Would you like to inspect the original subtitles? These are the user uploaded subtitles that are being translated: 0 00:00:00,300 --> 00:00:03,303 The 12th generation Core two years ago left a deep impression on us. 1 00:00:03,303 --> 00:00:05,555 The large and small cores introduced for the first time on the x86 platform 2 00:00:05,555 --> 00:00:08,274 , the greatly improved IPC and the excellent video codec 3 00:00:08,274 --> 00:00:10,810 all opened up a considerable generation gap between it and its predecessors. 4 00:00:10,910 --> 00:00:14,714 Today’s 14th generation Desktop Core is still a direct relative of the 12th generation. 5 00:00:14,714 --> 00:00:16,516 For desktops and game notebooks, 6 00:00:16,516 --> 00:00:18,501 the performance of the 12th generation is still good, 7 00:00:18,501 --> 00:00:22,389 but for thin and light notebooks and all-round notebooks, it is miserable. The 8 00:00:22,389 --> 00:00:28,094 battery life performance of the 12th and 13th generations has become the best among Intel notebooks. A shortcoming: 9 00:00:28,094 --> 00:00:30,747 We have talked about the battery life issue of x86 platform notebooks before. 10 00:00:30,897 --> 00:00:33,900 The current mobile CPUs have basically been SoC-based, 11 00:00:33,900 --> 00:00:35,952 so in addition to the energy consumption ratio of the CPU core, 12 00:00:36,102 --> 00:00:38,938 the energy consumption performance of the parts outside the core will also affect the battery life 13 00:00:38,938 --> 00:00:42,242 , especially the average CPU load. Reducing the continuous power consumption outside the core is very important for battery life 14 00:00:42,392 --> 00:00:45,545 in low-level daily applications. 15 00:00:45,645 --> 00:00:47,530 The Intel Core Ultra processor we are going to test today 16 00:00:47,530 --> 00:00:49,549 is designed to solve this problem. 17 00:00:49,549 --> 00:00:51,351 Can it avenge its shame and 18 00:00:51,351 --> 00:00:55,055 improve the battery life of Intel laptops ? What is the level of response? 19 00:00:55,055 --> 00:00:56,756 Before the official test begins, 20 00:00:56,756 --> 00:00:59,909 let’s briefly talk about the architecture of Core Ultra. 21 00:00:59,959 --> 00:01:03,430 Because it is very new, this part will be longer. 22 00:01:03,430 --> 00:01:05,765 If you want to see the performance test directly, you 23 00:01:05,765 --> 00:01:07,667 can jump here. 24 00:01:08,184 --> 00:01:13,206 Core Ultra is Intel’s complete restart of the product after the Core i series. From the perspective of 25 00:01:13,206 --> 00:01:14,858 26 00:01:14,858 --> 00:01:18,428 the overall structure of the SoC, it should be the biggest structural change since the 2nd generation Core i series 27 00:01:18,561 --> 00:01:22,132 . In fact, modern processors have long been more than just a simple CPU. 28 00:01:22,298 --> 00:01:26,603 SoC-based processors include CPUs and GPUs. , memory controller 29 00:01:26,603 --> 00:01:32,108 , IO controller, media engine, AI acceleration unit, etc. There are a lot of things 30 00:01:32,108 --> 00:01:36,062 , and the area of these units is no smaller than the CPU itself. 31 00:01:36,062 --> 00:01:38,231 For example, this is the Dieshot of Apple M3 32 00:01:38,231 --> 00:01:41,234 . Look at how much 33 00:01:41,234 --> 00:01:42,769 chip area the CPU takes up. What? 34 00:01:42,769 --> 00:01:44,204 Area is money! 35 00:01:44,204 --> 00:01:48,858 A larger area means that one wafer can cut fewer processors and the yield rate is lower. 36 00:01:48,858 --> 00:01:52,612 Not every area in an SoC requires the most advanced technology 37 00:01:52,612 --> 00:01:54,214 , so in order to save costs, 38 00:01:54,214 --> 00:01:55,632 each company has used a secret weapon. 39 00:01:55,632 --> 00:01:58,668 For example, AMD made the CPU into a CCD 40 00:01:58,718 --> 00:02:02,822 and other things separately to make an IOD. 41 00:02:02,822 --> 00:02:04,757 The CCD was produced using advanced technology. 42 00:02:04,757 --> 00:02:07,127 The IOD was produced using mature technology 43 00:02:07,127 --> 00:02:09,662 and then placed on the same substrate 44 00:02:09,662 --> 00:02:12,265 . This not only reduces the cost of advanced technology, 45 00:02:12,265 --> 00:02:16,319 but also because of the chiplet. The small area brought about improves the yield rate. 46 00:02:16,369 --> 00:02:20,106 It can be said that this design laid the foundation for the success of Zen2 47 00:02:20,106 --> 00:02:22,308 , but it also brings some problems 48 00:02:22,308 --> 00:02:25,762 . On the one hand, the chiplet design will cause multiple heat sources in the chip 49 00:02:25,762 --> 00:02:27,730 , and the area of each heat source is large. Relatively small 50 00:02:27,831 --> 00:02:30,216 , which may lead to "heat accumulation" problems. 51 00:02:30,216 --> 00:02:33,269 On the other hand, longer distances mean higher delays. 52 00:02:33,369 --> 00:02:37,223 The communication delay between CCDs or between CCDs and IODs will be relatively high. 53 00:02:37,223 --> 00:02:38,708 In order to solve this problem, 54 00:02:38,708 --> 00:02:41,911 Intel will also start to improve the "packaging process". "Get started 55 00:02:41,911 --> 00:02:45,431 , and Core Ultra is the first mature application of this technology. If you 56 00:02:45,431 --> 00:02:47,066 look closely at Meteor Lake's DIE, 57 00:02:47,066 --> 00:02:50,703 you will find that it is actually composed of small chips. 58 00:02:50,703 --> 00:02:55,225 These small chips are closely combined to form a large DIE 59 00:02:55,225 --> 00:02:56,609 . Intel calls each small piece of chip 60 00:02:56,609 --> 00:02:58,127 a Tile. 61 00:02:58,127 --> 00:02:59,162 You would never guess that 62 00:02:59,162 --> 00:03:01,915 these Tiles use different processes. 63 00:03:01,965 --> 00:03:03,433 I made a schematic diagram here. 64 00:03:03,433 --> 00:03:05,969 The CPU part uses Intel 4 65 00:03:06,102 --> 00:03:08,421 and the GPU part uses TSMC N5. 66 00:03:08,421 --> 00:03:11,624 Obviously these two areas The IO and SOC parts that require the most advanced processes 67 00:03:11,624 --> 00:03:14,460 use TSMC N6, which 68 00:03:14,460 --> 00:03:17,030 can reduce some costs while ensuring performance. 69 00:03:17,063 --> 00:03:21,634 The most interesting thing is that these small chips are not connected through a substrate like other companies. 70 00:03:21,634 --> 00:03:27,457 They are directly under these Tiles. A Base Die was made using the 22nm process 71 00:03:27,457 --> 00:03:28,458 to connect them, and 72 00:03:28,625 --> 00:03:31,027 one chip was used as the substrate. 73 00:03:31,027 --> 00:03:33,713 These fabs really do whatever they want! 74 00:03:33,830 --> 00:03:35,548 Connecting through such a Base Die 75 00:03:35,548 --> 00:03:39,469 should have higher bandwidth and lower latency than connecting through the substrate. 76 00:03:39,469 --> 00:03:42,305 Its technical principle is similar to that of 3D cache 77 00:03:42,305 --> 00:03:45,708 . Except that it is expensive, it is indeed an extremely advanced idea. 78 00:03:45,909 --> 00:03:50,463 These modular Tiles are put together like a jigsaw puzzle. into a complete SoC 79 00:03:50,463 --> 00:03:53,766 and then completely polished it through a unified packaging process. 80 00:03:53,917 --> 00:03:56,819 Let’s expand it to see what these Tiles are. 81 00:03:56,819 --> 00:03:58,204 First of all, the CPU part 82 00:03:58,204 --> 00:04:02,508 Compute Tile contains the Redwood Cove large core + Crestmont small core. 83 00:04:02,508 --> 00:04:04,928 The overall architecture of the core has changed very little. 84 00:04:05,011 --> 00:04:07,530 Basically, the design from the 12th generation is still used. 85 00:04:07,563 --> 00:04:09,265 The IPC of the small core will be slightly improved. 86 00:04:09,265 --> 00:04:10,817 It will still have 4 small cores in a cluster. 87 00:04:10,817 --> 00:04:13,169 The full blood specifications are still 6P+8E 88 00:04:13,169 --> 00:04:16,256 . In addition, this time the large core is actually divided into applications like the mobile phone SoC. 89 00:04:16,256 --> 00:04:19,559 There are 2 cores in the performance library and 4 cores in the application density library 90 00:04:19,559 --> 00:04:22,362 , which means that two of them are "super large cores". 91 00:04:22,362 --> 00:04:25,932 On Ultra 7 and Ultra 9, when all cores are fully loaded, 92 00:04:25,932 --> 00:04:27,634 they will run to a higher frequency. 93 00:04:27,634 --> 00:04:28,635 In addition to these 94 00:04:28,635 --> 00:04:31,354 , the CPU part also adds two extra small cores 95 00:04:31,354 --> 00:04:33,856 , but they are not in the Compute Tile 96 00:04:33,856 --> 00:04:35,758 but integrated in the SoC Tile 97 00:04:35,758 --> 00:04:38,811 . The architecture of an ultra-small core 98 00:04:38,811 --> 00:04:41,047 is basically the same as that of a small core. It mainly has a smaller cache and lower frequency. 99 00:04:41,047 --> 00:04:43,433 The most important thing is that it is in the SoC Tile, 100 00:04:43,433 --> 00:04:48,454 which means that it does not need to call the ring bus in the Compute Tile when it starts. 101 00:04:48,454 --> 00:04:52,525 In other words, Meteor Lake can directly turn off Compute Tile in some scenarios 102 00:04:52,525 --> 00:04:56,062 , which can greatly reduce the power consumption in these scenarios. 103 00:04:56,062 --> 00:04:59,432 We will also run SPEC2017 of these cores separately later to see 104 00:04:59,432 --> 00:05:02,035 whether the core architecture has been improved. 105 00:05:02,035 --> 00:05:04,654 Let’s see how the ultra-small core performs. Next 106 00:05:05,004 --> 00:05:06,456 , let’s take a look at the GPU. 107 00:05:06,456 --> 00:05:09,125 The GPU architecture this time is called Xe-LPG. 108 00:05:09,258 --> 00:05:13,112 You can understand it as a streamlined 109 00:05:13,262 --> 00:05:15,665 version of the A770’s Xe-HPG. It mainly simplifies the XMX unit 110 00:05:15,765 --> 00:05:18,117 . After all, Meteor Lake has an NPU. 111 00:05:18,117 --> 00:05:21,454 The XMX unit seems a bit unnecessary. 112 00:05:21,454 --> 00:05:24,424 As for other functions such as ray tracing, they are still 113 00:05:24,524 --> 00:05:25,325 in the specification 114 00:05:25,408 --> 00:05:27,010 . Full HP is 128EU. 115 00:05:27,010 --> 00:05:29,362 I am very much looking forward to the performance of the core display performance this time. 116 00:05:29,579 --> 00:05:32,332 This should be the highlight of Meteor Lake. 117 00:05:32,498 --> 00:05:34,117 There is another interesting thing 118 00:05:34,117 --> 00:05:40,023 in the GPU. The display part and media engine part have been moved from GT Tiles to SOC Tile. 119 00:05:40,023 --> 00:05:43,026 The core display media engine has always been a very important part 120 00:05:43,026 --> 00:05:44,861 , especially for video workers, 121 00:05:44,911 --> 00:05:48,965 the core display media engine can effectively accelerate the efficiency of video editing. 122 00:05:48,965 --> 00:05:50,917 This time the media engine It is also stronger 123 00:05:50,917 --> 00:05:52,869 and has added support for the AV1 format. 124 00:05:52,919 --> 00:05:55,221 We will also take a look at its performance later. 125 00:05:55,221 --> 00:05:57,006 In addition to the CPU and GPU, 126 00:05:57,006 --> 00:06:00,109 there is an important new member this time - NPU. 127 00:06:00,109 --> 00:06:02,862 The NPU is located in the SoC Tile. 128 00:06:02,862 --> 00:06:05,865 You can already I saw it in the Windows Task Manager 129 00:06:05,865 --> 00:06:08,034 . Of course, it can run Stable Diffusion 130 00:06:08,034 --> 00:06:10,803 and various AIGC applications that are compatible with OpenVINO 131 00:06:10,803 --> 00:06:15,041 . But its focus is more on energy consumption ratio rather than absolute performance 132 00:06:15,041 --> 00:06:18,745 . Therefore, currently these tasks are mainly focused on The main task of the NPU on the GPU 133 00:06:18,745 --> 00:06:22,615 is to do 134 00:06:22,615 --> 00:06:25,985 applications such as AI keying, video super-resolution, or motion capture. 135 00:06:25,985 --> 00:06:27,787 In addition, from the entry-level to the flagship 136 00:06:27,787 --> 00:06:30,373 NPU, they are exactly the same, without emasculating 137 00:06:30,373 --> 00:06:34,977 the CPU, GPU, NPU, and adding new ones. SoC Tile and IO Tile 138 00:06:34,977 --> 00:06:37,513 constitute the new Meteor Lake processor. 139 00:06:37,513 --> 00:06:40,600 This modular design allows chips of different specifications to 140 00:06:40,600 --> 00:06:44,087 be flexibly matched with different CPUs, GPUs and IO Tiles 141 00:06:44,087 --> 00:06:46,272 , but the delay and bus bandwidth are controllable 142 00:06:46,272 --> 00:06:49,575 , and CPU, GPU and NPU can be used. Completing AI computing 143 00:06:49,575 --> 00:06:51,461 is also the design focus of this generation 144 00:06:51,461 --> 00:06:53,913 . From a conceptual point of view, it is quite advanced. 145 00:06:54,280 --> 00:06:56,265 Welcome back. After talking about the architecture, 146 00:06:56,265 --> 00:06:58,468 I believe everyone is curious about 147 00:06:58,468 --> 00:07:00,703 the performance of Meteor Lake. What 148 00:07:00,703 --> 00:07:05,908 we are testing this time is a 2024 Lenovo. Xiaoxin Pro16 149 00:07:05,908 --> 00:07:07,810 is a 16-inch all-round notebook. 150 00:07:07,860 --> 00:07:11,681 It is equipped with Ultra 5 125H processor, 151 00:07:11,764 --> 00:07:14,567 32G LPDDR5x 7467 memory. 152 00:07:14,567 --> 00:07:17,053 Compared with the previous generation 2024 Xiaoxin Pro16, 153 00:07:17,053 --> 00:07:20,022 the battery has been increased from 75Wh to 84Wh. 154 00:07:20,173 --> 00:07:23,709 We will also test it with the new one. What is the battery life of the processor? 155 00:07:23,709 --> 00:07:24,310 For comparison, 156 00:07:24,310 --> 00:07:27,063 I bought two more 157 00:07:27,063 --> 00:07:30,483 Xiaoxin Pro 16 equipped with i5 13500H and Ryzen 7 7840HS processors 158 00:07:30,483 --> 00:07:33,119 respectively . Although Ultra 7 and Ultra 9 were not tested, 159 00:07:33,269 --> 00:07:35,822 Ultra 5 is also the next main shipping model. 160 00:07:36,022 --> 00:07:37,273 Let’s briefly review the specifications of 161 00:07:37,273 --> 00:07:40,026 4 There are 8 small cores plus 2 ultra-small cores. The 162 00:07:40,026 --> 00:07:43,246 single-core turbo frequency is 0.2GHz lower than the previous generation’s 4.7GHz. 163 00:07:43,246 --> 00:07:46,265 The GPU’s 112EU Intel Arc core display is 164 00:07:46,265 --> 00:07:49,018 slightly lower than the full-blooded 128EU 165 00:07:49,318 --> 00:07:52,788 . So first, please take our SPEC2017 test 166 00:07:52,788 --> 00:07:54,073 as the industry standard. Testing 167 00:07:54,073 --> 00:07:57,360 it can tell us whether its single-core performance has really improved 168 00:07:57,360 --> 00:08:00,112 and what exactly its ultra-small core is. 169 00:08:00,630 --> 00:08:02,165 In SPEC2017, 170 00:08:02,165 --> 00:08:08,671 the large-core performance of the Core Ultra 5 125H is obviously not as strong 171 00:08:08,671 --> 00:08:14,260 as the previous generation i5 13500H. After all, the previous generation 4.7GHz The core frequency is a bit higher than the 4.4-4.5 of this generation, 172 00:08:14,460 --> 00:08:16,312 and the IPC has basically not improved. 173 00:08:16,412 --> 00:08:18,064 This performance is not surprising. 174 00:08:18,414 --> 00:08:19,182 At the same time 175 00:08:19,182 --> 00:08:23,069 , it cannot beat the Zen 4 7840HS, which has a lower IPC. 176 00:08:23,219 --> 00:08:25,821 After all, although the same frequency performance is slightly It is weak 177 00:08:25,821 --> 00:08:28,524 , but a single core can run up to 5.0 under PBO. 178 00:08:28,591 --> 00:08:30,977 This frequency gap is really difficult to make up for 179 00:08:31,177 --> 00:08:34,580 the performance of this large core. Compared with the Apple M3, which has a much higher IPC, 180 00:08:34,580 --> 00:08:35,815 the gap is even greater. The performance of 125H 181 00:08:35,815 --> 00:08:36,465 on small cores 182 00:08:36,465 --> 00:08:40,169 is still significantly higher than 13500H. 183 00:08:40,169 --> 00:08:44,223 The leading margin is also larger than the 0.1GHz difference in frequency, 184 00:08:44,223 --> 00:08:47,476 which shows that the IPC of the small core should be improved. 185 00:08:47,476 --> 00:08:50,379 In order to further compare whether the same-frequency performance has been improved, 186 00:08:50,379 --> 00:08:57,887 I used 14900K to run the same large core 4.4 small core 3.6 memory 187 00:08:58,020 --> 00:09:00,122 as the 125H. Running 6400G4 188 00:09:00,122 --> 00:09:04,060 to roughly compare the performance of Meteor Lake and Raptor Lake at the same frequency, 189 00:09:04,060 --> 00:09:04,810 it is not difficult to see that 190 00:09:04,810 --> 00:09:08,481 the large core score of 125H is lower than that of the 14900K at the same frequency 191 00:09:08,481 --> 00:09:11,617 . Could it be that the IPC of Core Ultra sucks? 192 00:09:11,617 --> 00:09:18,874 This is mainly because the bus performance, cache performance, etc. of desktop CPUs will be higher. The 193 00:09:19,025 --> 00:09:21,310 core IPC should not have changed. 194 00:09:21,310 --> 00:09:22,678 After all, the architecture has not changed. However 195 00:09:23,012 --> 00:09:24,780 , there has been an obvious change in 196 00:09:24,780 --> 00:09:26,966 the small core. The performance of the small core is 197 00:09:26,966 --> 00:09:30,069 even worse when the peripheral components are worse. It is higher than Raptor Lake at the same frequency. 198 00:09:30,069 --> 00:09:34,190 It seems that the official IPC improvement 199 00:09:34,190 --> 00:09:37,643 of the small core is not deceiving. The performance of this small core is also much better than the small core of M3. 200 00:09:37,643 --> 00:09:40,613 Finally, let’s take a look at the newly introduced ultra-small core. 201 00:09:40,613 --> 00:09:42,615 Judging from the SPEC2017 results, 202 00:09:42,615 --> 00:09:46,218 this 2.5GHz small core is not very weak. 203 00:09:46,218 --> 00:09:48,921 Its performance is close to the M3 small core. 204 00:09:48,921 --> 00:09:52,825 If you want to compare it with ARM’s true small core A520 205 00:09:52,825 --> 00:09:54,910 , this one can beat it. Three cores 206 00:09:54,910 --> 00:09:56,462 are not a competitor of the same magnitude 207 00:09:56,462 --> 00:09:57,613 , but in the subsequent tests, 208 00:09:57,663 --> 00:10:02,168 you may be confused about the scheduling strategy of Intel's ultra-small cores like me. 209 00:10:02,168 --> 00:10:05,087 Because there are almost no places to use them, 210 00:10:05,271 --> 00:10:07,189 I also ran an inter-core delay test. 211 00:10:07,189 --> 00:10:11,177 After all, this The physical location of the sub-ultra-small core is completely separate from other parts of the CPU. 212 00:10:11,177 --> 00:10:12,211 As a result, 213 00:10:12,211 --> 00:10:14,513 the delay of this ultra-small core is indeed relatively high 214 00:10:14,513 --> 00:10:17,583 and close to the delay between Apple M series clusters. 215 00:10:17,583 --> 00:10:18,668 Surprisingly, it is 216 00:10:18,668 --> 00:10:22,321 between other cores of the CPU. The latency is also higher than that of Raptor Lake. 217 00:10:22,321 --> 00:10:25,591 I don’t know if the performance of Ring has been reduced to save energy. 218 00:10:25,591 --> 00:10:29,211 Let’s briefly summarize the performance of each CPU core. 219 00:10:29,211 --> 00:10:34,016 The large-core co-frequency performance of Meteor Lake is almost the same as Raptor Lake. 220 00:10:34,116 --> 00:10:36,285 The small-core co-frequency performance has been slightly improved. 221 00:10:36,319 --> 00:10:39,271 As for ultra-small cores, because IPC and small cores are basically the same, 222 00:10:39,271 --> 00:10:42,074 the main reason is the performance gap caused by the frequency difference. 223 00:10:42,074 --> 00:10:42,575 Next 224 00:10:42,575 --> 00:10:45,878 , we asked Cinebench R23, which can run at full CPU 225 00:10:45,911 --> 00:10:51,784 , to see their multi-core performance and performance under full-core full load. Let’s compare the performance. 226 00:10:51,784 --> 00:10:53,786 The first is the performance under the default power wall. 227 00:10:53,786 --> 00:10:55,271 Under the default power wall, 228 00:10:55,271 --> 00:10:56,022 it is a pity that 229 00:10:56,022 --> 00:11:02,511 the Ultra 5 125H with a multi-core score of 70W cannot beat the previous generation i5 13500H, 230 00:11:02,511 --> 00:11:06,882 let alone the 8 large-core Ryzen 7. In terms of single-core results of 7840HS 231 00:11:06,882 --> 00:11:10,069 , similar to the results of SPEC2017, 232 00:11:10,069 --> 00:11:12,788 the 7840HS with PBO is still the strongest 233 00:11:12,788 --> 00:11:16,776 Ultra 5 125H frequency. 234 00:11:16,776 --> 00:11:18,561 Next, let’s control the power consumption wall 235 00:11:18,561 --> 00:11:22,581 to see what the energy consumption performance of Core Ultra’s CPU is. No improvement, 236 00:11:22,581 --> 00:11:24,684 how can I say this result... 237 00:11:24,684 --> 00:11:26,752 There is indeed an improvement 238 00:11:26,752 --> 00:11:30,272 , but the improvement is really small. 239 00:11:30,272 --> 00:11:31,724 Because of the disadvantage in the number of large cores, 240 00:11:31,724 --> 00:11:34,677 it cannot get any advantage in front of the 7840HS 241 00:11:34,677 --> 00:11:36,579 . If you look at this chart carefully, 242 00:11:36,579 --> 00:11:37,880 you will find that A strange thing is 243 00:11:38,114 --> 00:11:40,266 that when the power consumption wall is lower than 28W, 244 00:11:40,316 --> 00:11:44,320 why is the 13500H even more powerful than the Ultra 5 125H? 245 00:11:44,520 --> 00:11:46,789 So I set the power consumption wall at 15W 246 00:11:46,789 --> 00:11:49,191 to observe the frequency strategy under 15W 247 00:11:49,275 --> 00:11:51,510 . Something outrageous happened. 248 00:11:51,510 --> 00:11:54,463 The small core was actually downclocked to 1.2GHz 249 00:11:54,463 --> 00:11:57,867 , while the large core ran at 1.5-1.6GHz? 250 00:11:57,967 --> 00:11:59,518 What kind of scheduling strategy is this? 251 00:11:59,585 --> 00:12:02,271 Generally speaking, if you want to improve the energy consumption ratio, 252 00:12:02,271 --> 00:12:06,976 you must try your best to let the small cores output more performance when the power consumption is insufficient, 253 00:12:06,976 --> 00:12:09,478 so that the big cores can avoid the edge and lower the point. The frequency is used to run 254 00:12:09,478 --> 00:12:12,181 Apple's low-power mode, which is exactly this idea. 255 00:12:12,181 --> 00:12:14,383 However, I can't understand Intel's idea. 256 00:12:14,417 --> 00:12:17,620 Four big cores are desperately sucking blood, and the small core frequency is extremely low. 257 00:12:17,787 --> 00:12:20,990 In this case, it is strange that the performance can be good! 258 00:12:20,990 --> 00:12:25,611 Moreover, the energy consumption performance of the first generation Intel 4 product did not meet my expectations. 259 00:12:25,611 --> 00:12:26,312 Generally speaking, 260 00:12:26,312 --> 00:12:29,064 I think the performance of the CPU part is only unsatisfactory 261 00:12:29,115 --> 00:12:31,383 and has not reached the improvement I expected. 262 00:12:31,383 --> 00:12:34,587 After reading the CPU energy efficiency, it is somewhat disappointing. Let’s take a look at 263 00:12:34,587 --> 00:12:36,021 the performance of the GPU 264 00:12:36,222 --> 00:12:38,190 compared to the CPU that has not been significantly changed. 265 00:12:38,190 --> 00:12:41,677 The GPU can be said to be completely reborn this time. 266 00:12:41,677 --> 00:12:43,612 In the 3Dmark Time Spy GPU test 267 00:12:43,612 --> 00:12:46,715 , even the Ultra 5 125H Arc GPU with residual blood 268 00:12:46,715 --> 00:12:51,687 completely surpassed it under the default power consumption wall. The performance of 780M compared to Ryzen 7 7840HS 269 00:12:51,687 --> 00:12:55,307 can be said to be the shame of Yixue Intel Core Display! 270 00:12:55,307 --> 00:12:56,976 Compared with the previous generation of Xe core display, 271 00:12:56,976 --> 00:12:59,578 the performance this time has even more than doubled. 272 00:12:59,578 --> 00:13:00,012 Of course, 273 00:13:00,012 --> 00:13:02,581 the power consumption limit this time is also higher than before. 274 00:13:02,581 --> 00:13:04,467 Basically, you will find that 275 00:13:04,467 --> 00:13:06,168 its performance has stabilized above 45W 276 00:13:06,168 --> 00:13:11,390 . The power consumption performance is actually relatively close to the 780M performance of the 7840HS, 277 00:13:11,390 --> 00:13:13,676 while the core display specifications of the previous generation are much smaller. 278 00:13:13,676 --> 00:13:16,712 The 25W power consumption wall is almost full. 279 00:13:16,712 --> 00:13:20,015 This GPU 280 00:13:20,065 --> 00:13:21,867 is indeed larger than the previous generation. However, there is one thing that surprised me. 281 00:13:21,867 --> 00:13:23,519 It is within 15W. 282 00:13:23,519 --> 00:13:29,024 The GPU scores of some Ultra 5 125H are lower than the 780M of 7840HS 283 00:13:29,074 --> 00:13:30,659 . It seems that 284 00:13:30,659 --> 00:13:32,595 this GPU is still too big for handheld use 285 00:13:32,595 --> 00:13:36,365 . However, the next U series is the model 286 00:13:36,415 --> 00:13:40,619 H series developed for this low-power platform. It is also mostly installed in models with 28W or above. 287 00:13:40,636 --> 00:13:42,872 This performance is not surprising. 288 00:13:43,322 --> 00:13:45,224 Let’s briefly summarize the results of the theoretical test. 289 00:13:45,324 --> 00:13:48,410 The performance of Meteor Lake’s CPU part is not surprising 290 00:13:48,410 --> 00:13:51,614 . The large core IPC has not improved, and the frequency is lower than the previous generation. 291 00:13:51,764 --> 00:13:54,233 The small core IPC has improved, and performance has improved 292 00:13:54,366 --> 00:13:57,069 . In terms of energy efficiency, there has been a slight improvement in mid- and high-frequency energy efficiency. 293 00:13:57,236 --> 00:14:00,239 Low-frequency performance is not normal due to the scheduling strategy. 294 00:14:00,523 --> 00:14:01,373 The GPU part of 295 00:14:01,373 --> 00:14:04,610 Meteor Lake has greatly improved compared to the previous generation. 296 00:14:04,610 --> 00:14:07,930 The performance in Time Spy has slightly surpassed the 7840HS, and 297 00:14:07,963 --> 00:14:08,831 the performance is good 298 00:14:08,964 --> 00:14:10,015 . After finishing the theoretical performance, 299 00:14:10,015 --> 00:14:13,369 let’s take a look at the performance of Meteor Lake in practical applications. 300 00:14:13,536 --> 00:14:15,371 The first is Cinebench 2024. 301 00:14:15,538 --> 00:14:17,039 In Cinebench 2024, 302 00:14:17,039 --> 00:14:20,276 the multi-core score of Ultra 5 125H is slightly better than 13500H. 303 00:14:20,526 --> 00:14:24,496 This may be because the memory frequency of this generation is as high as 7467MHz. 304 00:14:24,496 --> 00:14:27,766 Cinebench 2024 requires memory performance. It is relatively high 305 00:14:27,883 --> 00:14:32,238 , but there is still some gap between it and the 8-core 7840HS. 306 00:14:32,238 --> 00:14:33,372 In terms of single-core performance 307 00:14:33,372 --> 00:14:35,774 , because the maximum turbo frequency of the large core is lower this time, 308 00:14:35,774 --> 00:14:38,210 the result of 125H did not surprise me. 309 00:14:38,360 --> 00:14:41,564 Then look at the performance of another 3D software - Blender. In 310 00:14:41,714 --> 00:14:42,615 the CPU test, 311 00:14:42,615 --> 00:14:46,118 the Ultra 5 125H is between 13500H and 7840HS, 312 00:14:46,118 --> 00:14:47,620 slightly stronger than the 13500H. 313 00:14:47,620 --> 00:14:49,772 What surprises me is that the GPU 314 00:14:49,772 --> 00:14:52,625 does not support ray tracing because the previous generation Xe core display does not 315 00:14:52,625 --> 00:14:55,628 support it. Although Blender's GPU renderer 316 00:14:55,811 --> 00:14:58,113 7840HS supports light tracing 317 00:14:58,113 --> 00:15:01,033 , Blender's HIP renderer keeps reporting errors 318 00:15:01,033 --> 00:15:02,468 and cannot run the results. 319 00:15:02,568 --> 00:15:06,622 As a result, only Ultra 5 125H successfully ran the GPU results. 320 00:15:06,622 --> 00:15:08,240 It was a surprise. 321 00:15:08,240 --> 00:15:10,326 Then I tried Adobe's software 322 00:15:10,326 --> 00:15:13,028 PugetBench and updated them. The new version test. 323 00:15:13,028 --> 00:15:17,733 This test process is extremely painful 324 00:15:17,733 --> 00:15:19,852 , but fortunately we still finished the test. 325 00:15:19,852 --> 00:15:23,923 Currently, this test includes PS and PR projects. 326 00:15:23,923 --> 00:15:25,224 In Photoshop 2024, 327 00:15:25,224 --> 00:15:28,327 Ultra 5 125H is slightly stronger than 13500H 328 00:15:28,611 --> 00:15:30,629 , mainly because it is stronger in the Filter sub-item. 329 00:15:30,629 --> 00:15:32,765 The core display should play its role. It is not a small effect. 330 00:15:32,765 --> 00:15:36,035 The total score of 7840HS is higher than that of 125H. This 331 00:15:36,035 --> 00:15:38,821 is mainly due to the 8-core CPU, 332 00:15:38,821 --> 00:15:41,273 so the general sub-item score will be higher. 333 00:15:41,273 --> 00:15:42,441 Premiere Pro 334 00:15:42,441 --> 00:15:44,827 relies on the greatly enhanced core display performance 335 00:15:44,827 --> 00:15:51,216 of Ultra 5 125H. The total score of 16 Pro is significantly higher than the other two models. 336 00:15:51,216 --> 00:15:51,967 In the sub-items 337 00:15:51,967 --> 00:15:56,488 involving GPU performance, Intraframe and GPU Effects 338 00:15:56,488 --> 00:15:58,824 have significantly improved compared to the other two 339 00:15:58,841 --> 00:16:02,311 . It seems that the new core display has indeed brought it Considerable improvement. 340 00:16:02,311 --> 00:16:04,163 In the Media Encoder transcoding test, 341 00:16:04,163 --> 00:16:07,316 with its larger core display scale and enhanced codec, 342 00:16:07,316 --> 00:16:09,568 Ultra 5 125H also came out on top. 343 00:16:09,568 --> 00:16:13,272 If paired with a discrete graphics card, the lead would be even greater. 344 00:16:13,272 --> 00:16:17,276 Intel's media engine should be paired with a stronger GPU. It can also have greater potential. 345 00:16:17,860 --> 00:16:21,530 In the 7Zip compression and decompression test, the 125H is slightly ahead of the 13500H, 346 00:16:21,530 --> 00:16:25,317 but in the decompression test it still cannot beat the 8-core 7840HS. 347 00:16:25,317 --> 00:16:27,820 The DaVinci test results are similar to the PR 348 00:16:27,820 --> 00:16:31,573 of the Ultra 5 125H, relying on the substantial improvements in core display and media engine. The evolution 349 00:16:31,724 --> 00:16:35,427 has greatly surpassed i5 13500H and 7840HS . 350 00:16:35,427 --> 00:16:38,831 It seems that the new platform is very suitable for cutting videos. After 351 00:16:38,864 --> 00:16:40,966 completing the application test, it is not difficult to see that 352 00:16:40,966 --> 00:16:42,835 if it is a pure CPU load application, 353 00:16:42,835 --> 00:16:45,421 the improvement of Core Ultra compared to the previous generation is very limited 354 00:16:45,421 --> 00:16:47,239 , but as long as it is related to core display For applications 355 00:16:47,322 --> 00:16:49,174 such as video editing, the performance of 356 00:16:49,174 --> 00:16:51,410 Core Ultra has been greatly improved. 357 00:16:51,410 --> 00:16:54,346 This is also in line with the results of the previous theoretical test. 358 00:16:54,346 --> 00:16:56,832 We also briefly tested three games 359 00:16:56,832 --> 00:17:03,338 , namely the lightweight Genshin Impact, Iron Break and the high-pressure Cyberpunk 2077 360 00:17:03,338 --> 00:17:04,023 Original. The Arc core display of the Shenli 361 00:17:04,023 --> 00:17:07,026 125H is nearly doubled compared to the previous generation 362 00:17:07,026 --> 00:17:10,029 and exceeds the 780M core display on the 7840HS. 363 00:17:10,029 --> 00:17:15,167 The current generation of core display can already meet the performance requirements of 1080P high-definition 60fps. 364 00:17:15,167 --> 00:17:19,421 This performance is suitable for light gaming on business trips. It should be enough 365 00:17:19,438 --> 00:17:22,641 , and the power consumption during the test was not 366 00:17:22,641 --> 00:17:24,026 higher than the previous generation 367 00:17:24,026 --> 00:17:26,829 . This performance is still continued in Honkai Impact: Star Dome Railway 368 00:17:26,829 --> 00:17:31,934 . In Honkai Impact's 1080 low image quality, it can almost It reached 120fps. 369 00:17:31,934 --> 00:17:33,736 Even in 1080P high-definition, 370 00:17:33,736 --> 00:17:35,237 the average frame exceeded 60fps 371 00:17:35,237 --> 00:17:37,840 and reached an average of 74fps. 372 00:17:37,840 --> 00:17:41,326 Compared with the 27fps game experience of the previous generation, it was a qualitative leap. 373 00:17:41,360 --> 00:17:44,730 It also defeated the 780M core display of 7840HS 374 00:17:44,947 --> 00:17:47,433 and the Xe core display of the previous generation of 375 00:17:47,433 --> 00:17:51,920 2077. Playing 2077 sounds a bit funny 376 00:17:51,920 --> 00:17:55,040 , but the 125H core display is obviously much stronger than 377 00:17:55,040 --> 00:17:56,425 the 1080P low image quality 378 00:17:56,425 --> 00:18:00,512 without oversampling. It tied AMD's 780M core display. After turning on 379 00:18:00,512 --> 00:18:02,131 the XeSS balance file, 380 00:18:02,131 --> 00:18:04,466 it can run to an average of 60fps. After using XeSS upsampling 381 00:18:04,466 --> 00:18:07,369 based on deep learning, 382 00:18:07,369 --> 00:18:10,973 the picture quality is also very playable on the notebook screen. The 383 00:18:10,973 --> 00:18:14,359 frame rate is slightly lower than the 780M using FSR. 384 00:18:14,359 --> 00:18:15,961 I am also curious about one thing. 385 00:18:15,961 --> 00:18:20,032 Since there are currently two companies, Intel and AMD. All core displays already support ray tracing 386 00:18:20,032 --> 00:18:23,569 , and their performance has been greatly improved compared to previous core displays. 387 00:18:23,569 --> 00:18:27,539 So what if I use them to run 2077's path tracing? 388 00:18:27,539 --> 00:18:29,541 Hey, it really ran. 389 00:18:29,541 --> 00:18:33,762 Although it only got "e-sports performance" with an average frame rate of 3fps and 2fps, 390 00:18:33,762 --> 00:18:36,565 they didn't crash or explode the video memory 391 00:18:36,565 --> 00:18:40,636 . After all, can 32G of memory give you such an easy burst? 392 00:18:40,636 --> 00:18:43,071 In short, this test is just like Tu Yile. 393 00:18:43,071 --> 00:18:46,325 Think about it. Now the core display can run path tracking 394 00:18:46,325 --> 00:18:48,427 . Well, it’s good for Windows handhelds! 395 00:18:48,911 --> 00:18:49,962 I simply ran a few games 396 00:18:49,962 --> 00:18:52,831 and the performance of Intel's new core display was quite good, 397 00:18:52,831 --> 00:18:55,968 both in 3Dmark and in actual games. 398 00:18:55,968 --> 00:18:59,655 Even the 112EU residual version of Ultra 5 125H 399 00:18:59,655 --> 00:19:03,826 has more wins than AMD's current 780M. Not 400 00:19:03,826 --> 00:19:09,765 considering that AMD's 8040 series in 2024 will focus on one technology and rename it as 401 00:19:09,965 --> 00:19:14,536 Core Ultra. This core display should perform very strongly in 2024. In 402 00:19:14,536 --> 00:19:16,371 addition, the advantages of the media engine 403 00:19:16,371 --> 00:19:18,240 can help accelerate 404 00:19:18,240 --> 00:19:20,976 even when paired with a standalone display and Intel's core display. 405 00:19:20,976 --> 00:19:25,164 This is good news for light gamers and creators. 406 00:19:25,447 --> 00:19:28,333 So our performance test will start here. 407 00:19:28,333 --> 00:19:30,969 I want to say where the weakest point of current Windows laptops is. 408 00:19:30,969 --> 00:19:32,738 It must be the battery life performance. 409 00:19:32,738 --> 00:19:36,041 This time Core Ultra brings so much energy consumption. So 410 00:19:36,041 --> 00:19:39,361 how does it perform in the actual endurance test? 411 00:19:39,361 --> 00:19:44,132 It’s time to bring out our magic mirror - the Geek Bay endurance test model. 412 00:19:44,416 --> 00:19:46,318 Finally, in the balanced performance mode, 413 00:19:46,318 --> 00:19:51,723 Xiaoxin Pro 16 equipped with Core Ultra 5 125H ran a time of 6 hours and 49 minutes. 414 00:19:51,723 --> 00:19:56,962 This result is better than the previous generation equipped with 13500H. Xiaoxin Pro 16 has a longer battery life of 2 hours and 14 minutes, 415 00:19:57,029 --> 00:19:59,514 which means the battery life is 49% longer. It 416 00:19:59,514 --> 00:20:03,135 is also 1 hour and 24 minutes longer than AMD's 7840HS version. 417 00:20:03,168 --> 00:20:03,835 Of course, 418 00:20:03,835 --> 00:20:10,042 the battery capacity of the 2024 Xiaoxin Pro 16 has also been increased from the previous generation's 75Wh to 84Wh 419 00:20:10,042 --> 00:20:12,928 . Calculated in terms of battery capacity, if the battery capacity is equal, 420 00:20:12,928 --> 00:20:17,633 a notebook equipped with Core Ultra will have about 30% longer battery life than the 13th generation Core model, 421 00:20:17,733 --> 00:20:21,220 and about 12% longer than the 7840HS. 422 00:20:21,336 --> 00:20:24,439 Although I think this is not disruptive, it is 423 00:20:24,439 --> 00:20:27,226 still far from the MacBook. There is a considerable gap in battery life 424 00:20:27,226 --> 00:20:31,213 , but at least this should be the platform with the longest battery life 425 00:20:31,213 --> 00:20:32,631 among Windows laptops you can buy currently. 426 00:20:32,631 --> 00:20:36,468 However, higher expectations will be reserved for next year’s Lunar Lake. There 427 00:20:36,468 --> 00:20:38,437 is one more thing I need to mention here 428 00:20:38,437 --> 00:20:41,423 . The two ultra-low-power small cores introduced 429 00:20:41,423 --> 00:20:44,409 for the first time will not be used in daily applications. 430 00:20:44,409 --> 00:20:49,331 They can only be used in standby idle state, when watching videos locally, 431 00:20:49,331 --> 00:20:53,168 or in the software specially programmed for them. 432 00:20:53,368 --> 00:20:56,221 Our battery life test The model has almost no idle time 433 00:20:56,221 --> 00:20:58,373 and no scene for watching videos locally, 434 00:20:58,373 --> 00:21:03,412 so this ultra-small core can hardly bring any gain in battery life in our battery life test. 435 00:21:03,629 --> 00:21:06,665 Maybe it will help in the PCMark10 battery life test 436 00:21:06,765 --> 00:21:11,536 , but I think the battery life of PCMark10 The test model is seriously out of touch with actual usage. 437 00:21:11,720 --> 00:21:15,440 I think Intel should really allow more applications for ultra-small cores 438 00:21:15,624 --> 00:21:19,628 . After all, what kind of performance do I need to type in Word? 439 00:21:19,628 --> 00:21:23,015 If you don’t let me use the ultra-small core at this time, when should I use it? 440 00:21:23,015 --> 00:21:26,768 After all, it is not a small piece of garbage with performance like A520. 441 00:21:26,918 --> 00:21:29,821 To be fair, its performance is actually enough for typing. 442 00:21:29,821 --> 00:21:32,541 I really can’t understand Intel’s scheduling strategy this time. 443 00:21:32,841 --> 00:21:33,575 In addition to these 444 00:21:33,575 --> 00:21:36,261 , Meteor Lake also introduces the AI acceleration unit NPU, 445 00:21:36,478 --> 00:21:40,265 which is why it can say itself It is the core of an AI computer. 446 00:21:40,532 --> 00:21:44,369 It can accelerate AI applications with much lower power consumption and 447 00:21:44,369 --> 00:21:48,423 can also run AIGC applications such as Stable Diffusion. 448 00:21:48,623 --> 00:21:51,710 Of course, its focus is on energy consumption ratio rather than performance, and 449 00:21:51,710 --> 00:21:57,616 it is more oriented towards noise reduction, etc. Cut out the picture. This kind of native, low-power AI application needs. 450 00:21:57,716 --> 00:21:59,935 If you are really an AI practitioner, 451 00:21:59,968 --> 00:22:03,572 NPU still cannot replace the work of independent graphics. 452 00:22:03,572 --> 00:22:04,423 So here 453 00:22:04,423 --> 00:22:08,360 our first review of Core Ultra 5 125H is coming to an end. In addition to 454 00:22:08,360 --> 00:22:09,011 the CPU part 455 00:22:09,011 --> 00:22:12,264 , Core Ultra basically continues the overall architecture since the 12th generation. 456 00:22:12,264 --> 00:22:14,499 The small core has a small architectural evolution. 457 00:22:14,499 --> 00:22:16,935 The core display part has made considerable progress. 458 00:22:16,935 --> 00:22:21,473 The game performance can now achieve a 780M core display that is not inferior to the 7840HS. 459 00:22:21,623 --> 00:22:24,910 It also supports XeSS, ray tracing and other functions. 460 00:22:24,910 --> 00:22:27,696 I think the performance of the core display this time is very good. In 461 00:22:27,696 --> 00:22:28,330 terms of battery life 462 00:22:28,330 --> 00:22:30,565 , Core Ultra is significantly improved compared to the previous generation 463 00:22:30,565 --> 00:22:33,485 , but it is obviously still far behind the battery life of Mac. 464 00:22:33,485 --> 00:22:35,637 The addition of NPU is definitely a good thing 465 00:22:35,637 --> 00:22:41,126 , because many AI applications that do not require high computing power can now be run directly on NPU 466 00:22:41,126 --> 00:22:45,313 , so there are many small ones. AI functions can be integrated into software 467 00:22:45,313 --> 00:22:47,933 and can be used on the move. 468 00:22:47,933 --> 00:22:50,635 Although the current application scope is still very limited 469 00:22:50,635 --> 00:22:54,373 , I believe this is definitely a good start for Windows PC. 470 00:22:54,373 --> 00:22:55,323 At present, 471 00:22:55,323 --> 00:22:59,361 although it has not yet reached Apple in this field of thinness and lightness The level of the M series 472 00:22:59,361 --> 00:23:03,248 is still the best choice among current Windows thin and light notebooks. 473 00:23:03,248 --> 00:23:07,085 The current price of the 2024 Xiaoxin Pro 16 using Ultra 5 125H 474 00:23:07,085 --> 00:23:09,104 is 5999 yuan. 475 00:23:09,104 --> 00:23:13,859 At the same time, the previous generation version using i5 13500H is currently 5699 yuan 476 00:23:13,859 --> 00:23:17,095 . Do you think the current difference of 300 yuan is worth upgrading? 477 00:23:17,095 --> 00:23:17,779 In general, 478 00:23:17,779 --> 00:23:20,866 the Core Ultra of the Meteor Lake architecture 479 00:23:20,866 --> 00:23:23,385 is indeed the generation that has changed the most in recent years 480 00:23:23,418 --> 00:23:26,121 as Intel said , but you will find that the focus of the so-called "change" this time 481 00:23:26,121 --> 00:23:29,391 has shifted from the CPU level to the SOC level. 482 00:23:29,391 --> 00:23:32,794 Maybe next year's Lunar Lake will be this one. Under the completeness of the strategy, 483 00:23:32,794 --> 00:23:36,064 we will also look forward to Intel's performance in subsequent products. 484 00:23:36,081 --> 00:23:38,283 As far as the current Meteor Lake itself is concerned, 485 00:23:38,283 --> 00:23:42,070 I think the changes are significant, but 486 00:23:42,087 --> 00:23:45,474 the efficacy is not enough. We still need to take a bigger step. Okay, that 487 00:23:45,574 --> 00:23:47,426 's it for this issue. All the content of the program. 488 00:23:47,426 --> 00:23:49,261 If you like our program, don’t forget to press and hold the like button to give us a compliment. 489 00:23:49,261 --> 00:23:50,295 Don’t forget to follow our channel. 490 00:23:50,295 --> 00:23:52,881 Don’t forget to go to our Taobao store to see the clothes I’m wearing. 491 00:23:52,881 --> 00:23:55,217 Then we'll see you in the next episode 46925