Ask Dr. Ramsey Faragher About Navigation/Positioning Technology 104
Dr. Ramsey Faragher graduated from the University of Cambridge in 2004 with a first-class degree in Experimental and Theoretical Physics. He then completed a PhD in 2007 at Cambridge in Opportunistic Radio Positioning under the direction of Dr. Peter Duffett-Smith, a world expert in this field. He is now a Principal Scientist at the BAE Systems Advanced Technology Centre specializing in positioning, navigation, sensor fusion and remote sensing technologies in the land, air, sea and space domains. We recently covered his NAVSOP project, an advanced positioning system that exploits existing transmissions such as Wi-Fi, TV, radio and mobile phone signals, to calculate the user’s location to within a few meters. Dr. Faragher has graciously agreed to answer any questions you may have about NAVSOP, the future of GPS, or what a theoretical physicist puts on his business card. Ask as many questions as you like, but please confine your questions to one per post.
Faragher's Slashdot Post on How NAVSOP Works (Score:5, Insightful)
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It's a good and legitimate question for people who venture away from cities and urban centers to locations which have no radio or cell phone coverage. Those are areas that I frequent and I asked the question to understand HOW close you would have to be to a electronic signal to receive a location from this method, i.e. how sensitive of a device can be made with this method.
Most Surprising Correction? (Score:5, Interesting)
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For myself, I think the most surprising was needing to pay attention to the number of significant bits in the mantissa of real and double precision numbers used in the calculation
Indoor Positioning System (Score:4, Interesting)
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Let me add why this an important the next step in indoor robotics. The Roomba and similar robots and toys have avoided this problem by operating blindly, or by using limited aids such as virtual walls or markers. But these parlor tricks aren't good for long-term intelligent indoor robots. They need to not just avoid obstacles, but also find the refrigerator, skip vacuuming the garage, and know to use different cleaning fluids on the kitchen ceramic tile -vs- the dining room hardwood. They should stay aw
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Damn.. wish I had mod points.. would really like to see this one answered!
In-Building and Underground GPS (Score:5, Interesting)
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Aren't people working on indoor GPS via triangulation of wifi points, mobile points, etc? I thought I read up on something about that the other day similar to http://www.gadgetbox.msnbc.msn.com/technology/gadgetbox/get-ready-indoor-gps-tracks-your-every-step-735448 [msn.com] . Not sure if that's an alternate to your question or not.
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This approach is nifty, but is too limited for general purpose robotics use. It isn't accurate. It requires multiple wifi hotspots. It doesn't let you move your wifi routers or change them out - even a firmware update the changes the power output or the channel (which some routers do automatically) might break it. It requires training.
people don't lie on your planet? (Score:2)
Privacy (Score:5, Interesting)
It would seem that to use this technology, the client would need to have a much larger datastore than with GPS: Whereas only the positions of the GPS satellites need to be known to make a calculation, the dataset here is in the many thousands to millions. In addition to the data required for map storage, it would seem any implimentation of this would require an internet connection to download the data in a geographically-restricted fashion. This opens the door to privacy issues that standalone GPS clients do not have.
How do you plan on addressing the privacy issue with your product?
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Sure, maps are big, but all the data needed to get raw coordinates is quite small. But with this system, you need a database of all your new "reference points" - cell towers, wifi, etc.
What's worse, thi
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His question is more on the map being required to locate it's self, your comment is about maps which you can show your self on after you know where you are. They are completely different sets of "maps".
Precise Positioning in Deep Space? (Score:5, Interesting)
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For those objects for which high precision is required - there is. For those objects for which it's not - there isn't. There's surprisingly few of the former, and many, many, of the latter.
The ultimate problem however is that the input data is (relative to what we're used to for terrestrial applications) generally of fairly poor quality. Thus you need either a
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Untapped resources (Score:1)
With the improvement, both in time and coverage, that using WiFi and cell tower triangulation adds to straight GPS or A-GPS, and with NAVSOP going even further, what signals (or aspects thereof), in the EM spectrum or otherwise, remain untapped? What's the next step in improving time, coverage, energy efficiency, affordability of location systems?
Automation? (Score:4, Insightful)
your best guess on the GPS successor? (Score:5, Insightful)
What is your best estimate as to what is the US DOD's current GPS backup system?
IIRC Obama cut the budget for LORAN around 2010 and till then the system was financed with the explicit explanation and purpose - GPS backup. But no more...
I am currently teaching ECDIS systems to mariners and I always emphasize the weaknesses of GPS under jamming. Ever since Selective Availability has been switched off, the jamming topic pops up more and more as a soft spot of the whole process, so I think we are not fooling ourselves that the US would let down such a gaping hole in its systems uncovered...
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Because civilian aircraft and many other mission-critical functions depend on selective availability not being enabled, it's highly unlikely they'd use it domestically.
The other argument against SA is that there are severalmethods of interpolating the GPS signals to achieve a lock that don't require decoding anything but the almanac. So mucking up the signal intentionally doesn't have to affect equipment, as long as it is designed to use the more sophisticated methods of acquiring a lock. So if you're a te
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It never hurts to show the higher-ups that you're worth a few more 0's a year.
Post Processing (Score:3)
Regulatory approval? (Score:4, Informative)
Spoofing Use as a Counter Weapon (Score:1)
Global positioning signals are used to help target various weapon systems in the United States arsenal. These signals can be--and have been--spoofed, to mis-direct these devices. Do you see spoofing technology as a meaningful threat to our offensive and defensive capabilities?
How accurate could GPS get? (Score:1)
How accurate could GPS get? Will it be possible to make GPS accurate down to submeter levels? Could we one day get GPS accurate to within centimeters or better?
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Gravitational field strength (Score:2)
Does the gravitational field strength could be used also for NAVSOP ?
Maybe slight natural variations, and buildings, underground structures like metro, subways, large sewers can be sensed by gravitational sensors, at least the new ones with atom waves interference...
Dr. Faragher (Score:4, Funny)
Can you please tell me the whereabouts of Carmen San Diego and/or Waldo?
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An external antenna on top of your car.
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There's nothing wrong with GPS coverage, your receiver has a problem. It may require a firmware update or an external antenna.
Frequencies (Score:1)
Are there other frequencies of EM radiation that would be better suited for navigation than the gigahertz used now?
Map Projection (Score:1)
What is your favorite map projection? (Geeks like to know these things)
Interoperability (Score:2)
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Cambridgeshire pub preferences (Score:2)
Sensor fusion (accelerometer etc.) (Score:2, Insightful)
What potential do you see in the combination of these "opportunity" signals (Wifi etc.) that are to be used in NAVSOP and data from sensors like an air-pressure sensor, accelerometers etc.?
Introductory materials about navigation? (Score:2)
We all know how GPS works, and even the basics of the math behind it, but where does one find more in-depth mateirals? Like if one were to create a GPS receiver, how to translate those signals into something useful? Not just dumping the equations out and say "solve this" but working step by step through a solution and then adding in corrections like relativity?
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Using GPS technologies for encryption (Score:2)
So, since the GPS satellites and other systems are enmeshing the world in streams of digital data, can a portion of the data stream be used to transmit some sort of key so that it can be proven the receiver was at a specific space-time coordinate?
Like if satellite A was transmitting a continuously varying stream of random numbers and satellite B was doing the same then a receiver could take the product of the "random" numbers that it captured over a short window of time and use it to encrypt and "space-time
Sensor fusion (Score:3)
In order to combine all the sources of information, are you relying on a messy approach, something based on many signature machine learning algorithms (think boosting, SVNs, random forests etc) or are you writing an explicit generative model for the noise and then applying filtering to it, with a particle filter for instance?
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erratum:
In order to combine all the sources of information, are you relying on a messy approach, something based on some classic machine learning algorithms (think boosting, SVNs, random forests etc) or are you writing an explicit generative model for the (trajectory, sensor output) and then apply filtering to it?
Quantum entanglement to improve accuracy (Score:2)
So I've heard that a problem with the GPS and presumably other systems is that the radio signals are slowed by varying amounts by going through the ionosphere (thus reducing accuracy). I realize that you cannot use quantum entanglement to send (new?) information but does that include the information that a measurement has been made (if not the result)?
So could GPS use entanglement to precisely determine the time of a measurement? I think it's been demonstrated that they can send an entangled photon hundre
spoofing (Score:2)
Following the downing of an American drone in Iran the hypothesis was put forward that the Iranians spoofed the GPS signal and convinced the drone that it wasn't where it thought it was in order to get it to land in Iran (I'm not sure if this was ever confirmed). A recent issue of Aviation Week reported on a group I believe in the U.S. working on the same idea, spoofing the GPS signal in a transparent manner to convince an autonomous vehicle that is was somewhere other than its actual location. Would NAVSOP
Galactic GPS using pulsars (Score:2)
So I seem to remember a proposal to use pulsars to provide a sort of galactic GPS. (Pulsars, spinning neutron stars, are extremely stable periodic emitters of radio waves at interstellar distances). I think this might be what an earlier poster was referring to for spacecraft navigation, I believe they were used on the famous Pioneer 10 plaque (with the naked humans) to show aliens where we live.
Anyway, what's the accuracy for this (the previous poster mentions several hundred meters over hundreds of kilom
Calibration (Score:2)
I have been to various benchmarks and have been able enter the correct altitude and it remains stable for a very shot time but am unable to correct for lat/lon differences.
Accessing DBs of transmitter locatiosn (Score:2)
Dr. Ramsey,
In your post [slashdot.org] on Monday, you said:
A lot of the "this is not new" comments refer to differential positioning using reference receivers and having access to databases of transmitter locations (Rosum, the old Cursor positioning system from Cambridge Positioning Systems, etc). We consider those aspects to be undesirable constraints on a flexible opportunistic positioning system and don't rely on them.
Is the idea to be a fully self contained (and self teaching) system? Is there any way to (reliably) share transmitter location data between clients using some sort of P2P or swarm connection?
Compass and radar (Score:2)
Could your technology be augmented to enable bistatic radar apps for our mobile phones?
Have you considered doing the same using earths magnetic field rather than RF? Local varience within buildings or geology, earth field lines or using a RLG/GPS reference to see parallax in declination as a basis for rough positioning?
Handling Trust (Score:2)
How do you see trust being handled in these systems? It would seem to beat the core of everything - anti-spoofing, error detection and correction, and possibly authorized receivers.
Multiple receivers for increased accuracy (Score:2)
I am envisioning something that uses 4 or 5 receives arranged in either a triangle or square with one receiver located in the center of the others. The distance between any 2 of the receivers would be at most slightly more than 1 meter which is below the accuracy
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We can assume that if you measure GPS coordinates at a given time and location, you will have a systematic error (inaccuracy in satellite position, different speed of radio signal due to weather) that is the same for all GPS receivers in an area, plus a random error different from GPS to GPS. Taking lots of measurements would tend to cancel out the random errors and leave you with the systematic error.
With differential GPS, you p
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Computers using Traditional Navigation? (Score:4, Interesting)
I found it striking that in the case of the drone that was forced down in Iran (e.g.) the 'return to base' failsafe seemed to be completely dependent on electronic signals.
It would seem much harder to spoof the position of the sun, the Earth's magnetic field, the position of the stars, etc. I presume, perhaps naively, that the sensors and algorithms to do this wouldn't be all that expensive or complex. What's the challenge in getting computers to use traditional navigation techniques?
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There isn't a challenge - it's a well trodden path. The problem is that for the most part the sensors required are much more expensive than a GPS receiver, moderately complex, and require significant calibration and maintenance.
Pigeon Racing (Score:1)
How does it feel? (Score:1)
So how does it feel to have played a pivotal role in finding particles that travel faster than light?
Solar Events? (Score:2)
How will the system function during/after a major solar event? Assuming a worst case scenario, satellites in orbit could be disabled for good. And depending on the severity, transmitters on earth may be affected as well.
Your thoughts?
Really? (Score:2)
in the land, air, sea and space domains
That pretty much covers everything, no?
Best local navigation system (100mx100m)? (Score:2)
I'd like to fly drones over a, say, 100x100 meter area with centimeter precision, possibly indoors, for filmmaking. GPS is clearly not going to work, even outdoors. Time Domain sells a system with 5 cm resolution, using UWB technology [timedomain.com] -- but is there anything better than that?
Bayesian tricks (Score:2)
Do you use Bayesian inference to combine positional information from many sources, some of which might be sorrily mistaken? I'd be interested in hearing more about the algorithms used to stitch this data together, and if there are any heuristics or approximations that help.
On the fly mapping with environmental data (Score:2)
You mentioned earlier the domination of signal strength when indoors. Can you also use patterns in observed environmental data for automated mapping and exploration?
For example a robot exploring a cave or a large indoor structure like a power plant might be able to even use information such as ambient temperature / humidity, echoic nature of surroundings, or patterns in ambient air pressure / acoustic input from machinery or the sound of treads against floor.
Also someone was skeptical about using stars to n
GPS cost not coming down (Score:2)
We bought our first GPS receiver in 1992 for $1500. Today we have GPS receivers for pennies in your cell phone with better accuracy. Why have costs not come down on higher end systems? Patents? Lack of Competition? For instance, in agriculture you buy a 1500$ receiver and the vendor sells you different levels of $2000 software unlock codes to go from 8" to 4" to 2" to 1.5" to 1" accuracy. Are they selling the receivers initially at a loss?
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