From my testing last summer (31 Celsius in Hong Kong), the efficiency loss was much worse than 5%, especially at low charge currents:

http://www.teslamotorsclub.com/showthread.php/5655-Charging-in-High-Temperature-environments-13A-vs-32A-vs-70A-cost-of-air-conditioning

Here's were my results at around 31 Celsius:

<attachment.php.png>

Here is Tom's analysis of my log files, vs his in cool weather, at the time:

<Hot-Weather-Charging-Stats.png>

Bottom line is that ambient temperature is very important to the estimate.

Tom:

I agree that the log files would give us the best historical data for a jump-start on this. The issues are (a) getting the files, (b) ambient temperature.

I don't think (a) would be a problem. I'll submit my logs for inclusion (I've probably got 100 or 200 charges in there at temperatures from 5 Celcius up to 33 Celcius). 99% standard mode. I'm sure, that others would also submit, and we could pretty quickly build up a model.

For (b), we either need to find it in the logs files, approximate it from something in the log files, or use something like this to approximate it.

For example, I did a charge on my car at 19:31 on 30th March 2012. VMSParser shows:

03/30/2012 19:31:30 | 1333107090 | C1MB | Coolant 30C ESS 28C - 29C charging at 203.7V 0.01A

03/30/2012 19:31:30 | 1333107090 | C30M | range soc = 73%, 70A available

03/30/2012 19:31:31 | 1333107091 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.9V 0.00A

03/30/2012 19:31:32 | 1333107092 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.0V 0.02A

03/30/2012 19:31:33 | 1333107093 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.1V 0.00A

03/30/2012 19:31:34 | 1333107094 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.9V 0.00A

03/30/2012 19:31:35 | 1333107095 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.8V 0.02A

03/30/2012 19:31:36 | 1333107096 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.0V 0.01A

03/30/2012 19:31:37 | 1333107097 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.8V 0.00A

03/30/2012 19:31:38 | 1333107098 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.8V 0.01A

03/30/2012 19:31:39 | 1333107099 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.0V 0.00A

03/30/2012 19:31:40 | 1333107100 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.9V 0.02A

03/30/2012 19:31:41 | 1333107101 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.7V 0.00A

03/30/2012 19:31:42 | 1333107102 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.2V 0.04A

03/30/2012 19:31:43 | 1333107103 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.5V 0.00A

03/30/2012 19:31:44 | 1333107104 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.0V 0.02A

03/30/2012 19:31:45 | 1333107105 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.3V 0.00A

03/30/2012 19:31:46 | 1333107106 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.9V 0.02A

03/30/2012 19:31:47 | 1333107107 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.2V 0.00A

03/30/2012 19:31:48 | 1333107108 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.7V 0.01A

03/30/2012 19:31:49 | 1333107109 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.7V 0.00A

03/30/2012 19:31:50 | 1333107110 | C1MB | Coolant 30C ESS 28C - 29C charging at 221.9V 0.01A

03/30/2012 19:31:51 | 1333107111 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.2V 0.00A

03/30/2012 19:31:52 | 1333107112 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.3V 0.23A

03/30/2012 19:31:52 | 1333107112 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.3V 0.23A

03/30/2012 19:31:53 | 1333107113 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.8V 0.18A

03/30/2012 19:31:54 | 1333107114 | C1MB | Coolant 30C ESS 28C - 29C charging at 223.2V 0.19A

03/30/2012 19:31:55 | 1333107115 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.8V 2.23A

03/30/2012 19:31:56 | 1333107116 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.9V 2.52A

03/30/2012 19:31:57 | 1333107117 | C1MB | Coolant 30C ESS 28C - 29C charging at 222.1V 5.71A

03/30/2012 19:31:58 | 1333107118 | C1MB | Coolant 30C ESS 28C - 29C charging at 220.8V 16.96A

03/30/2012 19:31:59 | 1333107119 | C1MB | Coolant 30C ESS 28C - 29C charging at 219.9V 27.05A

03/30/2012 19:32:00 | 1333107120 | C1MB | Coolant 30C ESS 28C - 29C charging at 218.3V 36.99A

03/30/2012 19:32:01 | 1333107121 | C1MB | Coolant 30C ESS 28C - 29C charging at 217.5V 46.94A

03/30/2012 19:32:03 | 1333107123 | C1MB | Coolant 30C ESS 28C - 29C charging at 216.9V 47.74A

03/30/2012 19:32:04 | 1333107124 | C1MB | Coolant 30C ESS 28C - 29C charging at 216.7V 47.75A

03/30/2012 19:32:05 | 1333107125 | C1MB | Coolant 30C ESS 28C - 29C charging at 217.3V 47.79A

03/30/2012 19:33:05 | 1333107185 | C1MB | Coolant 30C ESS 28C - 29C charging at 216.7V 47.84A

03/30/2012 19:34:05 | 1333107245 | C1MB | Coolant 16C ESS 25C - 28C charging at 217.9V 48.12A

03/30/2012 19:35:05 | 1333107305 | C1MB | Coolant 16C ESS 22C - 27C charging at 218.1V 47.96A

03/30/2012 19:36:05 | 1333107365 | C1MB | Coolant 24C ESS 25C - 27C charging at 217.7V 47.97A

03/30/2012 19:37:05 | 1333107425 | C1MB | Coolant 26C ESS 26C - 27C charging at 218.8V 48.11A

03/30/2012 19:38:05 | 1333107485 | C1MB | Coolant 28C ESS 26C - 28C charging at 217.5V 47.92A

03/30/2012 19:39:05 | 1333107545 | C1MB | Coolant 28C ESS 27C - 28C charging at 217.7V 48.06A

03/30/2012 19:40:05 | 1333107605 | C1MB | Coolant 28C ESS 27C - 28C charging at 218.5V 48.11A

03/30/2012 19:41:05 | 1333107665 | C1MB | Coolant 28C ESS 27C - 28C charging at 218.9V 48.14A

03/30/2012 19:42:05 | 1333107725 | C1MB | Coolant 14C ESS 23C - 27C charging at 217.0V 47.81A

03/30/2012 19:43:05 | 1333107785 | C1MB | Coolant 23C ESS 24C - 26C charging at 216.8V 47.74A

03/30/2012 19:44:05 | 1333107845 | C1MB | Coolant 26C ESS 25C - 27C charging at 217.9V 47.98A

03/30/2012 19:45:05 | 1333107905 | C1MB | Coolant 26C ESS 26C - 27C charging at 216.9V 47.78A

03/30/2012 19:46:05 | 1333107965 | C1MB | Coolant 27C ESS 26C - 27C charging at 218.8V 48.14A

03/30/2012 19:47:05 | 1333108025 | C1MB | Coolant 28C ESS 26C - 27C charging at 216.7V 47.77A

03/30/2012 19:48:05 | 1333108085 | C1MB | Coolant 28C ESS 26C - 27C charging at 216.3V 48.09A

03/30/2012 19:49:05 | 1333108145 | C1MB | Coolant 17C ESS 24C - 27C charging at 216.4V 47.76A

03/30/2012 19:50:06 | 1333108206 | C1MB | Coolant 22C ESS 23C - 26C charging at 218.4V 48.26A

03/30/2012 19:51:06 | 1333108266 | C1MB | Coolant 24C ESS 24C - 26C charging at 218.4V 48.26A

03/30/2012 19:52:07 | 1333108327 | C1MB | Coolant 26C ESS 25C - 26C charging at 217.7V 48.16A

03/30/2012 19:53:08 | 1333108388 | C1MB | Coolant 26C ESS 25C - 26C charging at 219.1V 48.25A

03/30/2012 19:54:08 | 1333108448 | C1MB | Coolant 27C ESS 25C - 27C charging at 218.3V 48.27A

03/30/2012 19:55:09 | 1333108509 | C1MB | Coolant 27C ESS 26C - 27C charging at 217.0V 47.95A

03/30/2012 19:56:10 | 1333108570 | C1MB | Coolant 28C ESS 26C - 27C charging at 217.0V 48.03A

03/30/2012 19:57:10 | 1333108630 | C1MB | Coolant 14C ESS 23C - 26C charging at 218.0V 48.02A

03/30/2012 19:58:11 | 1333108691 | C1MB | Coolant 24C ESS 24C - 26C charging at 217.4V 47.98A

03/30/2012 19:59:12 | 1333108752 | C1MB | Coolant 25C ESS 24C - 26C charging at 216.6V 47.78A

03/30/2012 20:00:13 | 1333108813 | C1MB | Coolant 26C ESS 25C - 26C charging at 216.9V 47.81A

03/30/2012 20:01:13 | 1333108873 | C1MB | Coolant 26C ESS 25C - 26C charging at 218.7V 48.27A

03/30/2012 20:01:30 | 1333108890 | C30M | range soc = 79%, 70A available

03/30/2012 20:02:14 | 1333108934 | C1MB | Coolant 26C ESS 25C - 26C charging at 218.4V 48.16A

03/30/2012 20:03:15 | 1333108995 | C1MB | Coolant 27C ESS 25C - 26C charging at 217.5V 47.79A

03/30/2012 20:04:15 | 1333109055 | C1MB | Coolant 17C ESS 24C - 26C charging at 217.3V 47.79A

03/30/2012 20:05:16 | 1333109116 | C1MB | Coolant 21C ESS 22C - 25C charging at 218.2V 47.85A

03/30/2012 20:06:17 | 1333109177 | C1MB | Coolant 24C ESS 24C - 25C charging at 217.3V 49.34A

03/30/2012 20:07:17 | 1333109237 | C1MB | Coolant 25C ESS 24C - 25C charging at 218.4V 45.78A

03/30/2012 20:08:18 | 1333109298 | C1MB | Coolant 26C ESS 24C - 26C charging at 220.4V 42.43A

03/30/2012 20:09:19 | 1333109359 | C1MB | Coolant 26C ESS 25C - 26C charging at 220.0V 43.13A

03/30/2012 20:10:19 | 1333109419 | C1MB | Coolant 26C ESS 25C - 26C charging at 219.6V 42.09A

03/30/2012 20:11:20 | 1333109480 | C1MB | Coolant 26C ESS 25C - 26C charging at 218.3V 43.46A

03/30/2012 20:12:21 | 1333109541 | C1MB | Coolant 26C ESS 25C - 26C charging at 218.6V 41.73A

03/30/2012 20:13:22 | 1333109602 | C1MB | Coolant 14C ESS 22C - 25C charging at 220.4V 40.81A

03/30/2012 20:14:22 | 1333109662 | C1MB | Coolant 23C ESS 23C - 25C charging at 219.5V 33.66A

03/30/2012 20:15:23 | 1333109723 | C1MB | Coolant 24C ESS 24C - 25C charging at 218.9V 36.06A

03/30/2012 20:16:24 | 1333109784 | C1MB | Coolant 25C ESS 24C - 25C charging at 220.4V 35.36A

03/30/2012 20:17:24 | 1333109844 | C1MB | Coolant 26C ESS 24C - 25C charging at 221.0V 32.97A

03/30/2012 20:18:25 | 1333109905 | C1MB | Coolant 26C ESS 24C - 25C charging at 220.9V 32.17A

03/30/2012 20:19:26 | 1333109966 | C1MB | Coolant 26C ESS 24C - 25C charging at 219.4V 33.65A

03/30/2012 20:20:26 | 1333110026 | C1MB | Coolant 13C ESS 22C - 25C charging at 218.9V 37.86A

03/30/2012 20:21:27 | 1333110087 | C1MB | Coolant 22C ESS 22C - 24C charging at 219.2V 28.58A

03/30/2012 20:22:28 | 1333110148 | C1MB | Coolant 24C ESS 23C - 24C charging at 220.6V 27.84A

03/30/2012 20:23:28 | 1333110208 | C1MB | Coolant 24C ESS 23C - 25C charging at 219.7V 27.55A

03/30/2012 20:24:29 | 1333110269 | C1MB | Coolant 25C ESS 24C - 25C charging at 221.3V 28.81A

03/30/2012 20:25:30 | 1333110330 | C1MB | Coolant 26C ESS 24C - 25C charging at 219.6V 24.53A

03/30/2012 20:26:30 | 1333110390 | C1MB | Coolant 26C ESS 24C - 25C charging at 219.1V 26.89A

03/30/2012 20:27:31 | 1333110451 | C1MB | Coolant 26C ESS 24C - 25C charging at 220.6V 26.35A

03/30/2012 20:28:32 | 1333110512 | C1MB | Coolant 26C ESS 24C - 25C charging at 220.5V 24.03A

03/30/2012 20:29:13 | 1333110553 | IDLE | range soc = 84% ESS 23C - 25C, 2.691V min, 1.205V max

and OVMS reported:

2012-03-30 18:24:07.142047 +0800 info  main: #10 C EV915 rx msg S 81,K,-1,0,done,standard,250,219,48,67,100,10,7,4,0

2012-03-30 18:24:07.144289 +0800 info  main: #10 C EV915 rx msg D 136,32,3,42,78,29,3272,65163,45,0,25,2,113,113

==> Driving PEM:42, MOTOR:78, BATTERY:29, AMBIENT:25

2012-03-30 19:23:57.730154 +0800 info  main: #10 C EV915 rx msg S 81,K,-1,0,done,standard,250,234,48,67,100,10,7,4,0

2012-03-30 19:23:57.732294 +0800 info  main: #10 C EV915 rx msg D 104,8,4,34,56,29,3284,65175,0,3379,24,2,102,113

==> Stopped PEM:34, MOTOR:56, BATTERY:29, AMBIENT:24

2012-03-30 19:33:57.348051 +0800 info  main: #10 C EV915 rx msg S 82,K,217,48,charging,standard,253,237,48,2,100,0,5,1,0

2012-03-30 19:33:57.374906 +0800 info  main: #10 C EV915 rx msg D 124,8,4,42,55,28,3284,65175,0,3986,25,2,120,120

==> Charging PEM:42, MOTOR:55, BATTERY:28, AMBIENT:25

2012-03-30 19:44:11.802571 +0800 info  main: #10 C EV915 rx msg S 84,K,217,48,charging,standard,262,245,48,12,100,2,5,1,0

2012-03-30 19:44:11.805104 +0800 info  main: #10 C EV915 rx msg D 124,8,4,43,53,27,3284,65175,0,4581,29,2,118,118

==> Charging PEM:43, MOTOR:53, BATTERY:27, AMBIENT:29

2012-03-30 19:53:11.578629 +0800 info  main: #10 C EV915 rx msg S 87,K,219,48,charging,standard,270,253,48,21,100,4,5,1,0

2012-03-30 19:53:11.582720 +0800 info  main: #10 C EV915 rx msg D 124,8,4,43,52,26,3284,65175,0,5142,28,2,120,120

==> Charging PEM:43, MOTOR:52, BATTERY:26, AMBIENT:28

2012-03-30 20:03:55.020585 +0800 info  main: #10 C EV915 rx msg S 91,K,218,48,charging,standard,282,262,48,32,100,6,5,1,0

2012-03-30 20:03:55.022789 +0800 info  main: #10 C EV915 rx msg D 124,8,4,43,51,26,3284,65175,0,5777,27,2,114,114

==> Charging PEM:43, MOTOR:51, BATTERY:26, AMBIENT:27

2012-03-30 20:14:03.376116 +0800 info  main: #10 C EV915 rx msg S 93,K,220,37,charging,standard,290,270,48,42,100,7,5,1,0

2012-03-30 20:14:03.378258 +0800 info  main: #10 C EV915 rx msg D 124,8,4,43,49,25,3284,65175,0,6374,29,2,112,112

==> Charging PEM:43, MOTOR:49, BATTERY:25, AMBIENT:29

2012-03-30 20:24:01.668658 +0800 info  main: #10 C EV915 rx msg S 95,K,221,28,charging,standard,296,277,48,52,100,8,5,1,0

2012-03-30 20:24:01.681265 +0800 info  main: #10 C EV915 rx msg D 124,8,4,42,48,25,3284,65175,0,6980,29,2,120,120

==> Charging PEM:42, MOTOR:48, BATTERY:25, AMBIENT:29

2012-03-30 20:33:59.497056 +0800 info  main: #10 C EV915 rx msg S 96,K,0,0,done,standard,299,280,48,57,100,9,9,4,0

2012-03-30 20:33:59.505736 +0800 info  main: #10 C EV915 rx msg D 108,8,4,34,47,25,3284,65175,0,7577,27,2,119,119

==> Charged PEM:34, MOTOR:47, BATTERY: 25, AMBIENT:27

I reckon the actual ambient temperature was probably 24 or 25 Celcius. It goes up during the charge, presumably because the HVAC is spewing out hot air around the ambient sensor at the front of the car (which is in the garage so will build up heat).

I think my data above is not a very good example, as I wasn't driving hard so the battery temperature was unusually low. My first instinct was that it would be good to use as an approximation for ambient, but actually not. The theory is that when the ambient temperature is hot or cold, the car has to use HVAC/heater to keep the battery at the temperature it needs, and that uses power which reduces charging efficiency. Battery temperature is a side-effect, and won't help to predict energy usage.

So, I still think ambient temperature is the correct thing to use as a predictor for charging efficiency (along with current+voltage).

The question is, looking at historical logs how can we approximate that? Only looking at charges that occurred an hour after a drive would work, but would remove 95% of my charges, like anyone else who plugs in when they get home ;-)

Regards, Mark.

On 8 Apr, 2012, at 4:22 PM, Dominik Westner wrote:

I already did some tests calculating the remaining charge time and had it implemented in the iPhone app.

First I took the simple approach to linearly estimate the remaining time by taking the charge current and voltage and calculate the energy per sec. Then take the missing energy from the current SOC. This will give you an approximation of the remaining time.

If you are looking at +/- 1 hour. This already should work from my experience.

I tried to make it better by taking into account that the charging curve is not linear, but more on a logarithmic scale. This worked a bit better. I also figured that there is some loss when charging, which I set to 5% (this probably varies by temperature).

What I did not know is the fact that once finished charging the batteries will be rebalanced for 30 minutes. Is this still shown as charging in OVMS? If yes, this would explain, why I've been off for about 30 - 60 minutes with my calculation.

I also did not take the age of the battery into account, which should be an important factor, too.

I think that it might be better to use a formula which tries to approximate the charging curve instead of using a fixed lookup table. At least it also could be fine tuned a bit easier by just setting a couple of parameters through the app to change the calculation.

Greetings

Dominik

On 08.04.2012, at 06:16, Tom Saxton wrote:

I think your model would work pretty well.

To calculate charge time, you also have to take into account the current

tapering near the top of the charge.

We can get most of the required data from log files. The only tricky bit is

getting the ambient temperature, which I don't think anyone has identified

in the log files. You could get a good approximating by only considering

charge sessions that start a least an hour of the most recent drive and then

use the starting temperature of the coolant as a proxy for ambient

temperature.

Range mode is the trickiest and the most important to time, they are also

done less often, so it's harder to get data. I'd be happy to collect logs

and extract data if we can get owners to contribute logs for a variety of

charging levels and ambient temperatures.

  Tom

on 4/6/12 5:52 PM, Mark Webb-Johnson wrote:

The core question I have here is whether it is possible to build a static

table saying that at this temperature, this available voltage+currrent, the

charging efficiency is X%? Something accurate enough to give us a charge time

prediction (given temperature, kWh needed by the pack, available

voltage+current) of +/- 1 hour?

I'm assuming the temperature should be ambient, as that is more important

overt the duration of a reasonable charge than pack temperature?

If we can have such a table, with steps of 5 degrees celcius between -10C and

+40C, and say 10 current levels, that is only 100 entries - and we would only

need 1 byte for each entry. The module could then put in the current

temperature, current/voltage level, and get out an efficiency factor. It could

estimate the kWh the pack needs (by mode and SOC/ideal-miles difference), then

multiply by efficiency factor, and get out an estimate of how many minutes is

required to achieve that.

Without this table, we could do the lookup on the server, but that would mean

having to set it _every_ night from the App/Server - as it would depend on the

SOC% the car was actually at.

If we could build this data, where could we get the data from?

Regards, Mark.

Begin forwarded message:

From: Mark Webb-Johnson <mark@webb-johnson.net>

Subject: Re: [Ovmsdev] Charge Control

Date: 6 April, 2012 8:25:51 PM GMT+08:00

To: OVMS Developers <ovmsdev@lists.teslaclub.hk>

Bennett Leeds and I have had a discussion off-list (I'm not sure if he is on

this list or not), and he brings up a valid point about balancing the pack

perhaps not occurring if we cut short the charge with a SOC limit.

Looking here:

http://www.teslamotorsclub.com/showthread.php/3848-Tesla-Roadster-Battery-Car

e?p=41995&viewfull=1#post41995

it seems that this approach may be non-optimal. For clarity, let me

cut-and-paste the Tesla reply here:

For simplicity’s sake, I will refer to all SOC (State Of Charge) numbers as a

percentage of a full (100%) charge. I cannot provide exact percentages, as

there are many variables which can cause these numbers to vary slightly,

however, I will get as close as I can.

When plugging in a nearly empty car that is set to Storage mode, the charge

will generally stop at around 20%. The car will then settle into its normal

Storage mode rhythm, topping up and discharging between 10% and 50% as the

car sees fit. Oftentimes it will keep a tighter envelope based on parameters

that I am not aware of.

Most important to remember is that Storage mode is not intended to be a

driving mode. This charge setting is primarily meant to optimize battery life

while the car is under storage conditions for two weeks or more.

Storage mode does not attempt to balance the pack, and you will cause an

imbalance in the pack by driving and charging in this mode regularly.

This will penalize you when you do occasionally charge the car fully in the

other modes, as you will not have the full range of the car available to you

until the car has a chance to balance its battery. Additionally, the car’s

range will not be as accurate if driven while in Storage mode vs. having

charged it in Standard mode after storing the car, then driving it.

Allowing the car to sit plugged in after it has finished charging in Standard

mode automatically balances the pack, and it may take a few rounds of this to

bring an imbalanced pack back to its full potential after many partial

charges. This is one of the major reasons we recommend keeping the car in

Standard mode whenever possible. Partial charges in any mode, while not on

their own bad for the battery, do not give the car an opportunity to balance

its battery, and over time can prevent you from accessing the car’s full

range potential.

When balanced, Standard mode charges the car to about 87%, with Range and

Performance modes getting the car to about 97%. These two percentages are

very much affected by the balance between bricks in the battery. An

imbalanced pack will not fill up all the way in any mode, nor will it be able

to discharge as far. Additionally, the range predictions will not be as

accurate.

Your voltages are about right.

4.10 volts = full standard mode (187-195 ideal miles)

4.15 volts = full range mode

4.20 volts = maximum of the cells that we never touch

As you may know, there is much more to it than just using voltage to

calculate range with Lithium batteries. This is something that is incredibly

complicated, and not something that I am qualified to discuss in detail, as I

do not have the full picture.

It is important to remember that SOC is not the only factor in maximizing

battery life. For instance most lithium batteries are shipped at around

30-50% SOC in consumer electronics, and part of the reasoning is that they

are less susceptible to damage from extreme temperatures at these charge

levels. It is also safer to store them at these levels. Part of the benefit

of Storage mode is that there is less work required from the HVAC system to

keep the batteryhappy and safe, and therefore, less energy is consumed while

stored.

We chose ~90% as a Standard full charge level because it offers most of the

longevity benefit of keeping the car at a lower state of charge, while still

allowing a high degree of autonomy. I understand that you are interested in

taking extra steps to maximize your battery’s life, so I do have some

suggestions for you.

I would not recommend that you continue to use Storage mode as a means of

maintaining a lower state of charge. As I explained earlier, this mode is not

optimized for this type of use.

Think of battery degradation this way. It is very much a function of time

spent at voltage and temperature. For instance, you do not want to charge a

car all the way in performance mode, and then let it sit in the sun all day.

Between the higher thermal limits and the high SOC, you are causing the

battery a relatively high amount of degradation .In fact, the car will

eventually allow itself to discharge to Standard levels if left in

Performance mode to prevent inadvertent damage to the battery. If you start

driving right away after charging in Performance or Range Mode, and don’t let

it sit, you would minimize the damage incurred, as the time spent at these

extremes is an important part of the calculation.

Similarly, if you top off to full in Standard mode, then jump in the car

right away and bring the SOC down quickly, you will minimize the small amount

of degradation that occurs at ~90%.

If you prefer to keep a lower average SOC in an attempt to maximize the life

of your battery, I would instead suggest that you stay in Standard mode and

utilize the Roadster’s built in charge timer and current limiting options to

find an average SOC that works for you. For instance, try starting your

charge at a time that allows the car to top off to a level you are

comfortable with right before you need to leave. Alternately, you can use the

Current limiting function to adjust the amount of time it takes the car

reaches a target SOC, or even a combination of these two options. The car

will remember the settings you select based on your location, so once you

find something that works for your commute, you can set it and forget it.

Just remember that the car does benefit from being allowed to sit fully

charged in Standard mode, and should be allowed to do so frequently,

especially if being used on a daily basis. Leaving the car plugged in in

Standard mode after it is done charging will initiate this balancing program

automatically. This doesn’t take much time, 30 minutes or so should do. It

may take several of these balancing cycles to bring the car back to a

balanced state if it has become imbalanced, which is something that a lack of

regular Standard mode top ups and subsequent balancing cycles can induce.

It would therefore be a good idea to set the car to “Charge on Plug In”

instead of “Charge at X time” in the charge timing menu for at least a few

Standard mode charges per week to keep the pack balanced. There are simply

too many variables for me to be able to predict how often you would need to

do this, and we do not have a recommended procedure for alternate desired

average SOC levels.

I hope this helps answer your questions, and gives you a better idea of how

to maximize battery life under your driving conditions.

Regards,

Dan Myggen

From what he is saying, it appears optimal to time the charge to bring it to

full charge in standard mode 30 minutes before you leave. That would leave

the car sitting at high charge rate for the least amount of time, but allow

enough time for balancing to occur if necessary.

This sounds exactly like our finish-charging-by approach. Rather than set the

charge start time, you set the finish time, and the system works out how long

it should take then adds on a 30-to-60 minute safety margin (which would also

allow for battery balancing to occur).

Does this make sense? Or is Dan Myggen's advise wrong?

Regards, Mark

On 5 Apr, 2012, at 7:45 PM, Mark Webb-Johnson wrote:

I'm now starting to think about the v1.3 firmware, which is intended to add

the following:

Log charge history

Log drive history

Sophisticated control of charge time

We don't really have TOU metering in Hong Kong, so not much use for me, but

part [3] would be fun nevertheless. Most charge control in EVs is pretty

basic, and it might be interesting to see how sophisticated this can be made

without complications.

I don't know if this is workable or not, so put my thoughts out into the

open for discussion.

For charge time, the consensus seems to be that people want to enter the

time to FINISH charge, vs the current time to START charge. To do that, we

need an estimate of how long the charge will take. For that, we either need

a sophisticated model or a collection of historical data we can lookup to

find something approximate. Hence item [1] on my list.

Elon talked about the car learning about you. Where you park. Where you

charge. etc. So, if always leave home at 7:00am to go to the office on

Mondays through Fridays, perhaps the car can learn? Or, at least suggest

based on what it has seen... Hence item [2] on my list.

For [1], we would store such things as temperatures, SOC start, SOC end,

charge mode, charge current, charge voltage and duration. The can bus charge

message seem to include this information.

For [2], we would store such things as date/time of drive, duration (time,

distance, and elevation change), battery usage. We seem limited in this from

what we have decoded on the can bus so far.

Regardless of the above, [1] and [2] would be useful information for any

owner, anyway.

Privacy is an issue. Two problems - (a) protection of my charge/drive

history, (b) the use of 'shared' charge history for [3]. My suggestion is to

keep drive and charge history private. Perhaps it could just be stored as

paranoid mode blobs. But, there should be an option to allow anonymised

sharing of charge history for the use of [3]. My thinking is that if you

share your data anonymously, then your lookup includes the pool of others

anonymous charge history. if you choose not to share, then your lookup is

only against your own charge history.

I did toy with the idea of using the server to control this. So, at 3am the

server sends a command to the car to start the charge, etc. That would

simplify the firmware in the car, but has a major problem of GPRS

connectivity - if the cellular signal was lost the charge wouldn't start.

Bad. So, I think it best to have the historical database in the server, the

calculations in the App, and the settings downloaded to the car while it has

cellular signal (after which it just follows them autonomously).

The Tesla Roadster currently offers you a choice of charge on plug-in, or

start charge at a particular time. It also allows you to limit charge

current and set charge mode. My thinking is to extend this by making it per

day-of-the-week for a few defined locations, and to provide an override for

the 'current' day/night. If the override is not set, and you are in one of

the defined locations, then the system looks up the day of the week and

controls charge based on what you have set. The UI for this is quite simple

- presumably a screen with tabs/selector for day or the week, and then

controls to set charge mode, current limit, and time to start/complete by.

One developer also had the good idea that a charge SOC limit would be useful

(e.g.; please stop charge when it gets to 70% / 220km ideal).

How do we handle night vs day charging? Is this only for overnight, or do we

base it on when you plugin?

Is this workable? Useful?

Really interested in people's feedback on this.

Mark.

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