Minecraft
The Java version is inefficient and single-thread bound, often bottlenecking on the CPU unless you use performance mods. The Bedrock edition is optimized in C++ and runs much better. For Java, the CPU is king.
Actual FPS may vary based on RAM speed, background processes, and other system factors
Performance Report
At 1080p, all quality settings exceed 322 FPS, suitable for 144Hz+ monitors. At 1440p, all settings exceed 304 FPS. At 4K, all settings exceed 217 FPS.
The GeForce RTX 5090 is 1947% above the recommended GPU (GeForce 700 Series) for Minecraft. The Xeon 6747P is 1721% above the recommended CPU (Core i5-4690).
The GeForce RTX 5090 sets the FPS ceiling at 1080p (medium/high/ultra), all 1440p settings, all 4k settings, while the Xeon 6747P still has additional frame-generation headroom. The FPS ceiling is closely matched at 1080p low.
Approximated average price on current market:
Combo price: $9197. At 1080p Ultra, this combo delivers 322 FPS, equivalent to 0.04 FPS per dollar.
| Resolution | Low | Medium | High | Ultra |
|---|---|---|---|---|
| 1080p | 0.141 fps/$ | 0.108 fps/$ | 0.061 fps/$ | 0.035 fps/$ |
| 1440p | 0.127 fps/$ | 0.098 fps/$ | 0.056 fps/$ | 0.033 fps/$ |
| 4k | 0.080 fps/$ | 0.062 fps/$ | 0.038 fps/$ | 0.024 fps/$ |
* Table values represent FPS per Dollar (higher is better)
Affiliate Disclosure
ChipVERSUS is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to Amazon.com. We may earn a commission on qualifying purchases made through our links. This comes at no additional cost to you and helps support our work in providing comprehensive PC building guides and tools.
Amazon and the Amazon logo are trademarks of Amazon.com, Inc. or its affiliates.
This chart answers a simple question: which upgrade is more likely to increase FPS first? In this case, the answer is the GPU.
The largest gap appears at 4K Medium, where the GeForce RTX 5090 reaches about 389 FPS, while the Xeon 6747P still has headroom up to roughly 571 FPS.
That means the GeForce RTX 5090 is hitting its performance ceiling first, leaving a 32% gap versus the Xeon 6747P's available headroom in the most unbalanced scenario. Across all tested settings, this pairing is GPU-limited in 11 out of 12 cases, with 0 CPU-limited and 1 balanced results.
Overall, this is a GPU-limited combination in this game.
The GeForce RTX 5090 is usually the limiting part in this game, so upgrading the GPU is more likely to deliver a larger FPS gain than upgrading the CPU.
This chart shows which upgrade is more likely to unlock more FPS in each tested setting. The lower line represents the part that reaches its limit first. When the CPU and GPU lines stay close together, the system is more balanced. When the gap widens, one component is more clearly holding the other back. Hover any setting to inspect it.
The lower line is the current limiter. The closer the two lines are, the more balanced the CPU and GPU are for this game.
Each line represents an estimated FPS ceiling for one component, rather than live usage alone.
To estimate the CPU ceiling, we pair the Xeon 6747P with GeForce RTX 5090, our current GPU anchor. To estimate the GPU ceiling, we pair the GeForce RTX 5090 with Ryzen 9 9950X3D, our current CPU anchor.
The lower line indicates the current limiter, since that component reaches its FPS ceiling first. In most scenarios, that is also the part most likely to deliver the bigger performance uplift if upgraded first.
The percentage shown represents the gap between the two ceilings. In practical terms, it shows how much of the stronger component's potential is left unused because the weaker one becomes the bottleneck first.
See how your processor and graphics card compare against the game official minimum and recommended system specs. The placement of your hardware is calculated using relative synthetic performance scores to help you gauge overall playability.
Your CPU is 1721% above and your GPU is 1947% above the recommended specs. Ultra settings at 1080p, or High at 1440p/4K.
+1721%vsrecommended
+1947%vsrecommended
+3064%vsminimum
+40386%vsminimum
Yes, the Xeon 6747P paired with the GeForce RTX 5090 can run Minecraft smoothly up to 4k achieving around 217 FPS at Ultra quality. Your GPU is 1947% above the recommended specs, and your CPU is 1721% above the recommended requirements.
This CPU + GPU combo costs approximately $9,197 ($6,497 CPU + $2,700 GPU). Your GeForce RTX 5090 provides phenomenal top-tier performance but at a premium enthusiast price. Since you are essentially at the ceiling of current hardware capabilities, there are no meaningful performance upgrades available. However, if you wanted a more cost-effective build that still delivers a great experience, you could theoretically step down to a high-end card with a significantly better value rating.
Your GeForce RTX 5090 is already a top-tier graphics card. In the Performance Limiter Analysis, it is still the side that most often reaches its FPS ceiling first, but there is no meaningful upgrade path that would drastically improve your Minecraft performance right now. The main bottleneck appears on the GPU side. The largest gap shows up at 4K Medium, where the GPU reaches about 389 FPS while the CPU still has headroom up to roughly 571 FPS. Across all tested settings, the distribution is 11/12 GPU-limited, 0/12 CPU-limited, and 1/12 balanced.
Minecraft does not currently support Frame Generation technologies like DLSS 3 or FSR 3. Your performance is based entirely on native rendering. If the game adds support in a future update, newer GPUs will benefit the most.
Minecraft requires at minimum a Core i3-3210 (CPU) and GeForce 400 Series (GPU) with 2 GB RAM and 1 GB storage. For the recommended experience, you need a Core i5-4690 and GeForce 700 Series with 4 GB RAM. Your Xeon 6747P and GeForce RTX 5090 both exceed the recommended specs, so you're well-positioned for a great experience.
These Minecraft FPS results are not arbitrary numbers. They come from calculations informed by thousands of real gaming benchmarks, and the typical accuracy range is around 10% to 15%. That makes them far more useful than generic FPS calculators that simply invent values without a benchmark foundation. Actual in-game performance can still vary with drivers, updates, RAM configuration, cooling, and the exact scene being rendered.
Performance estimates are based on synthetic benchmarks and hardware capabilities.
Results may vary based on drivers, OS, and background processes.
