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Quote from: dreamdragon on January 16, 2014, 05:02:11 pmokay FINE. no emulate! my original question was this:can i run a ti84 os on a ti84 +c se directly? [can someone please scratch my back?!?!?]Quote from: Xeda112358 on January 16, 2014, 10:58:02 pmThat would require a modified OS updating all of the graphics of the OS. This is essentially what the CSE OSes are Added to that: Once you have a modded 84+ OS that works on the CSE, It will only be able to run BASIC programs correctly, and it will still run slower than the 84+ because it has to send more data to the screen. Assembly, axe, hybrid basic and probably also grammmar programs will still display garbage because they use their own routines to display stuff.
okay FINE. no emulate! my original question was this:can i run a ti84 os on a ti84 +c se directly? [can someone please scratch my back?!?!?]
That would require a modified OS updating all of the graphics of the OS. This is essentially what the CSE OSes are
More technically, the controller only accepts 16- or 18-bit color, meaning 2 to 3 writes per pixel. Outputting a single pixel takes at least 29 clock cycles (for filling the screen with a single color). By contrast, the old controller needed about 100 clock cycles per write, but each write could send 8 pixels, so each pixel only averaged 12 clock cycles. So it takes three times as long to write a single pixel (if you want actual graphics), and the screen has 12.5 times as many pixels. The old controller can accept 120 96x64 frames per second (but it only displays at 60 fps); the new one, displaying only a shrunken 96x64 subsection, can only manage 60 fps. So, the maximum frame rate for full-screen display is 7 fps (0.15 sec/frame), and that's only possible if you're filling the screen with a single color. In practice, 5-6 fps (about 0.2 s/f) is the best you can possibly get for full screen graphics.
From what I remember, the bottleneck is really the LCD itself. The CPU is only capable of updating 4 LCDs worth of data every second because there's just too much data to update. Of course the LCD driver might be at cause too, but since the CPU is too slow for the large LCD itself to begin with, it barely makes a difference. On the older models, there is barely any data to send to the LCD so yes the slow LCD driver can make a noticeable difference. It's possible that the CSE has no LCD driver delay, though.I think DrDnar once posted the t-states calculations showing the max possible frame rate on the CSE. Kerm's ball program also demonstrates how slow it can be by changing the entire LCD color before the ball animation starts.EDIT: Ok I found it: http://ourl.ca/18368/338852Quote from: DrDnarMore technically, the controller only accepts 16- or 18-bit color, meaning 2 to 3 writes per pixel. Outputting a single pixel takes at least 29 clock cycles (for filling the screen with a single color). By contrast, the old controller needed about 100 clock cycles per write, but each write could send 8 pixels, so each pixel only averaged 12 clock cycles. So it takes three times as long to write a single pixel (if you want actual graphics), and the screen has 12.5 times as many pixels. The old controller can accept 120 96x64 frames per second (but it only displays at 60 fps); the new one, displaying only a shrunken 96x64 subsection, can only manage 60 fps. So, the maximum frame rate for full-screen display is 7 fps (0.15 sec/frame), and that's only possible if you're filling the screen with a single color. In practice, 5-6 fps (about 0.2 s/f) is the best you can possibly get for full screen graphics.
Because TI-CARESTM.
Quote from: DJ Omnimaga on January 17, 2014, 12:07:21 pmFrom what I remember, the bottleneck is really the LCD itself. The CPU is only capable of updating 4 LCDs worth of data every second because there's just too much data to update. Of course the LCD driver might be at cause too, but since the CPU is too slow for the large LCD itself to begin with, it barely makes a difference. On the older models, there is barely any data to send to the LCD so yes the slow LCD driver can make a noticeable difference. It's possible that the CSE has no LCD driver delay, though.I think DrDnar once posted the t-states calculations showing the max possible frame rate on the CSE. Kerm's ball program also demonstrates how slow it can be by changing the entire LCD color before the ball animation starts.EDIT: Ok I found it: http://ourl.ca/18368/338852Quote from: DrDnarMore technically, the controller only accepts 16- or 18-bit color, meaning 2 to 3 writes per pixel. Outputting a single pixel takes at least 29 clock cycles (for filling the screen with a single color). By contrast, the old controller needed about 100 clock cycles per write, but each write could send 8 pixels, so each pixel only averaged 12 clock cycles. So it takes three times as long to write a single pixel (if you want actual graphics), and the screen has 12.5 times as many pixels. The old controller can accept 120 96x64 frames per second (but it only displays at 60 fps); the new one, displaying only a shrunken 96x64 subsection, can only manage 60 fps. So, the maximum frame rate for full-screen display is 7 fps (0.15 sec/frame), and that's only possible if you're filling the screen with a single color. In practice, 5-6 fps (about 0.2 s/f) is the best you can possibly get for full screen graphics.woah woah.why would they put a slow cpu to run a bigger screen?
Because TI-CARESTM.Anyway, as anyone who has seen a TI calculator at full retail price can attest to, TI wants to squeeze as much of our money as they can while also increasing their own profits. Look at the TI-84+, it used to come with extra Flash but then TI cut it to save ~$0.05. Still confused?[xkcd=768]Explained[/xkcd]
I know this topic is SO old, but do you think anyone could assist pulling together a TI 83+ emu for nspire?