When it comes to enhancing your computer's performance, maximizing the amount of RAM might seem like a logical step. However, using two sets of dual channel RAM can lead to stability issues and hinder your system's overall performance. In this article, we will explore the reasons why incorporating two sets of dual channel RAM may not be ideal, and provide alternative recommendations to ensure optimal stability and performance for your computer system. Understanding Dual Channel RAM: Dual channel RAM is a technology designed to improve memory bandwidth and speed in your computer system. It works by pairing two identical RAM modules, allowing them to operate together and deliver enhanced performance. With dual channel RAM, data can be accessed simultaneously from two memory modules, resulting in improved system responsiveness. The Drawbacks of Using Two Sets of Dual Channel RAM: Compatibility Issues and System Instability: When you opt for two sets of dual channel RAM, you effectively mix and match four different RAM modules. This mixing and matching can lead to compatibility issues, as the modules may not work seamlessly together. In turn, this can cause system instability, including frequent crashes, freezing, or difficulties in booting up your computer. Disabling the Dual Channel Feature: The primary purpose of dual channel RAM is to enhance memory bandwidth and speed. However, when you mix and match RAM modules, your system may revert to single-channel operation, disabling the dual channel feature altogether. This downgrade in memory performance can significantly impact your computer's overall speed and responsiveness. Recommendations for Ensuring Stability and Performance: 1. Utilize a Single Set of Dual Channel RAM: To mitigate compatibility issues and guarantee optimal stability and performance, we strongly advise using a single set of dual channel RAM. These RAM kits are specifically designed to work seamlessly together, ensuring compatibility and maximizing the benefits of dual channel technology. 2. Consider Purchasing a Higher Capacity Set: If you find yourself needing more RAM for your system, it is generally recommended to purchase a larger capacity set instead of adding a second set. By opting for a higher capacity set, you can maintain the advantages of dual channel technology while increasing your overall memory capacity. This approach minimizes the chances of compatibility issues and ensures that your system operates at its best. Conclusion: While it may appear tempting to use two sets of dual channel RAM to maximize your computer's performance, it can introduce compatibility issues and system instability. Mixing different RAM modules can disable the dual channel feature and lead to crashes or booting problems. Instead, we strongly recommend using a single set of Dual or Quad channel RAM that is designed to work harmoniously together. Alternatively, if you require more memory, it is advisable to invest in a higher capacity set rather than adding a second set. By following these recommendations, you can ensure both stability and optimal performance for your computer system during memory upgrades.
We recommend customers test the individual RAMs first to ensure whether any of them are damaged. If you determine that one of the RAMs is damaged, please refer to the TEAMGROUP RMA process to apply for repairs or contact TEAMGROUP customer service for assistance. If you determine that the RAMs are not damaged, please send an email containing a detailed description of your question and product information to the TEAMGROUP customer service inbox. Our tech department will respond as soon as possible.
1. ASUS (1) ASUS motherboard (AMD chipset/CPU) a. Open D.O.C.P i. Press “Delete” or “F2” to enter the BIOS. Then press F7 to enter “Advanced Mode”. ii. Press right arrow key to “Ai Tweaker”(Blue frame) and choose “Ai Overclock Tuner”(Green frame). Turn “Auto” into “D.O.C.P”(Red frame). iii. Press F10 to save the changes and exit the BIOS after completing steps above. b. Manual Overclocking Setting i. Press Delete or F2 to enter BIOS. After entering the BIOS, press F7 to enter Advanced Mode. ii. Press right arrow key to move to Ai Tweaker. Enter Memory Frequency to set the frequency you prefer. iii. After setting the frequency, go down to find DRAM Timing Control (red frame) and press “Enter”. iv. Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. v. Go back to the previous page after setting the CL value. Find DRAM Voltage and fill in the voltage you want. vi. Press F10 to save the changes and exit the BIOS after completing the steps above. (2) ASUS motherboard (Intel chipset/CPU) a. Open XMP i. Press Delete or F2 to enter BIOS. Then press F7 to enter Advanced Mode. ii. Press right arrow key to move to Extreme Tweaker(Red frame). Then choose Ai Overclock Tuner(Green frame). Change into XMP(Blue frame) and press F10 to save the data and then leave. b. Manual Overclocking Setting i. Press Delete or F2 to enter BIOS. Then press F7 to enter Advanced Mode. ii. Press right arrow key to move to Extreme Tweaker and find the DRAM Frequency(Green frame) below. Choose the frequency you prefer(Blue frame) and press “Enter”. iii. Find the DRAM Timing Control(green frame) and press enter after setting the frequency. iv. Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. v. Go back to the previous page and find DRAM Voltage(Green frame) after setting the CL value. Fill in the voltage in the DRAM Voltage. vi. Press F10 to save the changes and exit the BIOS after completing the steps above. 2. MSI (1) MSI motherboard (AMD chipset/CPU) a. Open D.O.C.P. i. Click “Delete” or “F2” to enter BIOS, and then click “F7” into advanced mode. ii. There are 2 ways to open D.O.C.P. (i) Click “A-XMP”(green frame), choose “2”, click F10 to save and then you can leave the page. (ii) Enter OC(green frame) on the left and switch “A-XMP” inside from “Disable” to “Profile2”(red frame), and click “F10” to save. Then you can leave the page. b. Manual Overclocking Setting i. Press "Delete" or "F2" to get into BIOS and press F7 to get into "Advanced Mode". ii. Get into "DRAM Frequency"(green frame) and choose the frequency (red frame). iii. After setting the frequency, click "Advanced DRAM Configuration" and fill in the CL value (green frame). iv. After setting the CL value, get into DRAM Voltage(green frame), fill in the voltage(blue frame). v. After doing the steps as above, press "F10" to save the settings. (2) MSI motherboard (Intel chipset/CPU) a. Open XMP i. Press "Delete" or "F2" to get into BIOS and press F7 to get into "Advanced Mode". ii. You have two choices to open XMP. (i) Click the A-XMP(red frame) on the top, transfer to "ON" and press F10 to save the settings. (ii) Get into OC(red frame), choose "Extreme Memory Profile (X.M.P)"(blue frame) and change from Disable to Enable. Then press F10 to save the settings. b. Manual Overclocking Setting i. Press "Delete" or "F2" to get into BIOS and press F7 to get into "Advanced Mode". ii. Get into "DRAM Frequency"(red frame) and choose the frequency(red frame). iii. After setting the frequency, choose "Advanced DRAM Configuration"(red frame). iv. Fill in the CL value(green frame) in Advanced DRAM Configuration. v. After setting the CL value, fill in the voltage(blue frame) in "DRAM Voltage"(green frame). vi. After doing all the steps above, press "F10" to save the settings. 3. Gigabyte (1) Gigabyte motherboard (AMD chipset/CPU) a. Open D.O.C.P. i. Click “Delete” or “F2” to enter BIOS. ii. Select M.I.T.(blue frame), select Advanced Memory settings(green frame) and then press “Enter”. iii. Select “Extreme Memory Profile(X.M.P.)”(red frame), press “Enter” to enter “Profile1”(blue frame). And then press “Enter” to check again. iv. Press “F10” to save and leave BIOS after finishing all the steps above. b. Manual Overclocking Setting i. Press “Delete” or “F2” to enter BIOS. ii. Switch to “M.I.T.”(blue frame), choose Advanced Memory Settings(green frame) and press “Enter”. iii. Select System Memory Multiplier(green frame), set the frequency(blue frame). For instance, input 28.00 if you’d like to set the frequency to 2800Mhz. At the moment, Memory Frequency(red frame) will automatically change into relative frequency. iv. After finishing setting the frequency, find “Memory Timing Mode”(red frame) below and switch “Auto” into “Manual”(green frame). v. Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. vi. After finishing filling in CL Value, back to the last page “M.I.T.” to find “Advanced Voltage Settings”(green frame) and then press “Enter”. vii. Select DRAM Voltage(red frame) and then select Voltage(blue frame). viii. After finishing all the steps above, press “F10” to save and leave BIOS. (2) Gigabyte motherboard (Intel chipset/CPU) a. Open XMP i. Press “Delete” or “F2” to enter BIOS ii. Switch to “M.I.T.”(blue frame), select “Advanced Memory Settings”(green frame) and press “Enter”. iii. Find “Extreme Memory Profile(X.M.P.)”(red frame), press “Enter” to enter “Profile1”(blue frame), and then press “Enter” again. iv. After finishing all the steps above, you can press “F10” to save and leave BIOS. b. Manual Overclocking Setting i. Press “Delete” or “F2” to enter BIOS. ii. Switch to “M.I.T.” on the above, select “Advanced Memory Settings” and press “Enter”. iii. Select “System Memory Multiplier”(green frame), set the frequency(blue frame). For instance, input 28.00 if you’d like to set the frequency to 2800Mhz. At the moment, Memory Frequency(red frame) will automatically change into relative frequency. iv. After finishing setting the frequency, select “Channel A Memory Sub Timings”(green frame). (Condition: Follow this step if you plug 2 sticks in the way from Motherboard’s Manual. If you plug in 4 sticks, please select “Channel A & B”.) v. After entering “Channel Memory Sub Timings”, switch “Memory Timing Mode”(green frame) from “Auto” to “Advanced Manual”(blue frame). vi. Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. vii. After finishing the setting of CL value, back to the last page “M.I.T.”, select “Advanced Voltage Settings”(green frame) and then press “Enter”. viii. After entering “Advanced Voltage Settings”, select “DRAM Voltage Control”(green frame) ix. Fill in the proper voltage(blue frame) in DRAM voltage. x. After finishing all the steps above, you can press “F10” to save and leave BIOS. 4. ASrock (1) ASRock motherboard (AMD chipset/CPU) a. Open D.O.C.P. i. Press Delete or F2 to enter the BIOS. ii. Press F6 to enter Advanced Mode (red frame) iii. Press right arrow key to OC Tweaker(green frame) and find Load XMP Setting(Red frame). Enter to choose XMP 2.0 profile 1(blue frame). iv. Press F10 to save the changes and exit the BIOS after completing the steps above. b. Manual Overclocking Setting i. Press Delete or F2 to enter BIOS. ii. After entering the BIOS, press F6 to enter Advanced Mode. iii. Press right arrow key to move to OC Tweaker and find DRAM Frequency (red frame). Enter to choose a frequency you prefer. iv.Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. v. Go back to the previous page after setting the CL value. Find DRAM Voltage and fill in the voltage. vi. Press F10 to save the changes and exit the BIOS after completing the steps above. (2) ASRock motherboard (Intel chipset/CPU) a. Open XMP i. Press “Delete” or “F2” to enter BIOS. ii. Press “F6” to enter “Advanced Mode”(red frame) after entering BIOS. iii. Press right arrow key to move to “OC Tweaker” (red frame). “Find DRAM Configuration”(blue frame) and press “Enter”. iv. Find “Load XMP Setting”(red frame). Press “Enter”, select “XMP 2.0 Profile 1” and press “Enter” again to confirm. v. Press “F10” to save the changes and exit the BIOS after completing the steps above. b. Manual Overclocking Setting i. Press “Delete” or “F2” to enter BIOS. ii. Press “F6” to enter “Advanced Mode”(red frame). iii. Press right arrow key to move to “OC Tweaker”(red frame). Find “DRAM Configuration”(blue frame) and press “Enter”. iv. Find the DRAM Frequency below and choose the frequency you prefer(blue frame). v. Find DRAM CAS# Latency and set the values according to your RAM specification as below in order. *The value on this screenshot doesn't represent all RAMs' setting. vi. Go back to the previous page after setting the CL value. Choose Voltage Configuration (red frame) to enter. vii. Fill in the voltage in “DRAM Voltage”(red frame) viii. Press “F10” to save the changes and exit the BIOS after completing the steps above.
“If my budget is only___, can I get a PC that can actually play games?” There are too many factors to consider for such a question, but if you don’t mind spending time on it, assembling it yourself is definitely more cost-effective than buying a finished PC. Today, we’ll recommend you the most suitable and affordable PC build on the market, and explain in order how to assemble the computer by yourself. Just follow the steps and you can build your own gaming PC! If you want to assemble your own gaming PC, first you have to know the list of parts you need to buy. The necessary parts include: 1. CPU, 2. Motherboard, 3. Memory, 4. Hard drive, 5. Graphics card, 6. Power supply 7. Case. In addition, you can get: 1. CPU Cooler, 2. Case fan, 3. Network card, etc. The main reason that CPU cooler is listed here is that the CPU comes with a fan, so it’s not a necessity. However, if it’s a large game load, it is recommended to buy a CPU cooler with a better cooling ability or a larger CPU cooler to control the CPU temperature to avoid overheating or crashing during the gameplay. 【All components for PC build】 A. CPU To make it affordable, the R5-3600X will be one of the best choices since AMD is a real bargain in the mid-range. The R5-3600X offers 6 cores and 12 threads. It has a basic clock of 3.8GHz and a boost clock of 4.4GHz, supports native 3200MHz memory, and is PCIe 4.0 SSD compatible. The expandability is excellent, and very few gamers will manually adjust the CPU or memory frequency. Learn more: https://www.amd.com/en/products/cpu/amd-ryzen-5-3600x B. Motherboard The new B550 series motherboard is definitely a blessing for gamers. In the past, the B series is quite different from the X series in terms of CPU overclocking, memory overclocking and I/O interface; The TUF Gaming B550 PLUS is highly compatible, close to the X570 level, and has a sleek military look, making it the best choice at this price range. Learn more: https://www.asus.com/Motherboards/TUF-GAMING-B550-PLUS/ C. Memory To keep the budget in check, try to avoid getting components that have RGB lighting. However, since it’s a gaming PC, the memory must be gaming style as well. We pick T-FORCE VULCAN Z 8GBx2 3200MHz. It looks like a mecha with a strong sense of gaming design, and 8GBx2 3200MHz is also very sufficient to run all kinds of games. Learn more: https://www.teamgroupinc.com/en/product/vulcan-z-ddr4 D. Solid state drive There are some tips on how to choose an SSD. Since we want to have enough speed and capacity while keeping my budget under control, we choose a 512GB TEAMGROUP MP33 PRO M.2 PCIe and a 512GB T-FORCE VULCAN G SATA 2.5” SSD, so the read/write processing is done in PCIe and data storage is stored in SATA to avoid purchasing expensive SSD that has both high speed and large capacity. Learn more: https://www.teamgroupinc.com/en/product/mp33-pro https://www.teamgroupinc.com/en/product/vulcan-g-ssd E. Graphics card As for graphics card, the ASUS TUF Gaming Geforce GTX1660 Super is a real bargain. Although the performance is not comparable to the ultra-high specification but over-budget RTX 3080, RTX 2080Ti, etc., but the 1660 Super is still the best choice in terms of Full HD quality. Learn more: https://www.asus.com/Graphics-Cards/TUF-GTX1660S-O6G-GAMING/ F. Remaining parts (Power supply, Case, CPU cooler) Among the remaining parts, you should pay attention that the use of a major manufacturer’s power supply with a better warranty, such as the durable CoolerMaster, will reduce the chance of burning out. The wattage should be sufficient to support PC’s normal operation. Generally speaking, it is recommended to choose a power supply of more than 650W for a PC build with a discrete graphics card. The case and the CPU cooler are basically the same as long as they are compatible. Anything that isn’t bad enough to become an oven can be considered. Learn more: https://www.coolermaster.com/catalog/power-supplies/mwe-series/mwe-gold-650-full-modular/ 【Installation Process】 Next is the installation process. How to make a cool PC build out of the scattered parts? Even if you are a total beginner, just follow these steps and you will be all set! 1. Install the CPU cooler base onto the motherboard Nowadays, many CPU coolers are designed to be used by both AMD and Intel, so the screws need to be slightly adjusted to align with the motherboard holes. You can refer to the attached manual for the adjustment. The manual of the Cooler Master Hyper 212 EVO CPU Cooler is quite detailed, so don’t worry! 2. Install the CPU in the motherboard Start by lifting the lever beside the CPU socket. Next, you need to pay attention to align the CPU correctly when placing it into the socket, otherwise the pin may be broken or burned. The motherboard and CPU are now equipped with foolproof mechanism, so you can install it correctly by following the arrows shown below. 3. Lock the power supply into the case From the front of the case, there is not much space on the right side, but if you open the right side panel, you will see a space below, this is where we will place our power supply. In most cases, the sockets and switches should face outwards and the air vents should face downwards, then lock the power supply from the back of the case. Also, since this is a non-modular power supply, which means the power supply itself is connected to a large bundle of wires, so it can be installed directly, but the downside is that it can’t be removed when there are too many wires. If you choose a “fully modular” power supply, since the wires need to be connected by yourself, you must make sure which wires are needed and connect them first and then lock the case, otherwise it won’t be easy to plug them after the case is locked! 4. Lock the motherboard tightly to the case Usually, the case has 9 screw holes corresponding to the holes of the motherboard, but not every motherboard will have 9 holes. As for myself, I usually lock 7 or 8 of them. When locking the motherboard, make sure that the CPU socket is on the top, so that the heat from the fan can be discharged out of the PC, and the graphics card will also have a place to put in. 5. Connect the power supply cable to the motherboard The most troublesome part of the installation is organizing the messy cables. We usually pull out the CPU power cable and the mother power cable from the reserved holes of the case and plug them into the motherboard. This can avoid leaving no room to plug in cables after other components have been installed. 6. Connect the front panel connectors of the case to the motherboard Almost all cases nowadays have 2~4 USB ports, power on/off and reboot buttons, etc. on the front panel. They all need to be powered and controlled by the motherboard. Since the wiring method of each motherboard is different, it is recommended to follow the user manual of the motherboard to connect them to the corresponding positions. The following is a brief introduction to the corresponding connection method of the TUF B550 PLUS motherboard. 7. Install rest of the parts on the motherboard Before installing, it is recommended to lay the case flat so that it can be screwed in easily. It can be installed in the order we are used to: Install the M.2 PCIe SSD first, then the CPU cooler to the base as mentioned in the first step, followed by the graphics card, memory, and finally the 2.5” SATA SSD. Most of the cases on the market still have the position of the 2.5” SSD on the power supply side, so the 2.5” SSD cable is usually the last thing we consider. Please note here that most mid-range and above discrete graphics cards also need to be connected to the PCIe power cable of the power supply! 8. Cable management The installation is almost complete! The rest is the most painful part: cable management. After installation, there will be a lot of messy cables, so you will need to find some cable ties to tidy them up and hide them out of sight. This is the part that requires more experience. 9. Install OS & update drivers Please support the genuine software when installing the OS. How to install the OS is explained in the “Tutorial of SSD Unboxing – The 6 Things You Should Do After Buying a New SSD”: https://www.teamgroupinc.com/en/info/ins.php?index_id=83 If you are lazy to search for the drivers, you can download Driver Booster. It has the latest drivers from major manufacturers and you can install them by one click: https://www.iobit.com/en/driver-booster.php Conclusion Here we explain the whole installation process, and introduce how to buy a PC for only $1,000, so that you can refer to according to different needs. All the selected products can be found on Amazon. T-FORCE VULCAN Z 3200 2x8GB: https://www.amazon.com/dp/B07QMM6NY3/ref=twister_B08L6D9P16?_encoding=UTF8&psc=1 T-FORCE VULCAN G SSD 500G: https://www.amazon.com/dp/B08F754NPR/ref=twister_B084H9RJ5S TEAMGROUP MP33 PRO 512GB: https://www.amazon.com/dp/B08GM9TQDB/ref=twister_B081CYW1B8 The installation process contains my own experience, and the order of the process is also based on convenience. Hope it will encourage new gamers to be more willing to try to build a PC by yourself!
The memory is going to enter the DDR5 era soon, which means that DDR4 technology is relatively mature. We've seen 8GB 3200MHz memory in stores and 32GB 4000MHz unboxing articles on forums. Comparing to three years ago, before AMD's rise to power, using 16GB 3600MHz memory with I7-8700K was already very luxurious then. DDR4 technology is much more mature than it was a few years ago, but there are times when you are so excited buying new memory, only to encounter various problems after getting it home. Today, we'll help solve some frequently asked questions to you. 1. Compatibility issues The IC, PCB, and Layout used are different for different memory manufacturers, models and specifications. Therefore, the memory QVL (Qualified Vendor List) is required to be verified for compatibility before the memory is released. The following screenshots are for reference. Usually, the QVL information is located on the motherboard page -> Support -> Memory However, there are numerous kinds of motherboards, and a motherboard manufacturer may produce 4 or 5 types of motherboards from a type chipset. With such a large number, manufacturers will prioritize upgrading newer chipsets. As the number of users of older chipsets gradually decreases, and as consumers using older chipsets usually have DRAMs that will not be upgraded, therefore manufacturers will assume that motherboards before a certain generation of the chipset will not support new ICs or specifications. In this case, if you buy a new memory and install it in the old computer, or use the new memory together with old memory, there may have incompatibility problems. Solution: Please refer to the motherboard's QVL List before buying the memory. Generally speaking, you only have to verify if the list has information such as (1) The memory manufacturer you wish to select. (2) What capacity is supported? (3) What frequency is supported? (4) How many sticks of memory can it install? It doesn't matter if the general public doesn't understand the external material number and CL value. Also, please avoid purchasing a new memory and use it with old ones that were bought a long time ago. Not only the difference of specification may cause incompatibility issues, but even products with the same specification may also be incompatible due to different ICs used in different periods. It is more effective to replace the entire set of memory if you want to upgrade. TEAMGROUP's memory will be sent to the motherboard manufacturer for verification during the development phase, and the memory will be left at the motherboard manufacturer so that it can be verified as soon as a new motherboard is released. TEAMGROUP memory is a reassuring choice thanks to the multiple verification of avoiding incompatibility issues. Here we provide some QVL list from specific motherboards for your reference. ASUS: https://www.asus.com/Motherboards-Components/Motherboards/All-series/TUF-GAMING-X570-PLUS-WI-FI/HelpDesk_QVL/ MSI: https://www.msi.com/Motherboard/support/MEG-X570-ACE#support-mem-19 GIGABYTE: https://www.gigabyte.com/Motherboard/X570-AORUS-MASTER-rev-11-12/support#support-doc ASRock: https://www.asrock.com/mb/AMD/X570%20AQUA/Specification.asp#MemoryMS 2. Overclocking issues This is a complicated question with no fixed answer. It involves the relationship between CPU, motherboard and memory. There are too many scenarios, so here is some basic logic for reference. The most frequently heard questions are: (1) I bought a 3200MHz memory, but why does it only run at 2400MHz? (2) Your specification indicates that it can go up to 4000MHz but no matter how I overclock it, it is only 3600MHz? (3) If I buy a 3200MHz product, is it guaranteed to overclock to 4000MHz? First of all, if you have a question about overclocking, be sure to provide the motherboard model, CPU model, BIOS version you are using to help us determine the situation accurately. Otherwise, any answer that is not based on comprehensive judgment is invalid! Solution: (1) For frequency issues, the first thing to consider is whether the maximum frequency supported by the motherboard meets the specification of the memory you bought. Generally, just click on the SPEC page on the motherboard and scroll down to Memory and you will see the details. (2) CPU support After all, overclocking is not a standardized specification, which means only referring to the specifications listed on the INTEL and AMD websites is not enough. It takes experience to know how much memory frequency can be overclocked by the CPU. Different motherboards will have different results, but in general the higher the CPU is, the higher the memory frequency can be overclocked. The following is a brief explanation of overclocking. For INTEL, I recommend selecting products with K at the end of the model, such as I9-10900K, I7-10700K. For AMD, I recommend picking products with X at the end of the model, such as R9-3900X, R5-3600X. If your CPU doesn't happen to fall into one of the above categories, your memory frequency may be limited to be overclocked. (3) BIOS version This is the most overlooked problem. Sometimes memory supportability will be corrected during BIOS update process, and if the older version has not been updated, the memory frequency may be limited. BIOS update can be downloaded from the official website of the motherboard manufacturer. It is recommended that for those who have not updated before, go check out the update SOP provided by the motherboard manufacturer first, because errors in the process may cause the entire motherboard to fail! (4) Check the actual representative type of the specification label It means to determine whether the frequency indicated on the memory package is the native JEDEC standard frequency, or is the frequency after XMP is enabled. JEDEC is an international solid-state technology association that sets different parameters for different frequency bands of memory. As long as the memory is produced following JEDEC standard, consumers do not need to do anything after purchasing the memory, just plug the memory onto the motherboard to meet the specifications on the package. The other type requires XMP, which is classified as an overlocking product. After buying it home, the most basic way to do is to go into the BIOS and enable XMP, and then let the motherboard read the SPD value in the memory and automatically overclock to the frequency indicated on the package. Just google JEDEC and frequency you are looking for, you will find the corresponding CL value on web pages. If the frequency and CL value of the memory you purchased match, it means it is the frequency within JEDEC standard and you can use it immediately by plugging it in. If the CL value of the memory you bought is below the JEDEC standard, then it is the type required XMP. Please note that not all motherboards can support the latest JEDEC standard frequency! Recently, JEDEC 3200MHz memory is slowly appearing on the market, but only the latest motherboard chipsets support this frequency, including the INTEL Z490, Z390, AMD TRX40, X570, B550. Therefore, if your motherboard chipset is not among them, you need to check the type of memory you purchase. Another situation is when the memory belongs to the type that requires XMP, but you haven't gone into the BIOS to enable XMP after buying it home, then it will only display the frequency without being overclocked. That is why many consumers bought 3600MHz home, but only showen 2400MHz. 3. Fully equipped with 4 modules often do problems. For optical reasons, many would like to have all RAM banks equipped on the motherboard. Since everything with the X470 / X570 or Z390 or Z490 is designed for dual channel and two ram modules would be sufficient for this, problems often arise when using four modules. A solution approach is, for example, that you only plug two modules on the mainboard and activate XMP. When the mainboard starts up and the XMP settings have been correctly applied, you can increase the memory controller voltage in the BIOS / UEFI. With AMD it is the SOC voltage and with INTEL the VCCIO voltage. Increases the voltage in small steps (0.05V steps). Save the setting and switch off the PC. Then plug the remaining two modules onto the motherboard and turn the PC back on. If everything works, the PC should start and the frequencies set in the XMP should be displayed. The background is that the memory controller is more loaded with four RAM modules (AMD external and Intel internal) and therefore requires a higher voltage for correct function. But remains in the motherboard specifications for the maximum voltages suitable for everyday use. If you have a lot of problems, take a look here https://linustechtips.com/forum/5-cpus-motherboards-and-memory/ 4. DOA problem Dead On Arrival, abbreviated as DOA, means damaged on arrival. This can happen with any electronic products, not just memory, which means that you can't avoid it completely as long as it is an electronic product. After all, the transportation environment or changing factors are unpredictable after they leave the factory. However, don't worry, as long as it is a DOA and you have proof of purchase, the manufacturer will usually let you replace it with a new one to ensure consumers' rights.
These settings are only from our recommendation. They don’t mean the must do or have Below are some very simple steps for setting up Team group DRAM module for desired frequency on the Asus ROG Crosshair VI Hero, Bios 3008. Because the IMC characteristics of Ryzen are way different from Intel, we decided to write this article to provide you some suggestions of how to set AMD Ryzen system easily and properly. :D!Currently we just find out this way will make your Ryzen system and our products work together easier. https://www.teamgroupinc.com/en/products/t-force/gaming-memory/ Environment: Motherboard: ASUS ROG Crosshair VI Hero Bios 3008x64 CPU: Ryzen 5 1600X Storage: T-FORCE CARDEA 240GB DRAM: TEAM GROUP DARK PRO DDR4 3200mhz C14 OS: Microsoft Windows 10 Professional x64 RS3 Memtest windows pro 3 Example for how to set up our DRAM modules for DDR 3200 on the AMD Ryzen system. First, choose Manual (Please don’t use DOCP) Set BCLK frequency at 100 Choose 2133/2400/2666MHz as memory frequency divider Next, go back and adjust the BLCK frequency again. When you change the BCLK value, the memory frequency changes as well. Therefore, you can raise the BCLK value to reach desired DDR frequency. Set the primary timings. Last, adjust the CPU and DRAM voltage. We advise you to set it at 1.35V when using 3000mhz or higher frequency RAM, and 1.2V when using under 3000MHz RAM. After that, save BIOS and you are done for all! Hope this would help you. If you have other question, please feel free to ask!
Refer to the user manual of the motherboard. The additional setting is unnecessary because BIOS on the motherboard would detect SPD parameters on Memory Modules automatically after the memory has been installed.
With the help of some software tools, you can detect memory settings from Windows XP. These may include the CPU-Z, SiSoft Sandra and EVEREST. In addition, SiSoft Sandra and EVEREST are equipped with the efficiency verification solution to further validate whether or not the performance based on the SPD settings is achieved.
Have you ever encountered installing or boot issue while using the memory? Do you know how to use the memory correctly? Let’s introduce the simple memory debugging process now! 1. Installation method The correct hand position for installing the memory can ensure the force on the gold contacts of the memory is even to avoid damage. When installing the memory, make sure there’s no dust or foreign objects on the gold contacts of the memory and the motherboard slots. Foreign objects or dander might easily burn the memory. 2. PC won’t boot (Cannot enter BIOS) First, refer to the order of the motherboard memory slot. → Install the memory (single or dual channel) in the correct memory slots of the motherboard. → Check if it can boot normally. →dual channel →single channel The memory slots of each brand of the motherboard have a custom order. Please refer to the manual of the motherboard. If already installed in the correct position but still can’t boot. → Install a single memory in a slot of the motherboard in turns for testing. → Find out which memory has a problem / If the problem that the PC is unable to boot has been confirmed, please contact the manufacturer for repair. Cross test to see if there is a problem with the memory slots of the motherboard. → Install the memory that works normally in DIMM1~DIMM4 in turns to see if all DIMM slots are working. If there’s another motherboard available → Install memory on the different motherboard to see if it’s working normally. → If it is still not working, it can be inferred that it is caused by the memory. 3. RGB lighting issue If RGB memory’s lighting is not working, it is mostly caused by the LED lightbulbs. It should be sent for repair directly. If RGB memory’s lighting cannot be controlled, please install and test with only one RGB software, or update RGB software to the latest version. While testing, please make sure other software is completely uninstalled. Please do not use alcohol or eraser to clean gold fingers.