As the world's most popular MOBA, League of Legends runs on a proprietary engine that has been updated for over a decade. Recently, Riot increased the minimum requirements to include AVX instruction support and dropped support for older OSs and DirectX 9. While still lightweight, modern team fights with complex particle effects can strain older integrated graphics. The game scales well with single-thread CPU performance, meaning even modern entry-level processors can deliver high frame rates.
Actual FPS may vary based on RAM speed, background processes, and other system factors
Performance Report
At 1080p, all quality settings exceed 177 FPS, suitable for 144Hz+ monitors. At 1440p, all settings exceed 133 FPS. At 4K, all settings exceed 88 FPS.
The GeForce GTX 1060 with Max-Q Design is 184% above the recommended GPU (GeForce GTX 560) for League of Legends. The Ryzen 7 7800X3D is 435% above the recommended CPU (Core i5-3330).
The GeForce GTX 1060 with Max-Q Design sets the FPS ceiling at all 1080p settings, all 1440p settings, all 4k settings, while the Ryzen 7 7800X3D still has additional frame-generation headroom.
Approximated average price on current market:
Combo price: $484. At 1080p Ultra, this combo delivers 177 FPS, equivalent to 0.37 FPS per dollar.
| Resolution | Low | Medium | High | Ultra |
|---|---|---|---|---|
| 1080p | 0.729 fps/$ | 0.585 fps/$ | 0.488 fps/$ | 0.366 fps/$ |
| 1440p | 0.548 fps/$ | 0.438 fps/$ | 0.366 fps/$ | 0.275 fps/$ |
| 4k | 0.366 fps/$ | 0.291 fps/$ | 0.244 fps/$ | 0.182 fps/$ |
* Table values represent FPS per Dollar (higher is better)
This section is based on estimated CPU/GPU FPS ceilings, not utilization percentages.
At 4k ultra, the GeForce GTX 1060 with Max-Q Design sets the ceiling at about 88 FPS, while the Ryzen 7 7800X3D has headroom up to 310 FPS. In this scenario, the GPU limits the CPU potential by 72% (FPS gap: 222 FPS). Overall distribution: GPU limits 12/12 cells, CPU limits 0/12, balanced 0/12.
Your GeForce GTX 1060 with Max-Q Design is the limiting side in the heaviest mismatch. This means part of the Ryzen 7 7800X3D frame-generation potential remains unused in those settings.
| Resolution | Low | Medium | High | Ultra |
|---|---|---|---|---|
| 1080p (Full HD) | GPU Limits CPU 50% | GPU Limits CPU 53% | GPU Limits CPU 53% | GPU Limits CPU 61% |
| 1440p (2K QHD) | GPU Limits CPU 62% | GPU Limits CPU 65% | GPU Limits CPU 65% | GPU Limits CPU 70% |
| 4K (Ultra HD) | GPU Limits CPU 69% | GPU Limits CPU 70% | GPU Limits CPU 70% | GPU Limits CPU 72% |
We estimate the maximum FPS the processor can sustain and the maximum FPS the graphics card can sustain in each setting, then compare those limits directly.
Limit Factor formula: (stronger - weaker) / stronger. Example: if CPU ceiling is 200 FPS and GPU ceiling is 140 FPS, then GPU limits CPU by 30%.
CPU Limits GPU means the processor ceiling is lower. GPU Limits CPU means the graphics ceiling is lower. Balanced means the FPS ceilings are close enough that the gap is negligible.
A component can still be the FPS limiter without reaching 100% utilization. The displayed percentages are derived from FPS ceilings, not generic utilization heuristics.
| Resolution | Low | Medium | High | Ultra |
|---|---|---|---|---|
| 1080p (Full HD) | CPU3% - 13% <> GPU77% - 95% <> | CPU5% - 20% <> GPU88% - 100% <> | CPU5% - 20% <> GPU88% - 100% <> | CPU5% - 19% <> GPU92% - 100% <> |
| 1440p (2K QHD) | CPU3% - 12% <> GPU78% - 97% <> | CPU5% - 19% <> GPU90% - 100% <> | CPU5% - 19% <> GPU90% - 100% <> | CPU5% - 19% <> GPU94% - 100% <> |
| 4K (Ultra HD) | CPU3% - 10% <> GPU73% - 93% <> | CPU5% - 17% <> GPU84% - 100% <> | CPU5% - 17% <> GPU84% - 100% <> | CPU5% - 17% <> GPU88% - 100% <> |
The Ryzen 7 7800X3D + GeForce GTX 1060 with Max-Q Design pairing runs this title with CPU utilization between 3% and 20% and GPU utilization between 73% and 100%. Ryzen 7 7800X3D keeps significant headroom across presets, while GeForce GTX 1060 with Max-Q Design carries most of the graphics load at heavier visual settings. As resolution scales, average GPU load rises from 93% at 1080p to 90% at 4K, while CPU averages move from 11% to 10%.
From a utilization perspective, this is a GPU-heavy load profile. At 1440p (2K QHD) Ultra, the GeForce GTX 1060 with Max-Q Design averages 97% usage (94-100%), while the Ryzen 7 7800X3D stays at 12% (5-19%). This shows the graphics pipeline is carrying most of the workload, but utilization alone does not define the FPS limiter.
At 1080p, averages sit around CPU 11% and GPU 93%. At 1440p, that shifts to CPU 11% and GPU 94%, and at 4K it reaches CPU 10% and GPU 90%. This shows that workload scaling is limited, which can indicate engine-side constraints.
1440p (2K QHD) Low is the most balanced preset based on this dataset. It runs around CPU 8% (3-12%) and GPU 88% (78-97%), which keeps GeForce GTX 1060 with Max-Q Design well utilized without constant max-out behavior while Ryzen 7 7800X3D remains stable for consistent frame delivery.
Upgrade priority should be the GPU. The GeForce GTX 1060 with Max-Q Design reaches 97% average load at 1440p (2K QHD) Ultra while the Ryzen 7 7800X3D still has headroom, so a faster graphics card would deliver the largest uplift.
Understanding Hardware Utilization: These percentages represent how much of your component's maximum processing power is actively being used during gameplay. They describe hardware load, but they do not directly tell you which component sets the FPS ceiling.
Important: a CPU or GPU can still be the FPS limiter without reaching 100% utilization. Two processors can both show 40% usage and still deliver very different frame rates, depending on per-core speed, cache, engine threading, driver overhead, and frame preparation efficiency.
Data generated by our Machine Learning engine trained on real-world benchmarks. Shows the approximate average utilization at each setting.
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 435% above and your GPU is 184% above the recommended specs. Ultra settings at 1080p, or High at 1440p/4K.
+435%vsrecommended
+184%vsrecommended
+1535%vsminimum
+1312%vsminimum
Yes, the Ryzen 7 7800X3D paired with the GeForce GTX 1060 with Max-Q Design can run League of Legends smoothly up to 4k achieving around 88 FPS at Ultra quality. Your GPU is 184% above the recommended specs, and your CPU is 435% above the recommended requirements.
This CPU + GPU combo costs approximately $484 ($384 CPU (Rank #212 Value) + $100 GPU). Since the GPU is the main limiting factor, investing in a stronger GPU will improve your framerates and overall value. For example, upgrading to the GeForce GTX 1080 SLI (móvel) (Rank #2 for value) could deliver noticeably better performance.
For League of Legends, upgrading the GPU would give you the most noticeable improvement. The GeForce GTX 1060 with Max-Q Design is the limiting factor here, while the Ryzen 7 7800X3D still has spare capacity. A more powerful GPU would unlock higher FPS, especially at higher resolutions and quality presets. GPU-limited at: 1080p low, 1080p medium, 1080p high, 1080p ultra, 1440p low, 1440p medium, 1440p high, 1440p ultra, 4k low, 4k medium, 4k high, 4k ultra.
League of Legends 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.
League of Legends requires at minimum a Core i3-530 (CPU) and GeForce 9600 GT (GPU) with 2 GB RAM and 16 GB storage. For the recommended experience, you need a Core i5-3330 and GeForce GTX 560 with 4 GB RAM. Your Ryzen 7 7800X3D and GeForce GTX 1060 with Max-Q Design both exceed the recommended specs, so you're well-positioned for a great experience.
These League of Legends 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.
