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Posted by Ncfan
 - May 17, 2020, 23:57:18
Hello, when will you test i5-1038NG7? Thanks
Posted by S.Yu
 - May 17, 2020, 14:24:27
Quote from: Philip on May 16, 2020, 19:57:35
The verge has MacBook pro 13 outperforming Dell XPS 2-in-1 and surface laptop 3: www.theverge.com/2020/5/7/21249966/apple-13-inch-macbook-pro-magic-keyboard-performance-video-premiere-affinity
By all accounts Dell's XPS13 2-in-1 does allow a stable 25W, so the reported difference is far greater than reasonable. Maybe there's a difference in the way Premiere is compiled between Windows and MacOS, anyhow a single app that's not even a benchmark is not a reliable indicator.
Posted by KPOM
 - May 17, 2020, 05:50:43
This is clickbait. Apple's 28W chips have long been slightly souped up versions of the 15W chips (which really top out at 25W). But even MaxTech (which started the whole "overheating" controversy) noted that in its tests the Ice Lake i5 MacBook Pro outperformed the Dell XPS 13 i7-1065G7.
Posted by Philip
 - May 16, 2020, 19:57:35
The verge has MacBook pro 13 outperforming Dell XPS 2-in-1 and surface laptop 3: www.theverge.com/2020/5/7/21249966/apple-13-inch-macbook-pro-magic-keyboard-performance-video-premiere-affinity
Posted by Valantar
 - May 16, 2020, 18:56:06
Quote from: _MT_ on May 16, 2020, 11:17:10
What did you expect? We all know that the chips are not running at TDP. And that they tend to be thermally limited. Higher TDP simply means higher base frequency. But nobody is benchmarking them at base frequencies. At best, Apple might be getting a high bin silicon (perhaps the highest bin). Laptop's design is the important variable. This applies in general to processors in the same line with the same core count. At best, the more expensive model is higher bin (putting aside cache size and such). Meaning more efficient. And that's the only difference that matters if you're thermally limited. With given efficiency, frequency (and therefore performance) is a function of cooling. Up to a power limit. Higher power limit only matters if the cooling can take you there. And the performance is going to come at the cost of more heat and therefore potentially more noise. Cooling really is perhaps the biggest feature in a laptop. When it comes to performance.

You might infer that usage of a higher TDP chip means better cooling. As TDP should guide cooler selection. But that just might be a wishful thinking. And you don't need a higher TDP chip to make use of cooling headroom. That's what boost is about. And the 28 W version has only 100 MHz higher boost IIRC. Negligible.
You're absolutely right, but in previous generations when chips haven't been pushed quite as far, the difference between, say, an i5 and an i7 in the same thermal envelope has tended to be that the i7 is slightly higher clocked, slightly more efficient, but also allowed to pull slightly more power. Of course this relies on the cooling system being more than simply adequate, which is increasingly rare with the ongoing quest for making laptops so thin they become transparent (at least it seems like that's the goal). Now, instead of this system - which actually worked! - we have chips boosting to many times TDP for short periods (which is a good thing overall, but stresses cooling severely), increasingly underbuilt cooling, and far more leeway for OEMs to configure chips thermally (often to the detriment of the laptop). Thus we end up with i5s outperforming i7s as the latter enters a thermal throttling loop with the former stabilizing at a higher average performance level, and even "28W" chips not beating "15W" chips (that might be configured to 25W, though nobody will tell you) as cooling is limiting the chip from actually consuming its TDP in steady-state. It's all quite frustrating really.
Posted by S.Yu
 - May 16, 2020, 17:10:42
Quote from: Tov on May 15, 2020, 17:07:23
I understand they can't use Renoir because upcoming ARM power chip won't surpass it. Keeping Intel with low power making future ARM look better at how many times CPU and GPU they will be stronger.
Seriously? They're messing up this gen to sell next gen? I honestly don't think I've ever come across a case in which a company plays its cards like this.
Quote from: JMac on May 16, 2020, 04:30:44
You realise those other ice lake CPUs are also running at around 25 W too right?
Some are 25W(like my XPS13 2-in-1, one of the reasons I bought it is a stable boost, far better than for example the SP with the same chip, which also happens to be more expensive), others are really 15W. Anyhow, there should still be a slight difference between 28W and 25W if properly implemented, especially since Apple's likely getting a good bin.
Posted by _MT_
 - May 16, 2020, 11:24:06
Quote from: Valantar on May 15, 2020, 14:46:04
Not hitting peak boost whatsoever is a serious issue - I would say grounds for a recall, frankly.
As long as it's only because of insufficient cooling (or because the manufacturer chose to impose a stricter power limit), it's not Intel's fault. And good luck trying to get the manufacturer to recall the laptop. I generally ignore advertising so I don't know what promises they make. But I wouldn't hold my breath.
Posted by _MT_
 - May 16, 2020, 11:17:10
What did you expect? We all know that the chips are not running at TDP. And that they tend to be thermally limited. Higher TDP simply means higher base frequency. But nobody is benchmarking them at base frequencies. At best, Apple might be getting a high bin silicon (perhaps the highest bin). Laptop's design is the important variable. This applies in general to processors in the same line with the same core count. At best, the more expensive model is higher bin (putting aside cache size and such). Meaning more efficient. And that's the only difference that matters if you're thermally limited. With given efficiency, frequency (and therefore performance) is a function of cooling. Up to a power limit. Higher power limit only matters if the cooling can take you there. And the performance is going to come at the cost of more heat and therefore potentially more noise. Cooling really is perhaps the biggest feature in a laptop. When it comes to performance.

You might infer that usage of a higher TDP chip means better cooling. As TDP should guide cooler selection. But that just might be a wishful thinking. And you don't need a higher TDP chip to make use of cooling headroom. That's what boost is about. And the 28 W version has only 100 MHz higher boost IIRC. Negligible.
Posted by Turbocharge
 - May 16, 2020, 10:35:55
JMac: you mean it's 15W running at base clock and 25W with tBoost?
Posted by JMac
 - May 16, 2020, 04:30:44
You realise those other ice lake CPUs are also running at around 25 W too right?
Posted by Mission
 - May 16, 2020, 04:17:55
True. www.MissionQuest.org
Posted by william blake
 - May 15, 2020, 19:20:09
Quote@rogame asserts that top-tier Tiger Lake-U processors may offer up to a 40% CPU and GPU performance uplift over the Core i5-1038NG7
oh really? same power, same node, +40% performance?
Posted by Spunjji
 - May 15, 2020, 17:56:58
Looking forward to a fair and balanced meltdown from the popular tech press on these chips (and Comet Lake) failing to reach their boost clocks.

Any day now.
Posted by Tov
 - May 15, 2020, 17:07:23
I understand they can't use Renoir because upcoming ARM power chip won't surpass it. Keeping Intel with low power making future ARM look better at how many times CPU and GPU they will be stronger.
Posted by Valantar
 - May 15, 2020, 14:46:04
Not hitting peak boost whatsoever is a serious issue - I would say grounds for a recall, frankly. Even AMD's early Ryzen 3000 with the shitty BIOS managed to hit those boost levels even for tiny tiny amounts of time - and of course the subsequent BIOS fix removed the issue altogether.

On the other hand I wonder how sustained performance plays out - the higher TDP (and hopefully matching cooling system) ought to make for less throttling over time than 15W SKUs. Fire Strike is by no means a long enough test to demonstrate this, so I guess we'll see once NBC gets these laptops in for proper testing.