Intel Core Ultra 7 165H Meteor Lake Falls Short in 5/6 Benchmarks Compared to 13th Gen Core-13700H


January 13, 2024 by our News Team

Intel's latest addition to their 1st Gen Core Ultra "Meteor Lake" lineup, the Core Ultra 7 165H, falls short in benchmarks when compared to its competitor, the 13th Gen Core-13700H, with disappointing single-core performance and lackluster results across multiple tests.

  • High maximum boost clock of 5GHz for P-core
  • Outperformed competitor in one benchmark (Cinebench R15)
  • Potential for future updates and improvements


Intel’s latest addition to their 1st Gen Core Ultra “Meteor Lake” lineup, the Core Ultra 7 165H, has recently been leaked, and the results are far from impressive. This 16-core CPU, featuring 6 P-Cores (Redwood Cove), 8 E-Cores (Crestmont), and 2 LPE cores (Crestmont on SoC), falls short in five out of six benchmarks when compared to its competitor, the 13th Gen Core-13700H.

With a maximum boost clock of 5GHz for the P-core, 3.8GHz for the E-cores, and 2.5GHz for the LPE cores, the Core Ultra 7 165H has a default TDP of 28W, a maximum boost power limit of 115W, and a maximum assured power of 65W. However, when put to the test by Notebookcheck, this chip had a PL2 limit of 65W and a base power of 55W. It was pitted against the Core i7-13700H (53W-89W) and the Ryzen 7 7840HS (54W-64W), with limited but relevant benchmarks.

Unfortunately for Intel, the Core Ultra 7 165H only managed to come out on top in one test. In the outdated Cinebench R15 benchmark, it proved to be 9% and 12% faster than the Core i7-13700H and the Ryzen 7 PRO 7840HS, respectively. However, in more modern benchmarks like R20 and R23, the 13700H outperformed the Meteor Lake chip, albeit not by a significant margin. Regardless, this is undoubtedly a disappointing outcome for Intel’s Meteor Lake.

The disappointment continues when examining the single-core performance of the Core Ultra 7 165H. It falls behind both the Core i7-13700H and the 7840HS in Cinebench R23, and it also trails the former in R20 and R15, with deltas of 3% and 6%, respectively. It’s hard not to question what went wrong with Meteor Lake. In fact, the performance of the Core Ultra 7 165H is no better than that of Ice Lake, except without the delays.

Overall, Intel’s Core Ultra 7 165H has failed to impress in the benchmarks when compared to its competitor, the Core-13700H. With lackluster results across multiple tests, it’s clear that Intel has some work to do to improve the performance of their Meteor Lake lineup. As technology enthusiasts eagerly await further updates and improvements, it remains to be seen how Intel will address these shortcomings and regain their competitive edge in the CPU market.

About Our Team

Our team comprises industry insiders with extensive experience in computers, semiconductors, games, and consumer electronics. With decades of collective experience, we’re committed to delivering timely, accurate, and engaging news content to our readers.

Background Information


About Intel: Intel Corporation, a global technology leader, is for its semiconductor innovations that power computing and communication devices worldwide. As a pioneer in microprocessor technology, Intel has left an indelible mark on the evolution of computing with its processors that drive everything from PCs to data centers and beyond. With a history of advancements, Intel's relentless pursuit of innovation continues to shape the digital landscape, offering solutions that empower businesses and individuals to achieve new levels of productivity and connectivity.

Intel website  Intel LinkedIn

Technology Explained


CPU: The Central Processing Unit (CPU) is the brain of a computer, responsible for executing instructions and performing calculations. It is the most important component of a computer system, as it is responsible for controlling all other components. CPUs are used in a wide range of applications, from desktop computers to mobile devices, gaming consoles, and even supercomputers. CPUs are used to process data, execute instructions, and control the flow of information within a computer system. They are also used to control the input and output of data, as well as to store and retrieve data from memory. CPUs are essential for the functioning of any computer system, and their applications in the computer industry are vast.


E-Cores: E-Cores (Efficiency Cores) are a type of technology used in the computer industry to provide a more efficient and reliable way of powering and cooling computer components. They are made up of a combination of copper and aluminum, and are designed to be more efficient than traditional copper cores. E-Cores are used in a variety of applications, such as in CPUs, GPUs, and other computer components. They are also used in servers, laptops, and other electronic devices. The technology is designed to reduce heat and power consumption, while also providing a more reliable and efficient way of powering and cooling computer components.


P-Cores: P-Cores (Performance Cores) are a type of processor technology developed by Intel that is designed to improve the performance of computer systems. This technology is based on the concept of multi-core processors, which are processors that contain multiple cores or processing units. P-Cores are designed to increase the speed and efficiency of computer systems by allowing multiple cores to work together in parallel. This technology is used in a variety of applications, including gaming, video editing, and data analysis. P-Cores are also used in servers and other high-performance computing systems. The technology is also used in mobile devices, such as smartphones and tablets, to improve battery life and performance. P-Cores are an important part of the computer industry, as they allow for faster and more efficient computing.


SoC: A System-on-Chip (SoC) is a highly integrated semiconductor device that encapsulates various electronic components, including processors, memory, input/output interfaces, and often specialized hardware components, all on a single chip. SoCs are designed to provide a complete computing system or subsystem within a single chip package, offering enhanced performance, power efficiency, and compactness. They are commonly used in a wide range of devices, from smartphones and tablets to embedded systems and IoT devices, streamlining hardware complexity and facilitating efficient integration of multiple functions onto a single chip.





Leave a Reply