Engineering drawing and graphic design, or what is known as Render, the installation of 3D modeling images and the analysis of graphics scenes, is one of the most heavy and complex work that drains the energy of computer hardware, especially the central processor. During work on engineering design programs, the tables of the central processor cores are used (filling) with the code and the dense data of 100% 100% 100 until the central processor finishes analyzing the image, installing its models and extracting its final shape.
The same applies to video editing and montage tools. Rendering operations depend heavily on the multiplicity of the central processor, and the reason lies in how to develop design applications that depend in their programming on a method called “containers”: We will try to simulate a central processor containing eight cores with construction workers responsible for lifting 1000 bricks to the third floor in A new residential building, whenever a worker finishes climbing with 40 bricks, he will go down a second time to fill his tractor cart with another 40 bricks, then go up with the cart again and so on, until all the workers finish from the bricks under the building. Just like the central processor, each individual core translates the required code, then analyzes the results, then takes care of a different code and analyzes it again, and so forth, until all the central processor cores finish completing the command and extract the final scene.
But unlike the rendering processes that rely on multiple core processor cores, 3D modeling processes depend on the frequency of the core of the central processor, and we can compare it to a group of workers trying to build a hierarchical building, so that every brick is placed in the hierarchical building It will be followed by a brick directly higher than it, and it is not permissible to work on a specific corner of the pyramid until after the installed hierarchical base is completed. Just like the central processor, in which each individual core is subjected to a set of complex calculations that depend on programming it in the form of a specific hierarchy that is completed step by step, and for this reason the speed of the frequency of the individual core plays a prominent role in the amount of time required to complete and finish projects.
How to choose the central processor best suited for engineering designs and graphics
So now you need a central processor that contains a large amount of processing cores, add to that the importance of looking at the frequency of its cores. But to get both things together at the same time was difficult to achieve for companies developing central processors, because the development of a central processor with a large number of cores operating at high frequencies will cause a very high energy consumption and will lead to a nature of work under high temperatures. This dilemma has been taken for granted for the past several long years, and there was no effective solution for AMD and Intel to avoid it, especially in the series of high-performance business processors such as the Xeon processor family, for example. But things have changed completely and technology has advanced.
To solve this dilemma, factories have resorted to developing Turbo Boost technology, and have significantly improved their efficiency with each new generation of processors launched. This technology helped automatically drive core frequency speeds to accelerate computing performance in heavy-duty work with high code density and complex computational data. But this is not all, as Turbo Boost technology can act as a traffic signal. When the rate of energy consumption gradually increases and the temperature of the central processor chip increases, this technology works to gradually reduce the frequency speed until a balance process occurs between the speed of performance and the rate of energy consumption used.
Meaning if the process of analyzing a 3D scene requires running only two cores from the central processor to do the code analysis, then Turbo Boost technology is concerned with boosting the frequency of the two nuclei to maximum speeds, but if the central processor encounters factory-specified ratios in power consumption or temperatures (whichever comes first), the frequency speed will automatically decrease Cores to the factory-specified default speeds. In this way, the manufacturing companies were able to preserve the default lives of central processors from the risks of high temperatures, while at the same time reducing the electricity bills borne by users.
Render and 3D modeling programs differ in the way they are developed and programmed, some of them are based on the strength and efficiency of the performance of the central processor, while some other programs depend on the strength of the performance of the graphic processor in analyzing and processing its code. But whether the first matter is the preference of most content makers and designers or the second is the most preferred, yet most engineering design programs depend on the strength of the performance of the central processor, in which the processor is the first responsible for analyzing its code and processing its data, only recently. These programs began to provide support for the ability to implement design work through the graphic processor (we always call the graphic card or screen card the title of the graphic processor), as it comes at the top of the list of programs that rely heavily on the graphic processor, such as FurryBall, Octane and V- Ray.
In terms of performance in the ability to complete projects and engineering drawings, the rendering processes through the graphic card take a few seconds instead of several long minutes, and thus this matter will be of great benefit to the user in completing his work in faster periods of time and increasing his productive and practical capabilities. Therefore, you have to take the appropriate decision in your choice of both the central processor and the graphic card that is appropriate for the nature of your business.
But back to the set of design programs that depend on the power of the central processor in the processing characteristics and the amount of cores it contains, we have brought to you a set of the best central processors specifically targeted for design work and content creators:
1- AMD Ryzen 9 3950X has 16 cores and 32 paths, it works at a frequency of 3.5GHz up to 4.7GHz with Boost technology, and it achieves in the review of Cinebench R20 single core 518 points, and it achieves 9165 points in multi-core performance.
2- AMD Ryzen 9 3900X has 12 cores and 24 lanes, it operates at a frequency of 3.8GHz, with Boost technology up to 4.6GHz, and has achieved in the review of Cinebench R20 single core 511 points, and achieved in multi-core performance 7100 points.
3- Intel Core I9-9900K has 8 cores and 16 lanes, it operates at a frequency of 3.6GHz, with Boost technology up to 5.0GHz, and in the Cinebench R20 review of single core it achieves 500 points, and it achieves 4914 points in multi-core performance.
4- AMD Ryzen 7 3700X has 8 cores and 16 lanes, it works at a frequency of 3.6GHz, with Boost technology up to 4.4GHz, and in Cinebench R20 review of single core, it achieves 494 points, and it achieves 4856 points in multi-core performance.
5- Intel Core I7-9700K has 8 cores and 8 cores, it operates at a frequency of 3.6GHz, with Boost technology up to 4.9GHz, and in the Cinebench R20 review of the single core, it achieves 466 points, and it achieves the multi-core performance 3656 points.
Certainly, these central processors are not a hypothesis, as there are many alternative central processors, whether from the current or previous generations, and are able to achieve the same results and sometimes even exceed them, also there are some design work that does not impose the presence of a central processor with a large number of cores, and it is possible Get enough engineering work with a Core I5 or Ryzen 5 processor, or even skip all of these processors and lift your head higher to the horizon until you reach the AMD Threadripper or Intel Xeon.
But we are trying to bring you the best central processors that may meet the interest of the middle class of designers, as they are considered the best efficient processors thanks to their modern architecture techniques, and that is why we chose this group for you, so be sure that any choice of them will be more than enough for all your creative work.
How to choose the graphic card best suited for engineering designs and graphics
As we mentioned to you at the beginning, there are some render works that depend on the graphics card in analyzing its code and processing its data. In the context of this matter (maybe) it is better to go towards the green team and buy an NVIDIA graphics card even if we are a fan of the red team, and we recommend this to you for a clear and simple reason: while high-performance Radeon cards are able to handle rendering and analyze 3D scenes naturally However, NVIDIA cards get better widespread support with engineering design software tools and engines. Fortunately, some design software development companies have started indicating that upcoming support will be provided for AMD graphics cards in the near future.
Is it necessary to buy the most powerful graphics cards for engineering designs? This question can be answered by you alone, as it completely depends on the type of programs and tools that you use in the implementation of your work and graphic designs. But in general, engineering designs or the designers themselves emphasize that the biggest factor lies with the central processor, random access memory and video RAM built into the graphics card more than reliance on the graphics processor itself. In other words, business stations for design and engineering drawings may be suitable for mid-range graphics cards. However, it may be different with some 3D drawing projects and editing techniques on video files (montages).
The graphics card is viewed merely as a means of translating tasks and commands into an image that is displayed on the screen, and therefore it is often in a state of waiting, anticipation and preparation until the central processor finishes the impossible task first, and then sends its results to the graphic card. For this reason, the central processor is considered specifically as the weakness or the cause of the bottleneck problem as a result of the time delay that the graphics card is exposed to while waiting for the information that the central processor tries to finish first. But having a powerful graphics card may help you greatly to speed up your tasks and accomplish them in faster periods of time, and it will also be very positive in the event that you seek to play some games and enjoy your free time or while you wait for the end of the combinations and analyze your designs and graphics, so this is a group of Best Graphics Cards with Good Results in Reviews:
1- Titan V card can achieve 396 points in OctaneBench review and can finish Redshift Bench review in 8.50Min time period and can finish VRYA review in 41.00Min period.
2- The RTX 2080 Ti card can achieve 304 OctaneBench review points and can finish the Redshift Bench review in a 8.38Min time period and can finish the VRYA review within a 0.51Min time period.
3- The RTX 2080 card can achieve 226 points in OctaneBench review and can finish the Redshift Bench review in a time period of 10.59Min and can finish the VRYA review in a 1.1Min period.
4- The RTX 2070 Super card can achieve 220 points in OctaneBench review and can finish the Redshift Bench review in a period of 11.17Min and can finish the VRYA review in a period of x.xxMin.
5- RTX 2070 card can achieve 210 points in OctaneBench review and can finish Redshift Bench review in 11.35Min interval and can finish VRYA review in 1.05Min period.
6- The GTX 1080 Ti card can achieve 222 OctaneBench review points and can finish the Redshift Bench review in a 11.44Min time period and can finish the VRYA review within a 0.56Min time period.
7- The RTX 2060 Super Card can achieve 203 points in OctaneBench review and can finish the Redshift Bench review in a 12.17Min time period and can complete the VRYA review in x.xxMin period.
8- GTX 1080 card can achieve 148 OctaneBench review points and can finish Redshift Bench review in 16.00Min time period and can finish VRYA review in 1.30Min interval.
9- The GTX 1070 card can achieve 133 OctaneBench review points and can finish the Redshift Bench review in a period of 17.11Min and can finish the VRYA review in a 1.35Min period.
How much RAM do you need
Just like choosing a central processor, the amount of RAM you need will depend on the type of business you have and the shape of your uses. If you are designing 3D models with large numbers of Polygon, you may need a large amount of RAM, so that the minimum is 16GB to 32GB. If you are working on complex scenes that contain thousands of elements and plugins and use a lot of templates and textures, then we recommend that you purchase a memory size of 64GB as a minimum. You may start with 16GB of memory temporarily, but you will soon discover that you definitely need to increase it.
The speed of the frequency and the times is not that important in the different form of the results, it is possible to a RAM with a frequency of 2933MHz achieves the same results as a random access memory with a frequency of 4166MHz, in addition to that we find most of the central processors do not benefit from the high-frequency RAM, some processors are the only ones Which takes advantage of high frequencies as an example of the high-performance Threadripper CPU class and more recently the 3rd generation Ryzen processors, thanks to the close interconnection between the central processor and the built-in memory controller. But generally speaking if you are seeking to squeeze out the last drop of performance power that you can get with your business platform, there is no problem in purchasing a high frequency RAM. The theory is fixed and unchanged. Memory with lower timings can send and receive data with the central processor or store it in faster time intervals than memory with higher timings.
There are many guidelines urging the importance of buying a complete set of RAM (one set / One Kit) instead of buying it separately, meaning that one kit 64GB is better than buying two 2xKit kits of 32GB each, and the reason for this is so important is that the manufacturers It works on testing the unified crew and makes sure of its work efficiency, stability and support in full compatibility with the motherboards while using it as a single package, and in this way the single crew is higher in the percentage of results than the different crews even if it is proven to provide support for different crews. Therefore, we recommend that you buy one set that comes in one box and not buy a small set and then increase it in the future, unless you are facing a certain deficit in saving the budget. But we strive completely to provide you with comfort and to make sure that you do not encounter any problems, especially since the different types of memories or their technical characteristics cause many problems that are hidden in most cases and difficult to identify.
As for the good types, it is preferable to buy leading brands such as Corsair, GSkill, ADATA and Crucial, and choose from the most popular models so that the chance of the motherboard compatibility with them is great and certain. Although motherboard companies are interested in doing a set of tests on the compatibility of types of RAM, but certainly these tests will not include all types and models in the market, so it is best to search first for supported memory types through your motherboard page on the company’s official website.
How to choose the most suitable motherboard for engineering designs and graphics
Of course, the motherboard does not have a noticeable effect on the overall performance of the platform, but what you should take care of is to make sure that it provides all the features and features that will meet all your needs and requirements at the present time and in the future as well:
- Ensure that the motherboard socket (socket) is compatible with the central processor you have decided to purchase.
- Ensure that the motherboard supports the size of RAM that you have decided to buy now and in the future.
- Ensure the number of additional PCIe Expansion Slots are appropriate for your current graphics cards or if you are considering purchasing more than one card in the future, with slots for sound and video cards … etc.
- Check the types of M.2 NVMe PCIe storage cases before purchasing, there are specific types of NVMe storage cards that each motherboard supports over the others, just like RAM.
- Ensure the number of USB ports at various speeds that are compatible with all of your devices that you will connect to the motherboard at the present time and in the future.
- Ensure that you have sufficient SATA ports for all of your storage.
- Ensure the number of phases / power outlets that the central processor power circuit contains, and know their types and capabilities if you intend to buy a CPU overclocking support.
- Motherboards come in different sizes, so make sure that the size of your motherboard, whether it is WTX, EATX, ATX, MicroATX or MiniATX, matches the size of your case / case.
How to choose the most suitable storage unit for engineering designs and graphics
Once the engineering drawings and graphic images are stored in the RAM, the speed of the volume will not benefit anything, but in terms of performance in the operations of automatic saving of projects, uploading them to open them again, loading the design software interface or moving to store information on the storage memory while the RAM memory is full at the time. Volume only plays a big factor in enhancing results and raising performance.
The content creators category has always relied on going the path of NVMe PCIe hard drives, in fact this is the best and fastest way if you are looking to speed up loading scenes and get work done and finished in short periods of time. But if you adhere to the financial condition and the limited budget, then you can rely on solid storage cases of the SATA SSD, but on the condition that you do not give it up at all costs, it will help you to work on the Windows system faster and will contribute to the acceleration of performance within your business programs.
One of the best fast storage solutions comes with the Samsung 970 EVO NVMe PCIe 3.0, but if you are satisfied with the SATA SSD, you can buy the Samsung 860 EVO. In this way, you can purchase a huge storage disk to archive large files and store them securely in case the system volume is damaged or failed.
There are some questions that you want to make sure of the nature of the NVMe PCIe card delivery environment, which requires four PCIe Lanes lanes while the graphics card alone requires 16 PCIe Lanes paths, which is the maximum number of paths supported by the PCIe Controller built into the central processor, very simply and not This clutter your mind. The PCIe Lanes lanes supported by the integrated PCIe Controller are distributed on the PCIe slots of the graphics cards alone, while the M.2 ports are powered by the PCIe Lanes lanes by the built-in PCIe Controller. The same mainframe, like SATA and USB ports.
On the other hand, this central chip is connected to the central processor via four PCIe Lanes paths through a DMI Link controller, and to be honest with you, this environment in the form of connections sometimes causes a bottleneck for NVMe PCIe storage cards, especially the high-speed ones.
Therefore, high-performance central processors come with a PCIe Controller that supports up to 48 PCIe Lanes or 64PCIe Lanes so that all graphics cards work with a large bandwidth, in addition to that, motherboard manufacturers can distribute a number of PCIe Lanes lanes supported by the processor controller. Built-in M.2 memory card slots as well. Ultimately, however, you don’t have to worry about this, as most mainframes provide enough suitable PCIe Lanes lanes for NVMe PCIe memory cards.
How to choose the display screen best suited for engineering designs and graphics
First of all, you must make sure that your screen features modern display technologies such as Non Glare, Low Blue Light and Flicker Free, as these technologies protect the eyes from the dangers of harmful lighting and protect them from distraction, fatigue, and flicker resulting from displays, especially if you are preparing For long sessions in front of the screen and staring at it every day, if your screen enjoys these technologies, you will not suffer at the end of your day any pain, and your experience of the screen will be comfortable and quiet and will boost your productivity.
In terms of the number of screens and the accuracy of their display, it completely depends on your personal preference and the nature of your business. Some designers find it necessary to have two or three screens, others work through four or more screens, but this case is within the jobs of professional designers and developers in large business companies. Some users prefer to deal on only one screen, but it is ultra-wide and bulky enough with high-quality display resolution. But you must make sure you have enough room for this large screen.
It is possible to consider buying two 27-inch screens with a resolution of 1080p or one screen with a resolution of 1440p, it is advisable if it is a resolution of 2160p, but regardless of the screen resolution, it must have IPS technology, so unfortunately TN Panel screens are not worthy for business nor It provides accurate gradations or color space and is difficult to work with from various viewing angles. You do not need a fast gaming screen as much as you need a screen with ultra-clear colors and crisp and accurate details.
How to choose the power supply best suited for engineering design and graphic design
Be interested in buying a power supply certified with a bronze or gold certificate or even higher, especially if you use the computer for long hours every day. Power supplies certified with a gold certificate may be a good option for the higher category, followed by the bronze certificate for the economic category. It is possible to suffice with a power supply of 450 watts to 500 watts, but the power and power of the provider depends specifically on your graphics card and its requirements, you may need a 750W provider If you are considering overclocking or purchasing an additional graphics card in the future, remember to make sure that the provider can provide current Real and make sure of its warranty period. We believe you are now ready to go and build your next platform.