Přepis řeči - ON AUTOCORRELATION-BASED MULTIANTENNA SPECTRUM SENSING FOR COGNITIVE RADIOS IN UNKNOWN NOISE

0:00:13	uh
0:00:15	i'm more talk about the use simple uh
0:00:18	multi antenna spectrum set
0:00:20	using the uh
0:00:22	data autocorrelation correlation function
0:00:25	and the uh
0:00:26	uh
0:00:27	so is the multiple antennas the noise variance at each antenna
0:00:32	uh that's the general model
0:00:38	i'm not gonna assume that the uh signal bargains uh gaussian possibly non gaussian
0:00:44	uh noise is assumed to be
0:00:49	first part of my talk at a time
0:00:51	extent
0:00:53	correlated gaussian noise
0:00:55	very complex
0:00:56	this proper
0:00:58	uh
0:01:00	the
0:01:01	nice very a different sensors can uh a lot to deaf
0:01:06	uh this problem has been what on by one bunch of people in different
0:01:12	forms
0:01:14	a
0:01:18	this paper here uh because of the need
0:01:22	title of paper or happening would buy
0:01:25	people including me
0:01:27	uh
0:01:28	so
0:01:28	this assume
0:01:30	the basic some so there is there on and as the title delay indicates is unclear good
0:01:35	so
0:01:35	the so each
0:01:37	sense can have different nice variance
0:01:40	and they use a generalized likelihood ratio approach
0:01:43	uh the basic assumption that is a a a a a a in addition to white gaussian noise the signal
0:01:47	itself is a gaussian as well as what
0:01:50	so we need i on the
0:01:52	like to a show all time samples are independent easy to write
0:01:56	like you you sure than a like to lies like to
0:01:58	sure
0:02:01	the next set of these two set of papers
0:02:05	they have a similar stuff but these two papers this you equal variances
0:02:09	and they also have to noise like to the sure approach
0:02:12	and again this assumed that the signal is by "'cause" you
0:02:15	and then the this paper has a a nice or are all the stuff available at that one extension
0:02:22	what i wanna do it i don't one assume that the signal is gaussian so i don't to be using
0:02:27	lies like to visual approach
0:02:29	i just go and straight and use the autocorrelation function
0:02:32	and the basic assumption be are using here is
0:02:35	that D
0:02:36	noise is spatially uncorrelated
0:02:39	so the cross-correlation correlation those signals
0:02:41	of the observation across different senses
0:02:44	is zero under the null hypothesis
0:02:46	could be non-zero under the uh
0:02:48	that's all
0:02:50	but they also out that up a go to all my stuff
0:02:54	my final result days
0:02:57	you put there result
0:02:59	a they have a to less like a short test which under low and my social conditions
0:03:04	the has an approximation which is exactly what i
0:03:07	in the case of like it's
0:03:12	okay so okay said think got thing about the the that like like a best is
0:03:16	that asymptotically you can use the will to room the related stuff
0:03:22	and you can you can
0:03:23	asymptotically the the most should will have a chi-square distribution
0:03:29	and the null hypothesis
0:03:31	a a central chi-square distribution
0:03:33	bear a i have be sensor so the the degrees of freedom is actually the number of unknown parameters under
0:03:38	H one
0:03:39	or of five parts
0:03:41	minus the number of one on put on this and of the not
0:03:45	do that
0:03:45	you get a
0:03:47	so asymptotically you have to do
0:03:49	oh the distribution and you can calculate the touch
0:03:52	knife i go back uh
0:03:55	do these two papers here
0:03:57	they exploit the fact
0:04:01	uh a that that the single signal with the one selected one
0:04:05	autocorrelation correlation function
0:04:07	under that the the uh in the absence of noise and of the alternative
0:04:12	the the with them is
0:04:13	that
0:04:14	they can they
0:04:15	compute the threshold
0:04:17	for
0:04:18	or
0:04:19	reasonable data a like using simple
0:04:22	okay there's no analytical way to compute that the threshold
0:04:25	they use this approximation but sort in their "'cause" this approximation is valid for very long
0:04:30	you have a we we have a like of
0:04:33	and the got or the probability of detection again that there's is a
0:04:36	bunch of results asymptotically it becomes a the chi-square just noncentral chi-square distribution
0:04:42	uh with the same because of it except the non-centrality parameter is a functional or
0:04:47	first them information matrix and
0:04:49	this
0:04:52	in my is they come what very simply there in in a very simple fashion
0:04:55	okay so what are gonna do is but simply take the uh uh estimate the uh
0:05:00	correlation function i i'm when you gonna use the correlation function of the data i zero like
0:05:06	but this is the new stuff
0:05:08	so the idea is the i and
0:05:10	the
0:05:11	idea a component of this so this is the
0:05:14	i you
0:05:14	sensor
0:05:15	and the G sensor cost correlated
0:05:18	so if
0:05:19	on that the null hypothesis X to a white complex gaussian i then turns out that the you like
0:05:26	the idea of component of that is complex gaussian asymptotically a zero game
0:05:31	a member the
0:05:32	noise is
0:05:33	uncorrelated spatial
0:05:35	okay so we now is not equal to J
0:05:37	it a zero mean
0:05:38	and the
0:05:39	uh
0:05:40	the variance of that the square of in here
0:05:43	this variance is this is the the noise variance under the
0:05:47	that for ten so this is the noise waiting for the G sense
0:05:51	okay
0:05:51	and they are assumed to be unknown so
0:05:53	uh
0:05:55	and plus if you
0:05:57	the this is a a B Y be me X P of the number of sensors
0:06:00	so the off diagonal terms either the log or triangle or or the low triangle
0:06:06	they are mutually in yeah asymptotically the be usually
0:06:13	okay so we don't that problem in two of the spectrum sensing whether there is a signal present or not
0:06:18	present
0:06:19	in two
0:06:20	oh this hypothesis testing problem so the
0:06:24	correlation function between in the uh the uh i in the j-th sensor
0:06:28	i
0:06:28	system i is spatially uncorrelated
0:06:31	they should be you don't is not a college check
0:06:34	no primary signal if the by me signal
0:06:36	this could be not
0:06:37	okay not it's not identically zero for i not jet
0:06:41	so we we use the large sample of correlation properties and B
0:06:45	consider this to the test statistic and how the statistic
0:06:50	these are the estimates
0:06:51	and if you yeah and and B do place the unknown is if we go back
0:06:55	i need this variance of be a list them by the estimate
0:06:59	and be it
0:07:02	okay and
0:07:03	compare is against trash
0:07:05	and as i mentioned it before if you go back to the national render rinse approach
0:07:10	are less like an sure approach and of the white a signal and white noise white gaussian signal in white
0:07:15	noise
0:07:16	under the low snr conditions it don't suck be pretty it's
0:07:19	see
0:07:23	but
0:07:23	so we want to you want to uh pick the special so for a given problem false alarm so we
0:07:28	look at lots of properties
0:07:30	and if you have a the true values here
0:07:33	then if we look at a single P i G I not equal G it's a
0:07:38	uh
0:07:38	chi-square distribution with two degrees of freedom
0:07:42	okay because asymptotically that's complex it
0:07:45	and it a some overall all to also so gonna a placed this by the estimated value
0:07:50	so kiss to i'm and all that stuff it's still is
0:07:53	asymptotically chi-squared distribution
0:07:55	we two do
0:07:56	but might that statistic is something and over all uh uh
0:08:00	possible page
0:08:03	non back not pairs
0:08:05	so if you do that
0:08:08	then it it becomes uh might that statistic i'm gonna be using
0:08:12	is to
0:08:14	chi-square distribution
0:08:15	but these many degrees of freedom
0:08:17	okay i'm using all
0:08:19	uh
0:08:21	payers money pace
0:08:23	and this is what you would got a you would have got a if you use the uh
0:08:27	like
0:08:28	uh
0:08:29	signal
0:08:30	some signal and use the
0:08:32	uh
0:08:32	we
0:08:34	i didn't have to use
0:08:35	but it's it's got
0:08:38	okay no we wanna to the detection probability
0:08:41	so a detection probability uh turns are
0:08:44	a we will use the the a low to do to my social calculations but uh under
0:08:49	alternative hypothesis and it doesn't have white signal but you have an expression for the
0:08:55	a correlation function something like this
0:08:57	and we make it big that a lot of it are basically take all the rooms
0:09:02	uh a square minus speech rooms
0:09:04	a a out of
0:09:05	or were to don't sort of this make a big but out of it
0:09:08	and asymptotically also this is uh gaussian
0:09:11	but
0:09:13	a a a bit uh this meeting
0:09:15	okay
0:09:16	and this mean is
0:09:18	the contribution of the mean is coming from the uh by means
0:09:22	but asymptotically it's not calm
0:09:25	okay it
0:09:26	it's not a it's a
0:09:28	but
0:09:29	it's not a problem or it's not a circular lisa
0:09:32	okay so the the real part is not going to put a
0:09:35	team at all
0:09:36	compliment a which does not sit however
0:09:39	if i and low snr condition
0:09:42	then it's approximately complex not seem so that's what i
0:09:46	basically the of the low snr conditions the or the only is
0:09:51	in
0:09:51	the mean becomes not
0:09:53	okay the variance doesn't T
0:09:56	so
0:09:56	if you use that that it's uh
0:09:58	complex gaussian and based on that you go back to the same test to just
0:10:04	and for large sample length
0:10:06	the test at this will become noncentral chi-square uh distribution
0:10:11	with non-centrality parameter a that which is given by this
0:10:14	but if use
0:10:16	this is a general expression but if for use uh a low snr assumption
0:10:20	then it becomes something like this it you if simplified
0:10:24	uh
0:10:25	what all the stuff and there is
0:10:27	so simple
0:10:28	so
0:10:28	i'm using the same expression except that
0:10:31	these
0:10:32	a a correlation functions are now with the primary signal press
0:10:36	okay so
0:10:37	do this that and use the nice variances as but he by have the effect of the pie
0:10:41	okay okay and eyes
0:10:43	not it to J this is not
0:10:46	and so now it's test the comes and of the
0:10:50	uh alternative hypothesis in the presence of the primary user signal
0:10:55	asymptotically is a noncentral chi-square distribution the same degrees of it
0:10:59	so
0:11:00	okay you you would have gotten a similar result
0:11:03	if you are assume that it was white gaussian signal white gaussian noise
0:11:07	and use the fixed
0:11:11	"'kay" is also you simulation sample
0:11:15	you of and and it's
0:11:16	and i'm many this although the results of that valid for the general channel
0:11:19	so mate
0:11:20	flat fading channel with independent components complex gaussian to basically each
0:11:25	uh uh a component is really fit
0:11:28	and i using a qpsk a to use a signal
0:11:32	and the nice variances
0:11:34	are multi pulse of some fixed variance to this good
0:11:38	is not null
0:11:39	significance to this
0:11:42	and i need an snr some sort of calculating this in my my they should each
0:11:46	and uh i'm just gonna take an average snr
0:11:49	so the at a signal power some the power signal power or or or or right hand as divide by
0:11:54	some of the noise power
0:11:57	i all the score an average S
0:12:02	and i compared with than and it with the standard energy detector
0:12:06	and this is the uh what what i call the uh time domain like to should test
0:12:11	oh these are the the uh what original paper so mentioned it people back to
0:12:19	i'm
0:12:20	these two papers are pretty much the same
0:12:22	okay so i'm comparing these to not
0:12:26	this paper that is that the same
0:12:29	okay i i under the condition that i
0:12:31	use
0:12:33	because
0:12:34	okay
0:12:35	these guys don't allow the noise variance to be different that
0:12:39	they are have this to say
0:12:40	it's a
0:12:41	and they compute the eigenvalues of a correlation
0:12:46	and you this is the largest eigenvalue of that that this is the so
0:12:50	some of
0:12:51	all the i i use a compare is a special
0:12:54	and again what this one
0:12:56	and it to detect there as well as for this uh glrt
0:12:59	the special has to be computed
0:13:02	so
0:13:03	a simple results
0:13:05	this
0:13:08	and and that's what i showing here the the
0:13:11	oh
0:13:12	this you were operating characteristic for one hundred and twenty eight
0:13:16	uh samples
0:13:17	minus seven every say
0:13:20	some of all set
0:13:21	signal power across all sense
0:13:24	some of my is of all sensor
0:13:26	this is
0:13:27	more
0:13:27	uh this is the
0:13:29	the glrt assuming
0:13:31	equal will so
0:13:33	at all sensors
0:13:34	this is the energy detector and this is the
0:13:37	are correlation function
0:13:40	and this is the uh uh a same set except i'm changing my S and not
0:13:44	one a probability of false alarm one zero one
0:13:47	and this is the
0:13:48	proposed stuff
0:13:50	and this is the energy detector this is the glrt
0:13:54	this the energy detector for
0:13:56	if if you're threshold is based upon the noise variances are simulations but if it all white to you also
0:14:03	it's sensitive to the selection of the touch it sensitive to
0:14:07	the pressure selection is based upon your knowledge of the mice variance if it noise one
0:14:11	all
0:14:12	it can the form is good
0:14:16	and this these are the is that for the uh okay
0:14:19	the for these two
0:14:20	well i it's
0:14:21	the uh i i really fading
0:14:24	but for my probability of detection calculation uh that's based on
0:14:29	fix
0:14:29	channel
0:14:30	okay so these results are for the fixed channel it's say
0:14:34	noncentral chi-square distribution so that's what i
0:14:37	so in here
0:14:38	so here i fixed the channel the magnitude at a channel did you want the face can change
0:14:44	and the solid curve is the simulation result and the task is
0:14:48	vertical stuff
0:14:50	and this is for her twenty eight at
0:14:52	oh probably due false so what you're one
0:14:54	and same noise mismatch the the four sensors
0:14:59	and this is for twenty five set
0:15:02	okay so the everything is based on
0:15:04	and samples is and this is the solid
0:15:07	simulations
0:15:08	the dashed
0:15:09	the is the uh
0:15:11	uh you
0:15:12	so that's pretty much what i have in my paper
0:15:16	so you have some more time
0:15:18	yeah okay so
0:15:20	a a i would show you what happens you can extend this is not a
0:15:23	conference paper
0:15:25	so no i'm but a lot of the nice to be close so
0:15:28	basically what you using is a nice is spatially uncorrelated cross
0:15:33	but
0:15:34	i'm wise
0:15:35	it can go like so that's what it is
0:15:37	and i is the same
0:15:39	okay so the a than than other losses
0:15:42	the correlation function of zero lag
0:15:44	a a i not equal to G zero five not equal to J
0:15:47	it's not at C
0:15:49	so what what happens is that a nice way is not G
0:15:53	a
0:15:54	the under tree
0:15:55	no hypothesis
0:15:57	if you estimate this bad
0:15:59	it's nice to is in my previous stuff
0:16:02	what i is entered to for it is white gaussian eyes
0:16:04	this is nonzero zero and meet weird is it but if it is
0:16:08	colour nice
0:16:09	then a a nice it is it's high and it also depends upon the
0:16:14	the the uh
0:16:15	correlation structure of the nice it it's
0:16:18	so i i i this is i it sense structure this is a G S the structure
0:16:22	this is a lack
0:16:23	okay so i have something it'll or
0:16:26	oh different lacks had my capital and this is is is the upper model on the
0:16:31	correlation
0:16:32	okay i'm assuming that
0:16:33	you on "'em" it goes to zero and the rest of the stuff is exactly what i do for we
0:16:38	we modification we is this
0:16:40	okay
0:16:40	and again X it is the chi-square distribution with the same number of degrees of freedom
0:16:45	and if you do that it looks very fine
0:16:47	okay this is
0:16:48	was stuff
0:16:49	the energy detector
0:16:51	and this is the energy detector a the uh
0:16:53	nice estimate mismatch
0:16:55	and if we
0:16:56	this is not this is this is this design for a probability of false one shoe
0:17:00	however
0:17:01	if we if you assume much white nice to apply the generalized likelihood ratio test
0:17:06	but white
0:17:07	uh a noise and white signal then the probably the false let me gonna get is
0:17:11	much high point one the
0:17:14	so that
0:17:15	to basically goes best are not in me in two
0:17:18	the correlation structure
0:17:20	it is but modifying it
0:17:22	this place
0:17:24	that's all
0:17:28	we have a couple of minutes for
0:17:30	question
0:17:31	from the speech
0:17:32	is there in question
0:17:36	yeah
0:17:44	yeah a i'm not i'm not i'm gonna i'm not using the approach
0:17:47	it get it may have it be correlated
0:17:49	it it as a matter now have trying to simulations zone
0:17:53	because
0:17:54	at your like
0:17:55	it has to be non sit at different uh the lexus
0:17:57	yeah
0:17:58	like i it is so
0:18:00	i i no i'm not exploit
0:18:07	a a have just not short one uh a said that
0:18:10	your paper and your
0:18:11	technique is improving the spec to existing literature
0:18:15	uh taken into account
0:18:16	the possibility of different
0:18:18	uh but as for the noise on each sensor
0:18:22	so uh
0:18:24	is it
0:18:25	um
0:18:25	can you give some example were in practice we could have
0:18:29	different sensors with different noise uh
0:18:32	at the receiver side i mean i you
0:18:34	assuming that
0:18:35	each each each one of your sense of could have be different from the other one
0:18:39	yeah are are be the calibration could
0:18:41	goal for with time
0:18:45	that's it that
0:18:46	but
0:18:47	okay
0:18:48	so uh uh
0:18:50	and and a question we have still one
0:18:51	one mean
0:18:53	if we want to
0:18:54	supplied
0:18:57	yeah
0:19:03	no
0:19:04	there on
0:19:06	yeah
0:19:10	okay
0:19:11	as i T
0:19:13	the speaker

ON AUTOCORRELATION-BASED MULTIANTENNA SPECTRUM SENSING FOR COGNITIVE RADIOS IN UNKNOWN NOISE

Spectrum Sensing for Cognitive Radio

Přednášející: Jitendra Tugnait, Autoři: Jitendra Tugnait, Auburn University, United States