Vanu Replacing Cell Tower Equipment With PCs 202
Dwight Schwartz writes "As reported in an
article on the ScienceDaily site, researchers from
Vanu, Inc. of Cambridge, MA,
have successfully tested a system, the Vanu Software Radio(tm), that can replace a cellular tower's room full of communications hardware with a
Pentium-based computer running Linux. The system
offers the hope of making cellular technology more affordable for small, rural communities." The systems have been tested for the last several months in parts of Texas, with wider adoption planned for the near future.
Finally. (Score:3, Funny)
This should have a big impact on small towns where expensive cellular equipment isn't cost effective.
Affordability for rural people! (Score:5, Interesting)
This is excellent. I live in South Africa, and there is a massive gulf between the poor and the few rich - this will help to connect all the poor people, and especially the ones in rural areas.
What makes me the happiest of all, is that the system runs Linux, and this is great in the light of the fact that the South African government has articulated its commitment to open source software (they have indicated that they may replace several government systems with Linux boxes! so I hope that it happenes)
It just shows what a bit of ingenuity can do.
Re:Affordability for rural people! (Score:2, Funny)
Now my boss can call me even when I'm on safari...
Re:Handsets (Score:2, Insightful)
And affordable customer service...and affordable billing systems...
This is good news, but there are many other expenses involved that new cell companies have to contend with.
shed some light? (Score:3, Interesting)
Re:shed some light? (Score:5, Informative)
GSM is pretty low-bandwidth stuff (around 13kbps). Further, the line cards handle a lot of the framing and general cookery for the interconnects (whether it's a wired E1, or microwave, or whatever). So even a fairly low-end Pentium would handle a few calls. The article does say that it needs a fairly large Linux server, but an ordinary PC would work for a relatively small node. The Digitalk telephone switches we use are really just dual PII-500 machines, and they handle 120 simultaneous wired calls.
Re:shed some light? (Score:5, Interesting)
Hell, if it's cheap enough, I'll start my own wireless phone company
Re:shed some light? (Score:3, Interesting)
It would be nice to get your own celltower, but your range would be pretty limited. You'd need one for every few square miles. I wonder if there'd be anything to stop you setting up your own cell tower in a dead spot, and letting people roam to it? We hardly ever use roaming any more in the UK, since nearly everywhere is
Re:shed some light? (Score:2)
And the key "battery not included" in this problem is also that this thing is going to need some link longer-range than itself to get back to the main PTSN, otherwise you can only call other users on the same micronode and that's likely pointless because they'll all be able to hear you shout too.
So really, the main use of such a device will be to fill in small bl
Re:shed some light? (Score:2)
Now your cell is your wireless, and you can use
it with your IP telephony service. Likewise when
visitors come to your house, their calls can be
routed over IP.
Imagine everyone has picocells. Now you don't use
cell minutes, you don't pay line charges, you just
communicate at will, whenever you're in range.
Re:shed some light? (Score:4, Informative)
aceteq.com [aceteq.com] has some good repeaters, even the 1900 mhz repeaters for US GSM for less than $800. Other systems can be $3000 or more, and can cover larger areas (I've seen some that were capable of 25,000 sq ft.)
So you would have to do a running line of small repeaters to get service to an area, similar to the 802.11 repeaters we've seen here. You might be able to convert it to line-of-sight and do it that way, too.
But the short of it is, it can be done, albeit somewhat expensively.
Re:shed some light? (Score:2)
The hardware itself is not particularly expensive. Commercial cellular equipment are costly because they tend to be custom hardware with limited production runs. They are also subject to very high reliability requirements (a few hours of downtime per year), and have hardware-level redundancy. If you relax those requirements, an PC with appropriate I/O hardware (even better, additional
Re:shed some light? (Score:4, Interesting)
So, my bets are: it's replacing a bunch of routers by becoming a software-based router itself, and doesn't handle calls, but merely switches between networks based on call type. All of the other equipment in the cell will still be required. So in essence it reduces the cost, but by no means reduces a cell node to one PC with an aerial sticking out of it.
Re:shed some light? (Score:2, Informative)
The practical effect is that instead of having a (hardware) platform tha
Journalistic Ignorance (Score:2)
I'm buzzing all over (Score:2, Funny)
It's like 1998 all over again!
The original article (Score:5, Informative)
Re:The original article (Score:2, Insightful)
Seriously, we've been installing digital nodes in the UK for years now with the kind of 'new' setup that you can see in the parent's picture. The old brown stuff looks like the kit I was ripping out back in 1997 - clunky old analog cell switches. So as well as reducing the kit costs, the services are also being switched over to digital as well? In that case, the size/kit reduction is a given, and this is nothing special.
If we're talk
Re:The original article (Score:2)
Re:The original article (Score:2)
Yes, in the sort of areas that have similar population densities to Scotland's non-served cell areas (and to be fair, some parts of Scotland that get lots of tourists but still have low population density do have digital cell coverage while in the USA areas there are few areas like that...there are also places in Scotland that have digital coverage while the equivalent part of the USA has analog only, but on the whole I would say
FCC Mandate (Score:2)
Re:The original article (Score:2)
Oregon alone (96,000 sq. mi.) is bigger than the United Kingdom (94,525 sq. mi.), but has 1/15th the population.
room full of communications hardware (Score:3, Insightful)
Re:room full of communications hardware (Score:5, Insightful)
Assuming using a PC can't give redundancy and resilience against failures is extremely presumptious. But for areas that currently don't have ANY coverage, even a desktop PC powered base station would be an improvement.
Re:room full of communications hardware (Score:3, Informative)
Because according to the article (as well as the writeup for this topic), they are targeted for rural communities, wehere by definition the towers will be so far apart that service will be entirely lost for that area because there will not be another tower close enough to pick up the slack....
Re:room full of communications hardware (Score:2)
then it'll probably cost you as much as the hardware its attempting to replace. Obviously they following the better-than-nothing approach here with a cheap price but not 5 9s reliability.
Re:room full of communications hardware (Score:2)
As for reduncancy, when I worked in the telecommunications industry - not wireless, but optical long-haul - even having redundant machines in the same physical location was regarded as unsafe.
What if there is big power failure? A serious fire? A flood? A plane crash on top of the station? A meteor strike? There's resilie
Because I read the article, you half-wit (Score:2, Insightful)
From http://www.nsf.gov/od/lpa/news/03/pr03117.htm which is the OFFICIAL PRESS RELEASE.
A single desktop. Sounds incredibly stupid to me. I mean, you gotta cough up the cash for the antenna and transmission equipment, why cheap out on the hardware? Sometimes saving money doesn't make s
Re:room full of communications hardware (Score:2, Interesting)
Re:room full of communications hardware (Score:3, Informative)
Re:room full of communications hardware (Score:2)
Re:room full of communications hardware (Score:2)
Re:room full of communications hardware (Score:2)
Re:room full of communications hardware (Score:2)
They aren't going to call up Dell and say they need a system. They're going to get a system from a manufacturer that deals in enterprise-level, high-reliability, fault-tolerant computer systems.
From the article, it seems this is mainly intended for areas where it isn't isn't economically feasable to put up an expensive, conventional cell-phone tower.
This could be a serious cost saving (Score:4, Interesting)
Replacing all of that with a tower, antenna and a PC would be a huge saving, both in terms of planing, installation and maintainence. A single site could be rolled out in a matter of weeks, rather than months, and cost a fraction of what it costs now.
For us in Europe, maybe it could help reduce costs and get the debt-laden operators back on their feet. For those of you in the US, you could well see much better coverage on all networks.
All OSes are equal but some are more equal... (Score:2)
2003 will be remembered as the year that the word "Linux" became synonymous with cheap, reliable, omnipresent operations.
Re:All OSes are equal but some are more equal... (Score:2)
This story shows nothing of the sort. Its not about how linux is the 'end all, be all' operating system for every kind of hardware. Its more about how a cheap, general purpose piece of hardware (the ubiquity of which having virtually nothing to do with linux) can serve the function of a larger set of very expensive, specialized hardware.
If the group had instead ported linux to that 'closet full of communications equipment'm your poin
Re:All OSes are equal but some are more equal... (Score:2)
If you take a step back and look at the big picture, it shows exactly that.
If you build something really new (or replace something from the ground up as in this example) Linux is the way to go. There are no "switching costs" holding it back, there are no desktop apps or games needed. Open Source is the only sane choice.
I believe in Linux as much as anyone, but I don't doubt they could have done the same thing with a windows box, or an OS X box.
Wrong. The goal was
Re:All OSes are equal but some are more equal... (Score:2)
I got the impression that the goal was to find a way to replace specialized equipment that costs hundreds of thousands, if not millions of dollars, with equipment that was much cheaper.
The whole 'the provider will screw you' argument is dubious. Windows and Mac OS X boxen are commodities, so its not as if Apple or MS will be able to apply pressure to some community using store
Re:All OSes are equal but some are more equal... (Score:2)
What if your not-connected-to-the-Internet machine doesn't work because of WPA? What if it turns out that some servicepack "alters the deal" and you now need thousands of CALs?
I'm sorry that I don't have a link, but something similar happened to an airline: They wanted to
Re:All OSes are equal but some are more equal... (Score:2)
A few more places where CSS might beat OSS.
Re:All OSes are equal but some are more equal... (Score:2)
With that hardware you have no OS in a classical sense at all, you implement your apps right on
Re:All OSes are equal but some are more equal... (Score:2)
I think you are right...however that gives a free OS like Linux a few advantages. One there is no purchase cost for the OS, so your per unit costs go down (by $200 if you have to buy WinXP retail, or maybe by as little as $5 if you buy a huge number of WinCE licencess). Two you can run on a wider array of hardware then
Re:The traditional advantage... (Score:2)
GNU Radio (Score:4, Interesting)
It's cool that as computers get faster, you can have software replace hardware
Software Defined Radio (Score:2)
Re:Software Defined Radio (Score:2)
Re:and why would it be entirely different? (Score:2)
Re:GNU Radio (Score:2)
Tell that to the linux laptop folks who have WinModems.
Winmodem? (Score:2)
1) It was designed from the ground up to run on Linux. Possibly the biggest problem that 'linmodem' driver developers had was getting specs from manufacturers. Obviously that's not an issue here.
2) When winmodems first appeared in the early Pentium days, resources were scarce. Running one on a desktop system that had lots of other things needing those same resorces was a problem. Now even most low end PC
Re:GNU Radio (Score:2)
About the only advantage software defined radio has, is that it's one common piece of general-purpose hardware to do everything. You could do the same thing by having inexpensive modules hook-up to a similar hardware device. Having software doing the job only ensures that it will never be effecient or feasable.
Just think... How much would you have to pay for a very fast computer that would be able to do MPEG
Secure? (Score:4, Interesting)
Re:Secure? (Score:2)
It's software if you configure/program it. It's hardware if someone else does it.
Is a dial up modem hardware or software? Is an Intel P4 processor hardware or software?
The fewer things you can do to something, the harder it is to compromise it. But just because you don't know nearly the full range of things possible on a piece of "hardware" doesn't mean others don't, esp those who know it as "software".
Re:Oh COME ON! (Score:2)
Perhaps a new law akin to Murphy's: if one man invents it, another man will make plans to pervert it.
Re:Oh COME ON! (Score:2)
If the source code becomes publicly available, then it's not conceivable for somebody to hack a special version (that, for example, eavesdrops on certain calls, or bills certain calls to a different account), break in to a remote cellsite, and replace the running software unnoticed. Doing this today would not be impossible, but it's more difficult.
Remember, Risk = Likelihood * Damage. This new technology increased the Likelihood, a
Re:Oh COME ON! (Score:2)
Re:Oh COME ON! (Score:2)
Yes, but because it runs Linux, it's easier to hack an exploit (say, intercept certain messages heading for a billing server) in, because the hardware and development software are readily available. By "easier", I'm comparing it to a commercial RTOS running on a custom board. If the application level sources are opened, then the vulnerability grows a bit more. Finally, as these low-cost base statio
Comment removed (Score:5, Informative)
ancient stuff? (Score:5, Informative)
The unit was about two mid-tower cases of volume, had an integrated PC, integrated antennaes, the whole bunch. Everything you need for a GSM basestation. And it really is an old model. Modern models are at least more efficient (with directional tracking antennaes, etc) and more inconspicious (they can look like fake chimneys, parts of wall, etc, so that it doesn't disturb the landscape.)
Probably we're not even talking about the same things since calling a basestation unit a "tower" is ridiculous. Maybe they've replaced the switching centre with a PC? Though I doubt it, since a PC/Pentium would be severely bandlimited to handle thousands of connections. Perhaps with dedicated hardware which is merely controlled by a PC..
Re:ancient stuff? (Score:2, Informative)
Re:ancient stuff? (Score:2)
I don't see what it so revolutionary about what Venu is doing, there have been small, cheap BTSs around for many years.
Re:ancient stuff? (Score:2)
united states has roughly double the population density of finland(~30 vs ~16 per square km) for example, and practically all of lapland has cell coverage, while the population density in lapland is 2.2 and most of of the areas are under 10 per square km. so the 'rural' excuse is worthless. the telecom companies however seem
Re:ancient stuff? (Score:3, Insightful)
There is another part of the equation, however. I don't specifically know about Finland, but in many parts of Europe the wired telephone carriers were absolutely horrible. For instance, a few years ago I know some people who were interconnecting some offices in Athens. They needed to build a radio link because there was a 9 month lead time to get a cir
Re:ancient stuff? (Score:2, Insightful)
Re:ancient stuff? (Score:2)
most people live in southern finland, northern & easter finland are quite rural.
and from the look of the postings(by americans complaining cell coverage) it looks that the people who are complaining do live in population centres of some sort anyways(not so central suburbs and others with plenty of customers around), if there's population worth mentioni
Re:ancient stuff? (Score:2)
Support for Internet access is even better (Score:2, Interesting)
Take a look at openggsn [openggsn.org] which is developing an open source GPRS core network. Maybe the Vanu people could use this to also allow Internet communications for their SW basestation.
Re:Support for Internet access is even better (Score:2)
Hmmm (Score:2)
Hopefully this means good things for companies that own and operate cell towers in the US. One thing most cities here lack is decent coverage with the services you're paying for. I live in southern California which is pretty densely developed. Coverage in the inland areas can be pretty
Re:Hmmm (Score:2)
Try a land line. You know , those old fashioned phones that plug into a wall and don't require
good RF reception? Jeez , what IS this obsession with cellphones people have , they're just telephones for chrissake! If your cell had a wire coming
out the back and had to be plugged into a wall socket would it be quite so "kool" then?
Re:Hmmm (Score:2)
If you're aw
Re:Hmmm (Score:2, Informative)
oh-oh (Score:2)
Oh-oh! Cheaper than a roomful of equipment? Just wait until SCO hears they are using Linux. Then it'll be cheaper to have a roomful of equipment again.
GSM vs. CDMA: do we need those towers? (Score:3, Interesting)
At first, it seems that the solution portrayed in the article would make the deployment of GSM networks easier and cheaper. This would not only be a solution for developing countries, but also for rural areas in western countries. An illustration of this last point is readily made by comparing the GSM coverage of a densely populated country like The Netherlands [gsmworld.com] (former state provider KPN) to that of a much more sparsely populated country like the US [gsmworld.com] (AT&T wireless).
However, GSM is not the only cell-phone standard there is. Another standard which is often used in rural areas is CDMA [cdg.org]. It seems this standard features larger cells, and fewer base stations (for, of course, a less densely populated cell). Indeed, Verizon has plans to convert parts of its network to CDMA: see here [newsfactor.com].
Does anybody have altual experience with deploying CDMA networks? (obviously, given the coverage map for GSM, I don't need that experience in Holland ;)
Re:GSM vs. CDMA: do we need those towers? (Score:2)
Verizon has the best coverage in the US largely because of their use of CDMA. People who complain about coverage in the US usually have GSM providers (T-Mobile, Cingular, ATT). Verizon seems to be rock solid - not 100% coverage but decent none the less.
Re:GSM vs. CDMA: do we need those towers? (Score:2)
Re:GSM vs. CDMA: do we need those towers? (Score:3, Interesting)
Not surprisingly, the US has the most CDMA towers (and, ironically, the most GSM towers) of any nation in the world. This is largely because the countries of the EU are not counted as a single nation, but nonetheless, the US has plenty of CDMA towers in service. CDMA isn't particularly new (it's been around for years), it's just that it's getting more attention now that 3GSM is based on wideband CDMA technology (WCDMA).
We have many, many w
For who? (Score:2)
Well I hope that's not the only reason. How about just having coverage all over America for starters? And cut out the damn roaming charges.
How different (Score:2)
This is nice to hear. I'm resting a lot of my investment dollars in Linux!
Re:How different (Score:2)
Re:How different (Score:2)
Cell phone calls aren't real time either. If you stand next to someone and talk to them on a cell phone there's almost always a very perceptible delay. But by human perceptive standards, its not noticeable unless you have the contrast of no delay to look at.
A/D is the bottleneck (Score:3, Interesting)
The bottleneck is in dynamic range -- there can be a large difference between the weakest and strongest signal in an channel (80 dB is one example). To sample with enough resolution to capture that dynamic range, you need a lot of bits. But the more bits you use, the slower you have to sample; it's a tradeoff.
Until A/D converters advance quite a bit more, SDR won't fulfill promise.
Smart family (Score:3, Informative)
Re:Smart family (Score:2, Offtopic)
If you're after decent speakers at a similar price, buy KEFs.
Re:Smart family (Score:2)
But that doesn't change the fact that he's a smart guy.
You know what this means? (Score:3, Funny)
More details in the whitepaper... (Score:5, Informative)
This may work...mostly. (Score:2)
Re:This may work...mostly. (Score:2)
Re:This may work...mostly. (Score:2)
Info from Vanu, Inc. (Score:3, Informative)
- Linux version: we're using a Debian 2.4 release with the real time patches. All the signal processing code runs as an standard application level process.
- A/D and D/A: we're using an external RF front end that provides over 90 dB spurious free dynamic range. The poster who said these are big and hot was right; it's a little smaller than a PC case all by itself, with a hefty fan to dissipate the heat of the power amp. It covers 25 MHz worth of spectrum and costs a lot more than the HP server that does the signal processing.
- software features: the linux applications running on the HP server handle the complete transmit and receive chains. We go from raw digital samples on one side (exchanged with the A/D and D/A converters) to voice and data packets on the other. A separate HP server runs the Base Station Controller functions, which are the protocol logic, handover control, and similar functions.
- reliability: a huge advantage of building the GSM software on top of linux is that it's portable. Some operators want the level of reliability that comes with commercial grade servers; some want the level that comes with telco grade servers. The GSM basestation software runs on whatever they need.
It's great to see how much interest there is in the slashdot community about this.
-john chapin
But can it work on 2.4GHz...? (Score:4, Interesting)
In reality, we'd probably NOT have personal GSM routers as I mentioned above... instead, we'd have community organizations sponsoring local sites, paid for and maintained by their users. Interconnected with other communities, it would form a massive network of telecom co-ops. If linked by microwave, you might not even need to involve your local utilities one bit.
I'm not suggesting that we dismantle the existing mobile networks; however, they are truly OUR airwaves. If we could see to it that a mobile network running on hardware like this were to be built using non- or minimally-licensed (community licensed?) bandwidth, a couple of years of network instability and growth could build a true grass-roots, free-as-in-speech-AND-beer telecom network.
Who's with me?
Re:But can it work on 2.4GHz...? (Score:2)
New Verizon commercial (Score:2)
Vanu Sovereignty has new technology? (Score:2)
Or at least that I get a chance to try this new stuff out myself.
(whaddayaknow, the sad thing is that nobody will get this reference)
Aha! (Score:2)
So that's why my phone keeps trying to dial 0.99834664850!
There's a downside (Score:2)
The form factor for the PC case is 600 meters tall.
Vanu! (Score:2)
It's been done, although usually with DSPs (Score:3, Informative)
It's neat that Vanu is doing this on Linux, but it's not like it's a revolutionary technology breakthrough.
There's still an analog RF radio involved; all the digital processing is at the IF frequency. Digital signal processing of raw RF in the gigahertz range is still a bit out of reach. (And it will require an A/D with huge dynamic range.)
It's not clear that it's a win to do this using commodity PC hardware. Most of the crunching is in tight signal-processing loops that don't use much memory. With custom boards, you can have more CPUs on a board. Squeezing the physical size down matters in this application. If you can put the gear in a box on the pole, instead of needing a little shed, that's a big win. PCs also tend to use more power, and thus generate more heat, than DSPs per MIPS. Cooling all the gear is a constant headache in the cellular business. It typically doubles the power consumption, and the air conditioners themselves are maintenance headaches. What the industry wants is gear that doesn't require air conditioning, at least for smaller sites. Qualicomm [qualcomm.com] has been shipping pole-mounted CDMA base stations since 1997.
It's also not clear that introducing a network between the radios and the processors helps reliability. If the radios are flexible enough that one can take over the job of another, it's easier to fail out a radio/processor pair and switch in another one.
None of this matters all that much because the cellular base station equipment industry is in the tank. The industry overexpanded based on forecasts of huge needs for 3G gear, and that didn't happen.
Re:What about the big companies? (Score:3, Insightful)
They don't have to "accept" it. It will be there if they accept it or not. They just need to understand that if they don't adapt to it, regardless of whether or not they "accept" it, it will flatten them.
This is just the tip of the iceberg. Improvements in the software could add support for USTDMA, iDEN, CDMA, and maybe even AMPS/TACS (analogue) phones, making the specific phone architecture irrelevant, and ending the existing format war.
An additional benefit is this: If service is made available to