An Intel Corei7-13790F is an Intel-made processor. It is based on the framework of multiprocessor architecture. It has two-core, four-core, and six-core processing architectures. The Intel Corei7 has utilized a variety of microarchitectures, including Bloomfield, Gulftown, Arrandale, Lynnfield, Clarksfield.
It can be installed on smartphones, PCs, and built-in devices. Intel’s fastest CPU for computers and other consumer electronics is the Corei7. Similar to the Corei5, the Corei7 has Intel’s Turbo Boost Technology.
The Intel Corei7 is available with two to six cores and can manage up to 12 threads simultaneously. Its cache memory is between 4 MB and 12 MB, while its processor clock speed ranges from 1.70 GHz to 3.90 GHz.
Intel Corei7 thermal design power (TDP) ranges from 130 watts to as little as 15 watts. As with other Corei series CPUs, the Intel Corei7 supports ECC memory, Intel Platform Protection Security, and Intel OS Guards. These features have built-in protection for the BIOS, enabling for secure booting and preventing attacks.
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What Are the Pros of I7 Processors?
Ability to Process
The i7 can quickly process data and has more cores. It performs effectively for demanding tasks like as creating and editing material with the Adobe suite and swiftly transitioning between tasks.
Method for Cooling
The i7 also has an efficient cooling system. It is crucial to monitor the temperature of your CPU, as demanding tasks can cause it to overheat. While you’re about it, fix the computer fan that’s running in the background.
In terms of gaming, the i7 is superior to the i5 for high-end, demanding gaming. Additionally, the i7 has the most recent overclocking technology from Intel, Turbo Boost Max Technology 3.0.
Specifications of Intel Core i7-13790F
Intel Core i7-13790F has the same number of cores and threads as Intel Core i5-13400F, but its cache and clock speeds are faster. In terms of specs, the Intel Core i5-13490F has the same number of cores and threads as the Core i5-13400F: 6 P-Cores and 4 E-Cores, for a total of 12 cores and 16 threads.
- The first change is in the clock speeds. The 13490F has a boost clock of 4.8 GHz and also has more cache. The CPU has L3 cache of 24 MB and L2 cache of 9.5 MB. The 13400F’s L3 cache is only 20 MB, and its L2 cache is only 9.5 MB.
- That’s about 20% more memory and a 4% faster clock. The high-end Intel Core i7-13790F has 8 P-Core + 8 E-Core, which adds up to 16 cores and 24 threads. It has up to 5.2 GHz of clock speed and 33 MB of L3 cache.
- That’s the same as the Core i7-boost 13700F’s clock, but it has 3 MB more cache. The CPU was tested in CPU-z by @wxnod. In single-core tests, the chip got 836 points, and in multi-core tests, it got 12139.8 points.
Intel Core i7-13790F Processors Have the Following Features:
Systems With More Than One Processor That Work Better With QPI
Nehalem processors moved the memory controller to the CPU and used Intel Quick Path Interconnect to make a distributed shared memory architecture (QPI). QPI is the new point-to-point interconnect that connects a CPU to a chipset or another CPU.
It can send and receive up to 25.6 GB/s per link in both directions. Intel’s decision to move the memory controller into the CPU and add the new QPI data bus affects systems with only one processor. But in systems with more than one processor, this effect is much bigger.
The Nehalem microarchitecture added the fast QPI data bus. The Core i7 processor and the memory controller are both on the same chip. In a multiprocessor system based on Nehalem, each CPU can use its own local memory. Each CPU can also access the local memory of other CPUs through QPI transaction.
The CPU Runs Faster Because of Intel’s Turbo Boost Technology
Intel and AMD began making CPUs with more than one core about five years ago. Since then, many applications and development environments have been changed to take advantage of the fact that a system has more than one processing element.
But because investing in software meant that applications had to be redesigned, there are still a lot of single-threaded apps. Before there were CPUs with more than one core, these programs ran faster on new CPUs with higher clock speeds. Multicore CPUs, which had more separate processing cores instead of faster clock speeds, stopped this trend.
Intel made a new feature called Intel Turbo Boost to speed up applications with few threads and reduce the amount of power the processor uses. Intel Turbo Boost is a smart feature that lets active processor cores run faster than the base operating frequency when certain conditions are met.
When the operating system (OS) asks for the most powerful processor state, Intel Turbo Boost is turned on. Intel calls the method of making a CPU run faster than its base clock speed “Turbo Boost.” Both Core i7 and Core i5 processors can use Turbo Boost.
Smart L3 Cache Has Improved Cache Latency
All Core i7 processors share the same L3 cache, which can be as big as 12 MB. The caches are set up for the Core i7-820QM quad-core processor in the NI PXIe-8133 embedded controller. There are four cores in the NI PXIe-8133 embedded controller.
Each core has 32 kilobytes of instruction storage in the L1 cache. Each core also has an L2 cache of 256 kilobytes and a shared L3 cache of 8 megabytes. All cores share the L3 cache, which helps improve performance and reduce latency by reducing the number of requests to the processor cores to “snoop” the cache.
A shared inclusive L3 cache makes sure that if a cache miss happens, the data is outside of the processor and not in the local caches of other cores. This keeps other cores from going through the caches of other cores for no reason.
The L3 is made so that the fact that it is inclusive makes it harder to listen in on the traffic between processor cores. How long it takes to get to L3 depends on the frequency ratio between the processor and the uncore subsystem.
This feature makes the processor work better as a whole and can be used for many different tasks, such as testing, measuring, and controlling. Each physical processor can have more than one processor core and something called a “uncore,” which is a group of shared subsystems. In the Intel Core i7 processor, the uncore gives all of the cores, Intel Quick Path Interconnect links, and logic access to the same third-level cache.
Intel Active Management Technology for Remote System Management (Amt)
AMT lets system administrators manage, monitor, and update systems from a distance. As part of the Intel Management Engine, Intel AMT is built into the chipset of a Nehalem-based computer.
This feature lets administrators start up computers remotely, keep track of hardware and software assets, and fix problems and recover data from a distance. Engineers can use this function to manage test or control systems that need to be up and running all the time. AMT makes it possible for test, measurement, and control applications to collect data remotely and check on the state of the application.
In the event that an application or system fails, the user can use AMT to remotely diagnose the problem and look at debug panels. This gets the problem fixed faster and keeps you from having to deal with the system itself. When software updates are needed, AMT makes it possible to install them remotely.
The Intel Nehalem microarchitecture-based Core i7 CPU has a lot of new and improved features that help a wide range of applications, such as measuring, controlling, and testing. When engineers and scientists compare this microarchitecture to the ones that came before it, they should expect improvements in processing speed, memory, and data throughput.
The Nehalem microarchitecture is used for the first time in the Intel Core i7 processor. This CPU is great for 3D computer games, running multiple programs at once, and programs with multiple threads. The i7 processors are the best, the i5 processors are in the middle, and the i3 processors are the least expensive.