
0:16:24	a function of hrtf model
0:16:26	and oh we use a
0:16:29	we use the some of the
0:16:31	where of random variable in in the model to uh evaluate the efficiency and the read that still
0:16:39	efficiency of the model
0:16:41	oh a spatial component expansion is around seventy percent and the
0:16:45	but what is still
0:16:47	uh a frequency component
0:16:49	pension is the spherical bessel don't function
0:16:53	thanks for attention
0:16:55	you
0:17:01	i
0:17:02	i
0:17:17	i
0:17:19	okay
0:17:23	i
0:17:24	and
0:17:30	all
0:17:32	i
0:17:34	i
0:17:34	the that
0:17:35	do that but um
0:17:37	i think it it can be
0:17:39	uh
0:17:40	for
0:17:41	the D C U and was to for all the prosody
0:17:45	oh
0:17:46	a a representation
0:17:49	mm
0:17:50	so i think it's can
0:17:52	four
0:17:54	hmmm
0:17:55	i
0:17:56	yeah
0:17:57	hmmm hmmm
0:18:00	hmmm
0:18:03	yeah
0:18:06	i
0:18:07	i

EFFICIENCY EVALUATION AND ORTHOGONAL BASIS DETERMINATION IN FUNCTIONAL HRTF MODELING

Spatial and Multichannel Signal Processing

Přednášející: Mengqiu Zhang, Autoři: Mengqiu Zhang, Rodney A. Kennedy, Thushara D. Abhayapala, Australian National University, Australia