No reason why should not be solar powered. Around here all the parking meters are solar powered, just for cost of installation reasons. Wiring electricity in to 50bn devices would be a pain, unless they are electric anyway.
Just curious, wouldn't a place that needs parking meters already be on the grid? Assuming we use parking meters to earn back the costs of building the parking lot or to stimulate the use of other forms of transportation than a car in that area.
On the other hand, having autonomous off-the-grid parking meters might be easier to install and maintain by a third party. Plus it allows you to start growing parking meters everywhere, even in the middle of nowhere. Let them pay!
The ones I've seen have been installed as higher tech replacements for traditional mechanical parking meters. Solar power means the old meter head can just be removed from the pole and the new one attached, with no need to worry about running underground electric service where none was before. I'm sure the savings in installation cost more than makes up for the addition of the solar panel.
I've seen solar powered road photoradars, and road lights on some crossings between cities. Solar cells are on 2-3 meter pole, at +- 45 degree, and have sth like 0.5 square meter surface, and big box the size of car battery under the solar cell.
I guess it's more cost effective than draw the wires a few kilometers from the city.
Ultracapacitors are great and all that but they can discharge incredibly quickly causing all sorts of problems (fires, explosions, dead equipment etc). These are several orders of magnitude more likely than LiPoly cells to do it as well. They are much more suceptible to damage too which can cause internal shorts.
An analogy: a traditional LiPoly cell is like a twisted rubber band waiting to unwind. An ultracap is like an inflated balloon ready to pop.
Also, they are not trialled for longevity yet and are expensive.
They sound good but are as usual, just an engineering trade off.
It has been done before, at least according to the article, it appears that there already is competition in this market:
Arizona-headquartered Microchip Technology designs and builds a rival range of 32-bit "Pic" microcontroller, while California-based Atmel offers 32-bit "Avr" products.
But doing a bit of fact-checking, it might not be so simple.
32 bit uCs are nothing new. However PIC32s are large high performance devices with AES, Ethernet, USB etc built in depending on model[1]. They operate in a totally different area. You can use one to run a webserver and drive an LCD panel for example.
Atmel also offer 32 bit uCs in the form of AVR32 and ARM based parts.
> I'm a bit surprised this hasn't been done before.
It kind of has been. This is not the first tiny low-power microprocessor out there -- it's just that ARM keeps pushing the envelope. The last "most power-efficient tiny 32-bit cpu" was Cortex-M0, of which this one is an evolutionary improvement.
Most of the embedded industry is still using really simple 8 or 16 bit microcontrollers. The business stragegy of ARM in the space is to push more advanced and complex cpus down to the space and grab marketshare by providing chips that are easier to program. It also helps that the size of the chip itself is a complete non-issue (the article referred to 1mm², while in reality the area for the core itself is actually less than 0.01mm² on a 40G process), and ARM can sell code density because they have more powerful instructions than the typical microcontroller, so while their cpu is bigger, the memory it needs is smaller.
Interesting that they only make comparisons with PIC and 8051. AVR still blows them away on many angles; particularly energy efficiency, community, ease of use on not-windows, and price. (MSP430 too, for efficiency and price.)
I'm fooling around with the lower power ARM chips on weekends, and they seem like a great option when you really want to shoehorn in a full operating system somewhere.
I don't think of AVRs as being particularly cheap relative to their competition but I haven't tried to buy any in quantity lately so what do I know. Maybe things have changed.
You really don't care as much when its got mains power but not all of these devices are plugged in. You will see them a lot in simple hand held consumer electronics like garage door openers, remote controllers, wireless mouses, kitchen timers and so on. In battery powered devices saving a mA make a world of difference.
mA may matter for something like a phone but really the war in the 8bit space is over uA and nA.
Many 8bit mcus end in places where their battery is expected to have a life time measured in years. Last I looked I think MicroChip is leading the way here in terms of sleep power. Their PIC XLP series only draws ~20nA while sleeping.
There is more competition in the 16bit space with the MSP430 from TI.
From an engineer's perspective, the AVR 8-bit instruction set is far nicer to work with than the 8-bit PIC. It's been a few years since I've been an embedded electronics engineer, but I seem to recall PIC not having an easy way to implement a stack, and hence a (proprietary) compiler which didn't support reentrant functions.
AVR OTOH has instructions which allow one to easily manipulate a stack, and since GCC targets AVR, you don't have to deal with Microchip's crappy compiler and can use whatever fun C constructs you wish and still get decent code.
Pretty apples to oranges here when saying something as general as '8-bit PIC' there are many architectures within that family, 4 last i knew. The low end ones are not intended for coding to with C anyway (although there are some poor compilers that try). The PIC18 series isn't bad to work with in C, I used the C18 compiler at the time and its 95% ANSI C.
I believe there is gcc support for the pic24/dsPIC (16bit) and the PIC32(32bit).
All that said last I knew Microchip still leads in 8bit mcu global market share.
Seems like a fairly straightforward evolution, they are claiming 11.2uW/MHz vs. 16 for the non-plus M0. Sounds like the instruction set is the same. I'm curious whether the M0 has been getting significant design wins over the established low-power microcontrollers like PIC, MSP430, etc.
Yeah, that's how the ARM microcontroller market works. I imagine NXP's peripheral set will be quite similar to the ones on their existing Cortex-M0 chips. Freescale will presumably base theirs on what's in their M4 parts, albeit scaled down. For another point of reference you could look at STMicro's Cortex-M0 implementation as well.
The idea behind a smart grid is usually some form of the local utility company taking money off your electric bill if your appliances are smart about not using energy at times of peak load. Nothing about the concept means the government has to be involved.
Well, ZigBee is what most governments are pushing for smart girds, and isn't totally free it is an open standard that anyone can join.
http://en.wikipedia.org/wiki/ZigBee
Yeah, there are lots of frequencies that are good locally, but not many that are good globally. If there were frequencies that were even just good in three of the US, Europe, India, and China that would probably be good enough.
ARM is a brilliant (if not the poster-boy) example of why the UK government should be investing in new technology companies rather than car manufacturing and banking.
On the other hand, the BBC Micro would almost certainly not have been the success it was without the Beeb and the lift it gave to Acorn in the educational market.
Look at it as very well-priced advertising, after all the BBC effectively promoted their product. They nearly lost out to Sinclair Research as well, but that's a well known story...
The BBC were careful never to say "Acorn" on-screen (same as they never said Sellotape, it was always "sticky-backed plastic", to the amusement of the entire population).
I actually had a NewBrain, think it's still around in my parents' attic somewhere.
I did quite a bit of real paying work on BBC Micros back in the day, and think they were great - but reading the way people tell the story today, one would be given the impression that the NewBrain was some kind of grim socialist piece of junk. It was actually a pretty decent bit of kit, quite a bit better quality than many of the other micros on the UK market at the time.
In an ironic turn, the company I worked for doing the BBC stuff later moved into Grundy's old premises in Teddington after they went bust.
To be fair, via TSB, the UK is investing in new technology companies... not sure how that compares to their investment in car manufacturing, though. However, afaik the main "investment" in banking was to save the banks that were going bust.
Disclaimer: I might be completely wrong about the above!
"If a British company imports components, it has to pay tax on those (and most components are not made in the UK). If, however, a completed device is made abroad and imported into the UK – with all of those components soldered onto it – it does not attract any import duty at all. This means that it’s really, really tax inefficient for an electronics company to do its manufacturing in Britain"
The banking industry managed to wreak itself without serious government investment. The trouble was an absence of effective deterrents to bankers seeking dangerously high levels of leverage.
ARM employs about 2 000 people [1]. They're definitely a huge boon for the British tech community and competitiveness, but justifying government support for such a small employee base would be untenable.
Most of the 2000 may be highly skilled or at least a large proportion to that of a bank, increasing funding in such a company may increase the number of people taking up science and engineering disciplines in education.
Yes. There's a temptation, because they both "make CPUs" to view ARM as the "next Intel", but it's not like that at all. Intel is an industrial manufacturing company. They happen to manufacture CPUs that they've designed, but "what they do" (or at least, where their money comes from and where the bulk of it goes to) is manufacturing. In the ARM world, all that cash flow goes through TSMC, Samsung, TI, Global Foundries, Fujitsu, etc... Basically none of it goes through the UK.
ARM's model, of course, is absolutely the future of semiconductor design. But it's not going to bring an Intel-sized industry to the UK.
I suppose you are too young to remember "picking winners", Harold Wilson, British Leyland, Red Robbo... Or more directly, Grundy and their NewBrain vs Acorn... Historically, government meddling in industry in the UK has been a disaster.
Well, they picked one winner - Leyland - and force-merged them with all the losers, in the hope that Leyland's magic would somehow infuse them. Instead, it destroyed them all. Some of the brands, like Jaguar, Daimler, Land Rover, etc live on. But not as British companies.
What went wrong with Leyland? It's a very respected trademark here in Uruguay, we still have some Leyland buses in operation here, including 1949 Leyland Olympics (!!!)
"The Olympic was popular in Montevideo, with 240 entering service in the 1950s and 1960s. 50 of these were new to the Montevideo local authority, most of which passed to major independent and the other customer CUTCSA on privatisation. Some of the 240 were still in use as late as 2001 including a 1951 EL40 in use as a driver trainer."
The US government picked winners like Intel, saving the US semiconductor industry through protectionist policies. (http://www.forbes.com/2003/10/10/1010grovepinnacor.html) In fact, the US technology industry was developed through enormous subsidy, from transistors to the internet.
Economist Ha-Joon Chang discusses that's how powerful nations develop. The entrepreneurial Japanese government's first forays into the auto industry were failures, but of course they kept at it, learning from failure. That's the nature of investment, as any HN reader should know.
Japan's record isn't that good - MITI tried to strangle both Japanese auto exports and the semiconductor industry in their cradle because they didn't conform to Japan's development plan.
You have to remember how many failures it takes to have a big success. For every Intel there's a wasteland of shoulda-been companies that are dead and forgotten, with billions invested having gone up in smoke.
Of course, when it's private venture capital that's behind this, people don't seem to complain as much.
Honestly, I've been in a couple of startups (including one that got a lot of funding from VCs and going public) and I've never seen anything like the inefficiency that was normal in the public sector projects that I worked on.
Not that I'm against public funding of research - I'm absolutely not. But my experiences of public sector research funding on "large" projects completely put me off working in that sector (so much so that I left academia to co-found a start-up).
I've worked on publicly funded projects and in the private sector. The publicly funded projects were the worst for pointless reporting, accounting, and paperwork.
In the private sector, the boss pops his head in and asks what I've done to day and what I'll finish by the end of the week, and we adjust goals. It takes about 5 minutes a week to do this.
When I was working on a publicly funded project, there was a report to be filed every day that took an hour of my time to do, a report to be filed every week that took about three hours over the course of the week, meeting with management to make sure that the first two reports were complete, accurate, and not fudged which took an additional two hours a week, and an end of the month assessment for both spending and time clocked in that took about twelve hours over the course of a month.
That was probably the single biggest issue, although there were others, there was a huge administrative overhead on all of the projects that it made it difficult to spot where any actual research was being done.
I would speculate that you're probably more selective about the kinds of companies you work for than a VC is in funding them.
There have been some legendary turkeys over the last ten years, but for every pets.com or hairdryersbyemail.com there's dozens of others so misguided you never heard a thing, they just went nowhere fast.
I'm not quite sure why the government's choices back then would have any bearing on their choices 30 years later? It's not the same people. It's not even the same generation.
I don't need years of battery life: I need 32-36 hours (of use, not standby). Then I can go from charging daily, like in the nineteenth century where you have to wind your watch up every night, and Sherlock Homes can tell a watch belonged to a drunkard by scratches around where you insert the winding key; how different is it to fumble with the power adapter jack? - ahem, to charging whenever it is CONVENIENT for me. It still wouldn't quite last through a long weekend at a lodge with just one inconvenient power outlet if you use it a lot EVERY day, but most people don't and if you do, you still only have to find a quiet period to charge it ONCE during the long weekend, like whenever the social activity dies down.
How many people keep multiple chargers at the different places (home/office) they are, or even take one with them ALL the time, just so they don't get left stranded. All this is fixed if the machine has a longer cycle than you do, over a typical 1-2 day cycle. Then you can pick the most convenient time to charge up from 20 or 40 or 60 percent or wherever it's at by then, you can work on it it at a cafe without plugging it in after working somewhere else you couldn't plug it in the night before, or go away for the weekend with it without any charger at all, if you know you're back in the ofice Monday and are sure to use it less than that.
In the meantime you don't worry, you aren't inconvenienced.
But it's not because you don't need years that nobody else would. And it's not because you immediately link ARM to smartphones and music players that that's the only use for a power-efficient CPU. Think a little harder :-)
I was talking about my laptop. Terribly sorry I didn't make this clear, too late to edit! I mean that nobody even thinks of making a laptop with the battery life mentioned. For office tasks, who cares if it's an arm?
I'm not sure it'd be possible given how much power would be drawn by the peripherals: screen, wifi, hard disks / SSDs, USB ports if used... although I do wonder if there are computers with netbook processing power and laptop batteries/form factor.
Right, but my point was that nobody even bothers to serve this laptop market. If there are laptops with netbook processing power (in both sense of the words: power usage and processing power), an ssd, and a massive battery that will push that sucker close to 20 hours (on email, word processing, office tasks), then I don't know about it. I just think nobody even considers taht a priority. Instead, they focus on "a full day's charge" -- like a wind-up watch in the 19th century.
I was talking about my laptops -- terrible sorry this wasn't clear! I thought the cafe/home/office example made it clear. Who works all day on their phone?
I need years of battery life. Recharging means not being late for a charge cycle for 50+ years lest I suffer ventricular synchronization failure, and replacement means cutting a hole in my shoulder - both of which rather inconvenience me.
This is not about being able to go for long periods without bothering to charge, but about energy usage, and being able to get a long period of actual usage from a machine without having to charge it from a reliable mains supply.
You do need years of battery life. Not by improving the capacity of batteries, but by improving the rate at which energy is drawn from them.
As the article quotes:
"Every developed nation country has a graph showing electricity demand is going to outstrip supply at some point in the next 20 years unless we do something different,"
You are inconvenienced, just not in the manner you highlight.
Generally the package is big enough to get all the connections out at a scale that won't irritate manufacturing.
There are tiny packages though, NXP (one of the ARM builders) has a 2mm x 2mm package with a similar ARM in it, but they can only get 16 pins out at that scale, 4 are power and ground, one is clock leaving you 11 pins to rule the world. (data sheet: http://www.nxp.com/documents/data_sheet/LPC1102.pdf)
These are not sold as physical chips, but as logic macros, where someone implementing a soc pastes this on with all the other stuff he wants. The total chip size will of course be bigger so that it can have pins.
Well, strictly speaking the Cortex A9 is supposed to be 1mm x 1.5mm, but that's:
1. According to ARM's promotional materials. No corroboration from licensors, as far as I'm aware.
2. Without caches. If you look at those pretty pictures of Intel chips, those huge swatches of regular rectangular stuff are caches, and they take up space.
Does that mean their hardware can multiply 32-bit by 32-bit
numbers in a single clock cycle?? I took a computer organization course where I implemented a simple hardware multiplier and it took a lot more cycles than that, so I was curious.
107 comments
[ 0.28 ms ] story [ 196 ms ] threadI'm a bit surprised this hasn't been done before.
Can this chip be solar powered (I mean, obviously, with a small solar cell)?
On the other hand, having autonomous off-the-grid parking meters might be easier to install and maintain by a third party. Plus it allows you to start growing parking meters everywhere, even in the middle of nowhere. Let them pay!
Sure, but not having to dig additional holes in the ground is a huge cost saver.
I guess it's more cost effective than draw the wires a few kilometers from the city.
EDIT: sth like that http://www.google.pl/imgres?q=%C5%9Bwiat%C5%82a+baterie+slon...
(http://en.wikipedia.org/wiki/Electric_double-layer_capacitor)
An analogy: a traditional LiPoly cell is like a twisted rubber band waiting to unwind. An ultracap is like an inflated balloon ready to pop.
Also, they are not trialled for longevity yet and are expensive.
They sound good but are as usual, just an engineering trade off.
The Microchip website gives 404 errors when I try to read their press release http://www.microchip.com/pagehandler/en-us/press-release/mic... - not really a good sign, hard to verify any claims.
The Atmel TinyAVR devices are small (2mmx2mm) but appear only to be 8-bit and aren't really comparable to the Arm offering.
Atmel also offer 32 bit uCs in the form of AVR32 and ARM based parts.
[1] http://www.microchip.com/pagehandler/en-us/family/32bit/appl...
It kind of has been. This is not the first tiny low-power microprocessor out there -- it's just that ARM keeps pushing the envelope. The last "most power-efficient tiny 32-bit cpu" was Cortex-M0, of which this one is an evolutionary improvement.
Most of the embedded industry is still using really simple 8 or 16 bit microcontrollers. The business stragegy of ARM in the space is to push more advanced and complex cpus down to the space and grab marketshare by providing chips that are easier to program. It also helps that the size of the chip itself is a complete non-issue (the article referred to 1mm², while in reality the area for the core itself is actually less than 0.01mm² on a 40G process), and ARM can sell code density because they have more powerful instructions than the typical microcontroller, so while their cpu is bigger, the memory it needs is smaller.
http://www.arm.com/products/processors/cortex-m/cortex-m0plu...
Advantages over 8-bit and 16-bit processors for embedded solutions, according to ARM:
http://www.arm.com/products/processors/cortex-m/cortex-m0plu...
I'm fooling around with the lower power ARM chips on weekends, and they seem like a great option when you really want to shoehorn in a full operating system somewhere.
If the economic benefits were so strong for those devices being connected that should have already happened.
What am I missing?
Many 8bit mcus end in places where their battery is expected to have a life time measured in years. Last I looked I think MicroChip is leading the way here in terms of sleep power. Their PIC XLP series only draws ~20nA while sleeping.
There is more competition in the 16bit space with the MSP430 from TI.
For other readers, AVR:
http://www.atmel.com/products/microcontrollers/avr/default.a...
AVR OTOH has instructions which allow one to easily manipulate a stack, and since GCC targets AVR, you don't have to deal with Microchip's crappy compiler and can use whatever fun C constructs you wish and still get decent code.
I believe there is gcc support for the pic24/dsPIC (16bit) and the PIC32(32bit).
All that said last I knew Microchip still leads in 8bit mcu global market share.
Why not just use nuclear to produce abundant energy?
The post I was responding to was specifically calling for it to be government controlled.
</shameless plug>
Acorn were also almost overlooked in favour of a company called Grundy, which had government backing, but inferior technology.
http://en.wikipedia.org/wiki/Grundy_NewBrain
I did quite a bit of real paying work on BBC Micros back in the day, and think they were great - but reading the way people tell the story today, one would be given the impression that the NewBrain was some kind of grim socialist piece of junk. It was actually a pretty decent bit of kit, quite a bit better quality than many of the other micros on the UK market at the time.
In an ironic turn, the company I worked for doing the BBC stuff later moved into Grundy's old premises in Teddington after they went bust.
Disclaimer: I might be completely wrong about the above!
"If a British company imports components, it has to pay tax on those (and most components are not made in the UK). If, however, a completed device is made abroad and imported into the UK – with all of those components soldered onto it – it does not attract any import duty at all. This means that it’s really, really tax inefficient for an electronics company to do its manufacturing in Britain"
[1] http://www.arm.com/about/company-profile/index.php?setcookie...
ARM's model, of course, is absolutely the future of semiconductor design. But it's not going to bring an Intel-sized industry to the UK.
Sometimes the government picking a loser can still cause a market to expand.
The government always picks the losing team. The winning team doesn't want anything to do with the government.
It's even on Wikipedia http://en.wikipedia.org/wiki/Leyland-MCW_Olympic
"The Olympic was popular in Montevideo, with 240 entering service in the 1950s and 1960s. 50 of these were new to the Montevideo local authority, most of which passed to major independent and the other customer CUTCSA on privatisation. Some of the 240 were still in use as late as 2001 including a 1951 EL40 in use as a driver trainer."
Edit: kind-of-answered simultaneously here http://news.ycombinator.com/item?id=3698064 while I was writing the question :)
"they picked one winner - Leyland - and force-merged them with all the losers"
http://en.wikipedia.org/wiki/Morris_Marina
http://en.wikipedia.org/wiki/Austin_Allegro
Economist Ha-Joon Chang discusses that's how powerful nations develop. The entrepreneurial Japanese government's first forays into the auto industry were failures, but of course they kept at it, learning from failure. That's the nature of investment, as any HN reader should know.
It's not down to lack of money - but the way it has been spent.
Of course, when it's private venture capital that's behind this, people don't seem to complain as much.
Not that I'm against public funding of research - I'm absolutely not. But my experiences of public sector research funding on "large" projects completely put me off working in that sector (so much so that I left academia to co-found a start-up).
I've worked on publicly funded projects and in the private sector. The publicly funded projects were the worst for pointless reporting, accounting, and paperwork.
In the private sector, the boss pops his head in and asks what I've done to day and what I'll finish by the end of the week, and we adjust goals. It takes about 5 minutes a week to do this.
When I was working on a publicly funded project, there was a report to be filed every day that took an hour of my time to do, a report to be filed every week that took about three hours over the course of the week, meeting with management to make sure that the first two reports were complete, accurate, and not fudged which took an additional two hours a week, and an end of the month assessment for both spending and time clocked in that took about twelve hours over the course of a month.
So guess where I'm more productive.
There have been some legendary turkeys over the last ten years, but for every pets.com or hairdryersbyemail.com there's dozens of others so misguided you never heard a thing, they just went nowhere fast.
That's because private venture capital is people spending their own money, rather than other people's money.
ARM only employs ~2000 people, not all of whom are in the UK. That's hardly a mass employer like the manufacturing sector is.
How many people keep multiple chargers at the different places (home/office) they are, or even take one with them ALL the time, just so they don't get left stranded. All this is fixed if the machine has a longer cycle than you do, over a typical 1-2 day cycle. Then you can pick the most convenient time to charge up from 20 or 40 or 60 percent or wherever it's at by then, you can work on it it at a cafe without plugging it in after working somewhere else you couldn't plug it in the night before, or go away for the weekend with it without any charger at all, if you know you're back in the ofice Monday and are sure to use it less than that.
In the meantime you don't worry, you aren't inconvenienced.
Think about something more like a toaster or a temperature sensor.
You do need years of battery life. Not by improving the capacity of batteries, but by improving the rate at which energy is drawn from them.
As the article quotes: "Every developed nation country has a graph showing electricity demand is going to outstrip supply at some point in the next 20 years unless we do something different,"
You are inconvenienced, just not in the manner you highlight.
There are tiny packages though, NXP (one of the ARM builders) has a 2mm x 2mm package with a similar ARM in it, but they can only get 16 pins out at that scale, 4 are power and ground, one is clock leaving you 11 pins to rule the world. (data sheet: http://www.nxp.com/documents/data_sheet/LPC1102.pdf)
1. According to ARM's promotional materials. No corroboration from licensors, as far as I'm aware.
2. Without caches. If you look at those pretty pictures of Intel chips, those huge swatches of regular rectangular stuff are caches, and they take up space.
>Enhanced Instructions >Hardware single-cycle (32x32) multiply option
Does that mean their hardware can multiply 32-bit by 32-bit numbers in a single clock cycle?? I took a computer organization course where I implemented a simple hardware multiplier and it took a lot more cycles than that, so I was curious.
BTW, most FPGAs have HW multiplier prebuilt block, because you will loose lots of flip-flops or LUTs (or both) implementing one yourself.