From mboxrd@z Thu Jan 1 00:00:00 1970 Return-Path: Received: (majordomo@vger.kernel.org) by vger.kernel.org via listexpand id S1751823AbdISW1T (ORCPT ); Tue, 19 Sep 2017 18:27:19 -0400 Received: from mail-io0-f177.google.com ([209.85.223.177]:56651 "EHLO mail-io0-f177.google.com" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S1751797AbdISW1P (ORCPT ); Tue, 19 Sep 2017 18:27:15 -0400 X-Google-Smtp-Source: AOwi7QBWV5cE5MsM7BKl+pyswJbllxpDANDJWcEb3Q8ojlLEgL2MiW0OVX5nenvJ1wSqRZcKBhtWP1mJYa7Zy/3cMfI= MIME-Version: 1.0 In-Reply-To: <478868b7-ff09-1332-5459-e788d0adae99@linaro.org> References: <20170904153504.27963-1-enric.balletbo@collabora.com> <239c9153-c0ea-319c-b554-3c727b75c8cd@linaro.org> <000001d32664$db62b2a0$922817e0$@gmail.com> <478868b7-ff09-1332-5459-e788d0adae99@linaro.org> From: Enric Balletbo Serra Date: Wed, 20 Sep 2017 00:27:13 +0200 Message-ID: Subject: Re: Re: [RFC 0/2] backlight: pwm_bl: support linear brightness to human eye To: Daniel Thompson Cc: Doug Anderson , Jingoo Han , Enric Balletbo i Serra , Lee Jones , Richard Purdie , Jacek Anaszewski , Pavel Machek , Rob Herring , Mark Rutland , Brian Norris , Guenter Roeck , linux-leds@vger.kernel.org, "devicetree@vger.kernel.org" , "linux-kernel@vger.kernel.org" , Alexandru M Stan Content-Type: text/plain; charset="UTF-8" Sender: linux-kernel-owner@vger.kernel.org List-ID: X-Mailing-List: linux-kernel@vger.kernel.org Hi Daniel, 2017-09-18 18:00 GMT+02:00 Daniel Thompson : > On 14/09/17 11:46, Enric Balletbo Serra wrote: >>>>> >>>>> So far in these discussions folks have been assuming that if we just >>>>> apply cie1931 to the PWM Duty Cycle then we're done and we have >>>>> perceived brightness in Lumens. ...but I think that's not quite >>>>> right. There are more factors. Let's use the datasheet for a random >>>>> backlight driver, like RT8561A. There appears to be a public >>>>> datasheet at >>>>> . >>>>> >>>>> A) There may be a non-linear curve between PWM Duty Cycle and LED >>>>> Current (mA). The particular curve is different based on mode >>>>> (Digital Ctrl vs. Analog Ctrl) and also PWM Frequency. Sometimes this >>>>> curve is nearly linear for large parts of the curve but not the whole >>>>> curve. Sometimes even though the curve is nearly linear there is an >>>>> offset (AKA 10% duty cycle could still produce nearly zero light >>>>> output). >>>>> >>>>> B) There may be a non-linear curve between LED current and light >>>>> output in Watts (I think?). >>>>> >>>>> C) The human perception model means there is a non-linear curve >>>>> between light output in Watts and human perceived brightness in >>>>> Lumens. >>>>> >>>>> So A and B are hardware dependent and _do_ belong in the device tree >>>>> (IMHO). >>>> >>>> >>>> >>>> You forgot to model how to screen size and its maximum light output of >>>> the >>>> backlight impact pupil dilation ;-). >>> >>> >>> Silly me... Oops, I also forgot to account for the absolute humidity >>> of the room. Do you think we can require all backlights come with a >>> humidity sensor? >>> >>> >>>> Or... putting it another way, A and B are only relevant if they help us >>>> eliminate significant sources of error. >>> >>> >>> Right. ...so your point is we can't model everything and we just need >>> to choose what's important. >>> >>> I'll agree that "B" above might not be worth modelling (though I don't >>> know). ...but I think we need to do _something_ about A. >>> >>> From the datasheet I point at looking at "Figure 8. LED Current vs. >>> ACTL PWM Dimming Duty Cycle", it seems like we at least need to do >>> something to account for the curve if we happen to be running at 30 >>> kHz for whatever reason. Specifically if we do no other work then any >>> duty cycle below 8% will result in no brightness. Eyeballing the >>> graph 10% duty cycle looks to be about 2% current. >>> >>> One option to solve this type of problem is to to specify a minimum >>> offset and assume things are linear after that offset. That might >>> work, but it also might prevent you from accessing some of those nice >>> low brightness points. Historically I have been frustrated when in >>> dark rooms that I couldn't set the brightness to be dim enough... >>> >>> The whole piecewise linear concept is that maybe you'd specify the >>> curve (in terms of milliPercent) like this (values found by measuring >>> datasheet curve with a ruler): >>> >>> <0 0> >>> <10000 1800> # 10% duty cycle gives 1.8% current >>> <12000 4300> # 12% duty cycle gives 4.3% current >>> <17000 10000> # 17% duty cycle gives 10% current >>> <93000 90000> # 93% duty cycle gives 90% current >>> <100000 100000> # 100% duty cycle gives 100% current >>> >>> >>>>> ...then the question is whether the device tree should specify the >>>>> curve so that the Watts scales linearly (and then the kernel adjust >>>>> for human perception) or so that Lumens scales linearly (which is >>>>> already adjusted for human perception). >>>>> >>>>> Historically I believe the device tree has always wanted it so that >>>>> Lumens scales linearly. So I guess the "we don't do anything" answer >>>>> is that the device tree should help account for for A + B + C. >>>> >>>> >>>> >>>> I would interpret the history slightly differently (although I'm not an >>>> authoritative historian here). >>>> >>>> There is a problem with the backlight interfaces (but entirely unrelated >>>> to >>>> Enric'c patch). The units the backlight users are not defined and varies >>>> from driver to driver. >>>> >> >> Based on this seems reasonable maintain current implementation to not >> break backward compability. Even, I think makes sense improve current >> implementation by adding somekind of piecewise linear concept to the >> brightness levels, similar to Doug's suggestion. So if we want, i.e, >> 256 levels or more, instead of specify the full table in the DT we can >> only specify some points in DT but the driver can expose to userspace >> more steps (how many?) between two brightness levels. Of course, this >> doesn't makes the live of the future users easier but I think will >> make the live of the current users of this interface more flexible >> (specially when you want lots of levels). > > > Ideally I'd like the driver to derive the number of steps based on the PWM > resolution it discovers (I don't entirely agree that having a large portion > of the slider map to no change is a good thing... we should be able to > estimate the smallest useful step size). > > Having said that, I'm open to suggestions about why we cannot make such an > estimate. > > >> Then, to make the user live easier, there is the thing about human >> perception, we can move brightness-levels to be optional and fall to >> apply the human perception code if it's not specified. Here the thing >> and point of discussion is, if the cie1931 is the right algorithm to >> do the 'magic' in the driver. From what I investigated seems that is >> but I might be wrong. > > > It's certainly more correct than linear ;-) . > > Actually I don't recall you commenting on the idea that we could ditch the > fixed point code and simply have a default table built into the driver that > can be used if there is no brightness-levels property (interpreted by the > same piecewise linear code as everything else). > Sounds a good idea, was on my mind improve the fixed point code, but this is better, indeed. I'm not sure if one table will be enough though, maybe we need a table for every PWM resolution? I'll try to do some tests on some different boards. Enric > I suspect such a table could be fairly small. > > >> Seems reasonable apply both solutions? I can send a second RFC with >> both approaches. > > > Works for me. > > > Daniel.