Lets start this article with a poll.

If there’s one thing that always annoys me in the ultra mobile PC category, it’s a wasted chance. Be it poor design, poor software or poor hardware. If there’s one thing that annoys me more than that its when a company makes the same mistake twice. Even worse than that is when the device in question is high-quality in every other respect. Because of this I find the SC3 the most frustrating device I’ve ever owned. I want so much to love it and take it into my daily life but….

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Author: Hanno Zulla
Original article appears on Hanno’s blog. Reprinted in full with permission.

When it comes to portable electronic gadgets, there are three major annoyances.

The three hour limit must fall

Photo by AndyArmstrong

There is an unwritten rule when designing portable computers:

The battery will last three hours.

Once technological advances allow the next generation to run longer – be it thanks to more efficient hardware or more powerful battery technology – the manufacturers decide to shrink the battery, capping the device back to the three hour limit.

Three is a nice psychological figure. “Lasts three hours? – not too short!” “Less than three kilogramms? – not too heavy!” After all these years, today’s 3 kg laptops usually still run for 3 hours or less.

This must end.

Three hours is not enough for a true mobile device (especially since the advertised three hours of battery time usually result to less than two in real use).

Read on for more….

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At CeBIT 2007, Intel revealed their ‘Menlow’ plans and told a room full of reporters that we’d be seeing sub 4W PCs in 2008. In March 2008 I asked Intel if they were on target and they told me that I’d be surprised. I am!

I’m lucky enough to be testing a Menlow-based Gigabyte M528 (sample) this weekend and this evening I’ve been doing a battery life test. I’m listening to MP3’s streaming over Wifi through a java applet on the Firefox 3-based browser with the CPU averaging about 30% utilisation (yes, this java app isn’t the most efficient at playing MP3’s!) It’s been going for over 2.5hours on its 10wh battery. (backlight off)

For those that don’t know, the Gigabyte M528 is one of the first MIDs and it’s based on Intel’s Menlow platform; A PC platform. This baby can run Windows XP!

The test is still going. Check back to see how long the test goes for….

Updates:

I’ve just passed the 3hrs mark. I hope the battery dies soon as its 00:20 here and I need to go to bed!!

It’s 12:30 now. 3hrs 10 mins…still going…

I estimate that with no backlight, the device is running about 0.5W less than with the screen backlight on at 50%. When the test finishes I can estimate a backlight-on time.

3hrs 20 mins. That’s an average drain of 3W. Its getting into smartphone territory at this point.

3hrs 30 mins….

Battery light flashing at 3hrs 35 mins… not long to go now.

And there she goes. Test completed at 3hrs 35 mins.

Average battery drain (assuming the battery really is empty now.) 2.8W

I estimate that with the screen on, it would be about 3.3W which would give a run time of 3hrs.

Well done Intel! I’m off to bed now.

This tickled me. A post on Friendfeed a short while ago…

“As the iPhone begins to resemble and be used like a computer, we will have to contend with challenges like crashing and battery life.” [Steve Rubel]

He’s right. Many people still assume that smartphones have excellent battery life compared to UMPCs. The reality is slightly less exciting if you use both devices for mobile Internet activities on a regular basis.

Apart from having a little giggle, the comment also reminded me to check up on the reported iPhone 3G battery life and compare it with my figures. I came up with an interesting article from AnandTech who have completed a browsing test which resulted in a dead iPhone in just over three hours. That’s much less than the 5-hrs quoted by Apple. It’s not even the most power-hungry test you could do on an iPhone. Try doing some Voip, live tracking or even IM with some music playing in the background and you’ll have a dead iPhone in under 2 hrs. Well, you would if the Iphone would let you run 3rd party background tasks!

3G radios, GPUs, displays are all going to take a lot of power whether they’re on a ultra mobile PC or a smartphone. Add 3rd-party software into the mix and you find that if you want the FIE on a regular basis, there’s no substitute for a fat battery!  As I mentioned in a previous article, 10wh is about your minimum battery size for any serious mobile Internet device in 2008 and 2009. The battery in the iPhone is only 5wh (possibly only 4wh according to this article.) 

In perspective, the iPhone 3G is still an impressively efficient device. 1.5W maximum power drain makes it one of the most energy efficient MIDs around and it’s still leading the way in the consumer-oriented market. In 2007 we were seeing best-of-breed UMPCs taking 9W to do similar 3G browsing tasks. Later in 2008, the differential will shrink to just 2 or 3watts and in 2010, the differential will be close to zero but in all cases, you still need that big battery if you need the FIE for long periods between charges. For now, the multi-device strategy still seems to be the best for you pro-mobile users.

[If you spot any other iPhone 3G battery life tests that were done under ‘MID’ conditions. Please drop me a comment. I’m interested. Thanks.]

Last Thursday I spent a lot of time analyzing exactly how efficient my charging solution was with a real-life test. What dropped out was a rather poor picture of how inefficient the whole solar charging setup was. From over 1.2KW hitting the area of my solar panel I managed to use about 19W. That’s a 1.5% efficiency rate and its amazing that I was able to do anything with it!

Take a look at the diagram again below. it shows the loss-points along the route from the sun to the UMPC.

More efficient UMPCs?

Of course! Any improvement in efficiency here would help. Currently a good average is around 9W and if this could be reduced to 6W average, it would be a major improvement.

Bigger battery life?

No. For my tour, the battery life or battery capacity was really not an issue. 50W/hr per day total capacity (via two battery packs; one that can be used and one that can be charged, is ideal.)

Solar Panel improvements.

From 1.2KW that hit the panel, only 660W hits the solar cells and those cells are only around 8% efficient and this is the first place we can look for improvements.

Current top-end production solar panels are 22% efficient but these are hard panels. To get the equivalent of 25W power you would need a hard panel of about 35x35cm plus frame. Lets say 40cmx40cm in total area. By using a hard panel of this size I could have actually put one on the front and one on the back of the bike to achieve a much more powerful solution. Finding a 40x40cm high efficiency panel might have been difficult though and probably less rugged. There could be a weight consideration too. Given the space restrictions on a bike, I think that a hard panel solution might have been better. In the campsite it wouldn’t have made much difference. The foldable panel was light and small and there should be no need for more than 25W of max power.

Battery tech and charging methods.

There’s a lot that needs to be improved here and the improvements can be achieved through a combination of process and of technology. What follows are the most important issues.

Lead-acid out!

The lead-acid battery proved to be a hindrance more than a help. It was heavy. It had no charge level indication and at low charge levels it couldn’t deliver enough current to drive my DC DC converter or even charge the AA batteries. In short, I didn’t use it much at all and I would drop it from my kit list if I did it again.

Li-Ion problems.

I knew that charging a battery just to have it charge another battery would be inefficient but I didn’t realize that it could be so bad. For example, the Li-Ion battery pack I have (Tekkeon/Tablet Kiosk MP3400) appears to lose about 25% energy through the input and Li-Ion charging stage. That is, you have to pump something like 20% more energy into it than it can store. But that’s not the whole story. The voltage conversion process on the output stage kills another 20% of the energy! From input to output you’re losing a shocking 40% or more energy!

But there’s another problem too and i’ve mentioned it before. The charging of Li-Ion batteries occurs at a fixed rate which means however much energy you have available and however quickly you could feed it into a Li-Ion battery, it won’t take it any quicker than its designed for. The MP3400 takes about 15W (about 0.8A at 19V) of energy to charge it and even if I attached a panel capable of delivering 50W, it would still only take 15W wasting a huge amount of available energy.

This last problem is the one that needs attention when designing a solar charging solution. I have detailed some possible solutions at the end of this article.

Direct charging UMPCs from solar.

One thing that I found annoying was that the only was I could charge my UMPC battery safely was to charge it from the Li-Ion battery. Obviously this is inefficient for the reasons mentioned above but why can’t I charge the UMPC direct from the solar panel? The main problem is that the DC input circuitry on the UMPC is an unknown factor. There’s no way to tell if there is over-voltage protection or whether it will charge a through varying input voltages and its just too much of a risk to try it out. When the DC input on the UMPC is broken, so is the UMPC! I also though about trying to charge the UMPC battery on its own but there’s no standard in connectors or charging currents and voltages so unless you want to build your own charging circuit, this isn’t possible (with the one exception of the OQO Model 02 that has an external battery charger.) I don’t really see this changing much on UMPCs in the near future though. There’s no real reason to increase the complexity of the DC circuit just because Chippy and a few others wish to use solar panels!!

How to improve the solar charging process today…

The Sunlinq 25w panel and Tekkeon MP2400 battery pack is an easy option, readily available and relatively cheap. It works, and if you use the tips above, it can be quite succesful but there are further improvements that could be made, especially if you have the time a flexibility to adjust your solution as you go. Lets assume the lead-acid battery option is too heavy and will not be used.

Ideally you will have the flexibility to add load and add solar capacity as conditions vary. This requires multiple smaller solar panels and multiple smaller Li-Ion batteries that can be set up in different situations. This is currently the only way to provide the most efficient charging solution. Buy multiple slow-charging (500mA for example) Li-Ion battery packs that can be stacked in parallel as energy availability increases.  You will need a voltage regulator on the output of the solar panel and this will need to match the input voltage of your charging solution. Preferably 12V. Fit an ammeter and voltmeter to the output of the voltage regulator so that you can monitor load and voltage. This all takes a lot of time and effort though and for most people its not worth the trouble. Ideally you would have a smart charger that does the monitoring and switches in Li-Ion packs as current availability increases. I have not seen such a solution yet and this, along with some more advanced solutions is what I’d like to see in the near future.

…and in the future.

How about a Li-Ion battery pack that has three levels of charging speed. Low, Med and High. These can be manually adjusted to match the energy available. Ultimately you would have a Li-Ion battery pack that self adjusts to the input current available. I have seen a few advanced components that claim to be able to do this but have never seen a consumer product that is able to do it. If you can get vari-charging Li-Ion batteries then there is really no need for the heavy lead-acid battery at all.

Finally, I’d like to see more UMPCs that have an external battery charger with good, efficient circuitry, over voltage protection and a wide range DC input voltage. Currently there are very few options here.

I’ll be watching this space carefully from now on and I hope that it won’t be long before I can report about new solutions to the issues of solar power and battery charging.

Location: Sürth
Distance since last post:15km
Weather: warm but cloudy and wet.
Notes: Always wear tight underwear when cycling!

A business issue this morning cost me 25% of my battery power and with the current weather situation, cloudy and wet, that could cost me dearly. There was a brief bright period at around noon where i slammed on the breaks and stopped to put out the panel but it was short, lived. The mobile phone needs a top-up and the GPS too. It’s fair to say that this has not been the best week for solar energy but despite that, it’s been possible to get a few hours of umpc work done every day. The bad weather has also made me think long and hard about how the process can be improved. I have some notes that i am going to try to type up tonight but that, of course, depends on my battery!

Distance since last post: 75km
Weather: Cloudy, rainy.
Forecast: Bad for the next 3-days. Looks like I’ll have to be careful!
Notes: Crashed into a lamppost while I was trying to mount my bike. No damage. Phew!

View towards Remagen (two bridge towsers can be seen at base of hill) in terrible weather.

No sun, no energy although somehow I’m managing to squeeze enough out of the clouds to charge the phone which is pretty amazing. Luckily I have enough juice on the UMPC battery and the Li-Ion battery to give me about 4 hours of computing. If I spot any sun at all over the next 3 days I’ll have to stop and sap up as much as I can. Its going to be very tight. Will I have enough left for the final report in Duesseldorf?

Right now I’m in Bonn and at home with my wife. I’m only using battery power and won’t be charging anything so there’s no change to the plan. Apart from a long bath and a good sleep tonight ready for the last two legs on Saturday and Sunday.

Distance since last post: 15km
Weather: Clouds thinning
Notes: I don’t have much faith in the lead-acid battery. The Li-Ion battery seems to be charging much more reliably.

Another day completed and I feel like I’m getting into a better rhythm. Checking emails and RSS on the mobile phone and creating rich journal updates with the Q1b. I only wish I had a  mind recorder because I’m thinking of some great ideas while I cycle but forgetting them when I get to a point where I could write them down!

The bike, which I’ve decided to call Berta (the Blue Bakers Bike) is performing fantastically well. I was a bit worried about having no gears but the fixed gear ratio is perfect for around 22km/h which, with 65KG of pack on a 25KG bike is just perfect. The thick tyres help to soak up bumps and now that I’ve pumped up the pressure a bit more, seem to roll without too much resistance. I even clocked 34kn/h on a straight today . Wohoo! Berta is Berta

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