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June, 2005
Brethour, Time DomainSlide 1
doc.: IEEE 802.15-05-0370-00-004a
Submission
Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [Ranging with Energy-Detect Receivers]
Date Submitted: [26 June, 2005]
Source: [Vern Brethour] Company [Time Domain Corp.]Address [7057 Old Madison Pike; Suite 250; Huntsville, Alabama 35806; USA]Voice:[(256) 428-6331], FAX: [(256) 922-0387], E-Mail: [[email protected]]
Re: [802.15.4a.]
Abstract: [Comments on 15-05-0336-00-004a.]
Purpose: [To promote discussion in 802.15.4a.]
Notice: This document has been prepared to assist the IEEE P802.15. It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein.
Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P802.15.
June, 2005
Brethour, Time DomainSlide 2
doc.: IEEE 802.15-05-0370-00-004a
Submission
Ranging with Energy Detect Receivers.
Comments on 15-05-0363-00-004a
June, 2005
Brethour, Time DomainSlide 3
doc.: IEEE 802.15-05-0370-00-004a
Submission
05-0363r0 shows the energy detect ranging performance hitting an error floor at 17 dB
June, 2005
Brethour, Time DomainSlide 4
doc.: IEEE 802.15-05-0370-00-004a
Submission
17 dB is a lot of S/N in a receiver that can’t do coherent integration.
• So how is the 17 dB going to be achieved if coherent integration is not available?
• Simple! By reducing the range.
June, 2005
Brethour, Time DomainSlide 5
doc.: IEEE 802.15-05-0370-00-004a
Submission
So what does the range come to if we need 17 dB of S/N at the receive end?
• It depends on the channel.
• There is no simple single answer.
• But rather than say NOTHING about the range, I will offer a simple single answer!
June, 2005
Brethour, Time DomainSlide 6
doc.: IEEE 802.15-05-0370-00-004a
Submission
The single simple estimate comes from a link budget type analysis.
• 15-05-0371-00-004a is a companion spreadsheet to this presentation.
• I will argue that for a general ballpark type estimate of performance, this link budget analysis is actually better than any one simulation.
• It is not better than 800 simulations of channels which are appropriately calibrated for the lengths we are talking about.
June, 2005
Brethour, Time DomainSlide 7
doc.: IEEE 802.15-05-0370-00-004a
Submission
05-0371r0 looks like this:
The “needed” 17 db goes in this cell
The path loss exponent goes in this cell
When our link margin crosses zero we are at the maximum link distance.
June, 2005
Brethour, Time DomainSlide 8
doc.: IEEE 802.15-05-0370-00-004a
Submission
So what does it say?
• If we need 17 dB of S/N to do our ranging, we’ve got a 2 meter link (assuming a path loss exponent of 2 for the first meter and 3.5 for the second meter).
• That’s not right: Because, with a 2 meter link, we won’t have a path loss exponent of 3.5!
June, 2005
Brethour, Time DomainSlide 9
doc.: IEEE 802.15-05-0370-00-004a
Submission
So what if the path loss exponent is 2?
• With a path loss exponent of 2, we predict a 3 meter link.
• Path loss exponent of 2 is as good as it reasonably gets.
June, 2005
Brethour, Time DomainSlide 10
doc.: IEEE 802.15-05-0370-00-004a
Submission
So we have a 3 meter link, is that Okay?
• We always said that the energy detect receiver would operate at reduced range from the coherent receiver.
• We shouldn’t be surprised, 17 dB is a lot of S/N.
June, 2005
Brethour, Time DomainSlide 11
doc.: IEEE 802.15-05-0370-00-004a
Submission
What kind of range errors are we getting on this 3 meter link?
The error floor is showing up at 2.5 ns.
June, 2005
Brethour, Time DomainSlide 12
doc.: IEEE 802.15-05-0370-00-004a
Submission
So we have a 3 meter link, is that Okay?
• We need to wonder!• We’re looking at range errors of almost a meter
on a 3 meter link.• With node densities that high, we almost don’t
need to talk about GDOP, but if we did use a GDOP factor of 4, we’d be looking at 2 meter errors on a 3 meter link.
June, 2005
Brethour, Time DomainSlide 13
doc.: IEEE 802.15-05-0370-00-004a
Submission
Okay, so the performance isn’t great.. But at least it’s a simple receiver…..
Right?
• No it’s not!
• To do the leading edge detection requires (at least) two receive channels with a controllable known time offset between them.
June, 2005
Brethour, Time DomainSlide 14
doc.: IEEE 802.15-05-0370-00-004a
Submission
2 channels…. What’s that about?
• One channel tracks the acquire point & the other does leading edge detection.
LNAReceive chain 1
Acquire and track
Controllable offset
Receive chain 2
Leading edge detection
June, 2005
Brethour, Time DomainSlide 15
doc.: IEEE 802.15-05-0370-00-004a
Submission
• No. That’s the analogue approach. With the analogue approach, samples are kept track of at the symbol rate.
• FT has talked about continuous sampling and keeping track of all the samples. That’s a digital approach with only one receive chain, but now samples must be kept track of at the tracking (envelope over-sample) granularity.
2 channels…. Is that really necessary?
June, 2005
Brethour, Time DomainSlide 16
doc.: IEEE 802.15-05-0370-00-004a
Submission
So why am I saying it’s not a “simple receiver”?
• Dangerous assertion: “Simple” is in the eye of the beholder.
• If a “simple receiver” is defined to be the simplest receiver that can do communications, then by that metric, the ranging capable receiver is not simple.
June, 2005
Brethour, Time DomainSlide 17
doc.: IEEE 802.15-05-0370-00-004a
Submission
At least we have a long (nominal 4 ms) preamble available to try to get
some processing gain. (?)
• Not really.• The 4 ms must be used to search the entire
leading edge search back zone.• The good news is that if we are only putting in
3 meter links, the search back zone is relatively small.
June, 2005
Brethour, Time DomainSlide 18
doc.: IEEE 802.15-05-0370-00-004a
Submission
Covering the search-back zone.
• Here I’m assuming that the receiver is using the analogue approach.
• For a 3 meter link, let’s assume a 24 ns search-back zone.
• Even with a 3 ns search step size, that’s 8 search offsets that must be characterized.
June, 2005
Brethour, Time DomainSlide 19
doc.: IEEE 802.15-05-0370-00-004a
Submission
Characterizing the search-back steps
• If there are 8 steps to be characterized, then the preamble is broken up into 7 segments to be covered by the search channel. Assuming that .5 ms of the 4 ms preamble was spent on acquisition and establishing tracking lock, then only 3.5 ms remain to be split 7 ways.
• Only half a ms is available for each characterization.
June, 2005
Brethour, Time DomainSlide 20
doc.: IEEE 802.15-05-0370-00-004a
Submission
Conclusion.
• The expected link distances for ranging with energy detect receivers are on the order of 3 meters.
• The expected range errors with energy detect receivers are on the order of a meter.
• If the communication only receiver is our metric for a “simple receiver” then the receiver necessary to get this ranging performance is not a simple receiver.
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