ANACOMDA G5 DDR5 RGB 6000 Gaming Memory Unboxing Review

ANACOMDA Anaconda has launched the Snake Nini Nini Limited Edition G5 DDR5 RGB 6000 32GB (16GBX2) memory with Intel XMP 3.0 and AMD EXPO Dual-Platform One-Click Overclocking Profile, but what's most appealing is the Nini Nini Nini Nini graphic printed on it!

ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBX2) Neon Secondary Memory Specs:

QVL Enquiry Serial No.: ?
Capacity: 32GB (2x16GB)
Speed: DDR5 6000 MT/s
Chronology: CL 36-36-36-76
Voltage: 1.35V
Specification: 288-Pin DDR5 UDIMM
Warranty: Lifetime Warranty
Dimensions: 148.5 mm x 8.2 mm x 39.8 mm (Length x Thickness x Height)
Profile Parameters: Intel XMP 3.0 Certification (Extreme Memory Profile), AMD EXPO Certification (EXtended Profiles for Overclocking)

ANACOMDA G5 DDR5 RGB 6000 32GB (16GBX2) Gaming Desktop Memory Unboxing

There's always a saying in Taiwan's computer community: "Give Snake Snake a chicken lung"! A few days ago, I saw someone share on a forum that ANACOMDA Python (also known as Snake Snake) had shelved the G5 DDR5 RGB 6000 32GB (16GBX2) gaming desktop RAM neon secondaries, and although the product name arrangement was strange, I was mildly interested when I saw the pattern.

ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBX2) Serpentine Limited Edition seems to be the only DDR5 6000 MT/s 2x16GB specification available on their official shrimp skin.

Snake Girl, NeNe. NeNe seems to be a secondary mascot made by ANACOMDA, maybe it's because I've seen too many cool memories, and this secondary pattern accidentally attracted my attention a little bit.

∆ ANACOMDA Anaconda DDR5 G5 PYTHON RGB LIMITED EDITION Serpentine. Neon Limited Edition.

∆ is currently only available in 6000 MT/s 32GB (16GBx2) specification.

∆ A list of the contents of the box.

 

ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBX2) Gaming Desktop Memory is 3.98 cm in height and features Neon Nini - a white heatsink with a Serpentine print and some blue cherry blossom patterns.

∆ Close-up of the pattern.

The back of the ∆ memory is the same pattern configuration plus an SN sticker.

 

The top part of the memory has an RGB light bar with ANACOMDA text, and the memory itself supports GIGABYTE, ASRock, ASUS, and MSI motherboard manufacturers' lighting control software to set the lighting effect.

∆ Branded text printed on the top of the memory.

∆ Top light bar lighting effect.

∆ Usual view angle display.

 

The unboxed G5 DDR5 RGB is specified as DDR5-6000 CL 36-36-36-76 1.35V 32GB (16GBX2), with SS (Single Sided) single cell and 1R (1 Rank) layout, and a single DRAM IC Count specification consisting of eight 2 GB (2048 MB) DRAM cells. The single DRAM IC Count specification consists of eight 2 GB (2048 MB) DRAM cells.

∆ SS (Single Sided) Single Sided particles, 1R (1 Rank), eight 2 GB (2048 MB) particles.

∆ It is a pity that the PMIC area is not equipped with thermal pads.

∆ Actual installation not energized for display.

 

AMD Ryzen 9 7900 and GIGABYTE B650I AORUS ULTRA Platform Memory Performance Tests

Using AMD Ryzen 7000 platform which supports DDR5 memory, to see how the memory performs on AMD platform, using AMD Ryzen 9 7900 processor and GIGABYTE B650I AORUS ULTRA (rev. 1.0) motherboard to test the performance and overclocking space of DDR5 memory, the motherboard BIOS is updated to F34b version for testing. The motherboard BIOS was updated to version F34b for testing.

Testing Platform

Processor: AMD Ryzen 9 7900 (PBO AUTO)
Cooler: AMD Wraith Prism
Motherboard: GIGABYTE B650I AORUS ULTRA (BIOS Version: F34b)
RAM: ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBx2) DDR5-6000 CL36-36-36-76 1.35V
Graphics: NVIDIA GeForce RTX 4060 Ti Founders Edition 8GB
Operating System: Windows 11 Professional 23H2
System Drive: Kingston A2000 NVMe PCIe SSD 500GB
Gaming Disk: Intel 670P 2TB M.2 2280 PCIe SSD (Solidigm)
Power supply:FSP Hydro PTM PRO ATX3.0 (PCIe5.0) 1200W
Case: STREACOM BC1 Benchtable V2

 

In the motherboard's BIOS, you can see that there are two profiles built into this set of memory, the DDR5-6000 CL36-36-36-76 1.35V for Profile 1 and the DDR5-5600 CL36-36-36-68 for Profile 2 can be used as a backup, but I think the 6000 frequency is basically fine for the current DDR5 motherboards. DDR5 motherboards basically have no problem with this frequency.

Both Intel XMP and AMD EXPO Profile parameter profiles are available, and the SPD information shows that the DRAM IC uses Samsung chips.

∆There are four built-in Profile profiles available, the PMIC uses Richtek, and Samsung particles are used.

 

由 CPU-Z Looking at the AMD Ryzen 9 7900 and GIGABYTE B650I AORUS ULTRA test platforms, the SPD page shows that the ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBX2) memory is based on Samsung cells and supports Intel XMP 3.0 (Extreme Memory Profile), AMD EXPO (EXtended Profiles for Overclocking) one-click overclocking profile. Memory Profile), AMD EXPO (EXtended Profiles for Overclocking) one-click overclocking profile.

∆ AMD platform CPU-Z.

 

utilization AIDA64 Cache & Memory Benchmark ANACOMDA G5 DDR5 RGB memory was tested at JEDEC frequency 4800 MT/s with read/write performance of 59,144 MB/s and 63,942 MB/s and latency of 94.8 ns.

With DDR5-6000 CL36-36-36-76 1.35V on EXPO Profile 1, the read/write performance is 78,294 MB/s and 78,410 MB/s with 71.7 ns latency.

∆ Default JEDEC Frequency: DDR5-4800 CL40-40-40-77 1.1V_AMD Platform Test Results.

∆ EXPO Profile 1: DDR5-6000 CL36-36-36-76 1.35V_AMD Platform Test Results.

 

OCCT Memory Benchmark Configuration The benchmark performance test, which is conducted on memory, yields three scores, each representing the memory's read performance, the memory's write performance, and the memory's performance in a simultaneous read/write test.

LATENCY / BANDWIDTH BENCHMARK CONFIGURATION represents the delay and bandwidth of the memory.

∆ EXPO Profile 1: DDR5-6000 CL36-36-36-76 1.35V_AMD Platform Test Results.

∆ EXPO Profile 1: DDR5-6000 CL36-36-36-76 1.35V_AMD Platform Test Results.

 

OCCT Memory Benchmark Configuration Benchmark performance testing of Custom mode, which graphically displays the latency, read, and write of the memory when tested at different file sizes (8 KiB to 4 GiB).

∆ EXPO Profile 1: DDR5-6000 CL36-36-36-76 1.35V_AMD Platform Test Results.

 

Memory Thermal Performance Test

And then through OCCT MEMORY CONFIGURATION To test the pressure stability of the memory, the memory load was manually set to 99% in the software, the memory test setting was set to memory EXPO Profile 1 parameter DDR5-6000 CL36-36-36-76 1.35V, and the test scenario was to conduct the actual test in a closed room with an indoor temperature of 19 °C, while the data was collected using HWiNFO64 to collect and record the temperature of the SPD Hub after 30 minutes of testing. The data was collected using HWiNFO64 to collect and record the temperature of the SPD Hub after 30 minutes of testing, with a maximum temperature of 53.5 °C. The test scenario was a closed room at 19 °C.

It is important to note that the test platform is placed on the STREACOM BC1 Benchtable V2 bare test platform, and the memory does not have an additional fan to assist in cooling, but most users will install an exhaust fan on top of the chassis to assist in the cooling process, the author's test environment and the test software are more severe than the daily use of the test software, so this side of the temperature test is only for reference.

∆ Fanless for OCCT MEMORY CONFIGURATION Temperature Stress Test, SPD Hub up to 53.5 °C.

 

Intel Core Ultra 9 285K and ASRock Z890 Taichi OCF Platform Memory Performance Tests

The Intel Core Ultra 9 285K test platform supporting DDR5 CKD memory and XMP 3.0 was used for the test. The motherboard used ASRock Z890 Taichi OCF and the BIOS was updated to version 2.26 AT08 to test the performance and overclocking capacity of DDR5 memory.

Testing Platform

Processor:Intel Core Ultra 9 285K (Power Delivery Profile_ASRock Extreme Mode)
Cooler: Valkyrie E360 (full speed)
Water-cooled fan: LIAN LI UNI FAN P28 (full speed)
Motherboard:ASRock Z890 Taichi OCF ( BIOS version: 2.26 AT08)
RAM: ANACOMDA Anaconda G5 DDR5 RGB 6000 32GB (16GBX2) DDR5-6000 CL36-36-36-76 1.35V
Graphics: NVIDIA GeForce RTX 4060 Ti Founders Edition 8GB
Operating System: Windows 11 Professional 24H2
System Drive: Plextor PCIe Gen3 x4 M.2 2280 SSD 512GB
Game Dish:XPG GAMMIX S70 PRO PCIe Gen4 x4 M.2 SSD 4TB
Power supply:FSP Hydro PTM PRO ATX3.0 (PCIe5.0) 1200W
Case: STREACOM BC1 Benchtable V2

 

By the same token CPU-Z to review the testbed specifications and information already available.

∆ Intel platform CPU-Z.

 

utilization AIDA64 Cache & Memory Benchmark ANACOMDA G5 DDR5 RGB memory was tested at JEDEC frequency 4800 MT/s with read/write performance of 74767 MB/s and 68900 MB/s with 110.5 ns latency.

With XMP Profile 1 on, the DDR5-6000 CL36-36-36-76 1.35V delivers read and write performance of 94018 MB/s and 83940 MB/s, with 96.4 ns latency.

∆ Default JEDEC Frequency: DDR5-4800 CL40-40-40-77 1.1V_Intel Platform Test Results.

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

 

OCCT Memory Benchmark Configuration The benchmark performance test, which is conducted on memory, yields three scores, each representing the memory's read performance, the memory's write performance, and the memory's performance in a simultaneous read/write test.

LATENCY / BANDWIDTH BENCHMARK CONFIGURATION represents the delay and bandwidth of the memory.

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

 

OCCT Memory Benchmark Configuration Benchmark performance testing of Custom mode, which graphically displays the latency, read, and write of the memory when tested at different file sizes (8 KiB to 4 GiB).

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

 

Intel MLC GUI V1.2.2.0 The graphical Intel Memory Latency Checker (Intel MLC) test software, created by some people on the Internet, is a non-official version of the software based on Intel MLC, which is a utility used to measure memory latency and bandwidth, as well as the variation with increasing system load. It also offers a variety of more detailed survey options, including the ability to measure the bandwidth and latency of specific cores to cache memory.

在 Quick The test results are shown in the item for bandwidth (MB/s) and delay (ns) results respectively, while the test results for Bandwidth The project will test different read/write ratio requests for memory to measure the resulting bandwidth (MB/s) performance.

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

 

Intel MLC GUI V1.2.2.0 的 Loaded_Latency The principle is to simulate the memory latency of the system when the CPU is performing computational tasks simultaneously. The purpose of the test is to quantify the effect of CPU load on memory access latency, and to help analyze and optimize system performance under real application scenarios.。

∆ XMP Profile 1: DDR5-6000 CL36-36-36-76 1.35V_Intel Platform Test Results.

 

Conclusion

This time I unboxed ANACOMDA Python G5 DDR5 RGB 6000 32GB (16GBX2) gaming desktop memory Snake Gee Limited Edition, I am not afraid to say: "I am interested in the memory printed with Nini Nini pattern", a little bit of a look at the fact that it is the DDR5 G5 PYTHON RGB memory and then printed on the Snake Gee pattern of the Limited Edition, the price is exactly the same as that of the two. The prices of the two models are exactly the same, but I see that the official website is not open, which may make it more difficult for consumers to find out more information.

This memory is only labeled with the XMP 3.0 Profile on the sales page, but when you actually look at the SPD file of the memory, you can see that the memory actually has the XMP and EXPO profiles, as well as a spare DDR5 5600 MT/s profile, although I don't think that this spare profile is used in any of the current platforms anymore. I don't think this spare profile will be used on any current platforms, though.

Overclocking from a JEDEC frequency of 4800 MT/s to 6000 MT/s on the AM5 platform, it gained 32.3 % of read performance, 22.6 % of write performance, 22.1 % of copy performance improvement, and further reduced latency by 24.4% in AIDA64 tests.

The LGA1851 platform from the JEDEC frequency of 4800 MT / s overclocked to 6000 MT / s, in the AIDA64 test obtained 25.7 % read performance, 21.8 % write performance, 25.1 % copy performance enhancement, and further reduce the latency time of 12.8%, but at present, the Z890 platform to measure the latency results are very high. However, the latency results measured on the Z890 platform are very high, and some people say that it's because of the platform architecture that I won't add much.

Originally, I was worried that heat dissipation would be the weak point of this memory since the memory itself does not have thermal pads in the SPD and PMIC areas, but the actual pressure test showed that the maximum temperature was only 53.5 °C, so it seems that we don't need to worry too much about heat generation under the specification of 6000 MT/s 1.35V.