What is the best resolution for FPS and quality?

For competitive FPS titles like Valorant and CSGO, 1080p remains king. Higher resolutions like 1440p or 4K offer increased detail, but the performance hit often outweighs the visual benefits in fast-paced gameplay. The larger, clearer visuals at 1080p give you a crucial edge – quicker target acquisition is paramount. Less demanding on your hardware, 1080p allows for higher refresh rates (like 240Hz or even 360Hz), resulting in smoother gameplay and a significant competitive advantage. This translates to faster reaction times and improved accuracy, crucial factors in high-stakes matches. The trade-off in visual fidelity is negligible compared to the massive performance gain and the resulting competitive edge. Ultimately, maximizing frame rate and minimizing input lag is more important than pixel density in professional-level FPS gaming.

What graphics settings affect FPS the most?

Alright gamers, let’s talk FPS. The biggest hitters, the settings that’ll tank your frame rate faster than a noob in a PvP match? Shadows, hands down. You’ve got your basic shadow volumes, which chew up CPU like crazy, and then you’ve got the fancy pants stuff like ray tracing, which is a GPU-muncher of epic proportions. Dial those down first. Seriously, even medium settings can make a huge difference.

Next up: anti-aliasing. Jaggies are annoying, but smooth edges are a luxury. TAA (Temporal Anti-Aliasing) looks great, but it’s a performance hog. MSAA (Multi-Sample Anti-Aliasing) is less demanding but can still impact FPS. Experiment and find a balance.

Dynamic reflections – beautiful, but brutal on performance. If you’re seeing puddles that look like a mirror reflecting the entire environment, you know where to cut back. Same goes for ambient occlusion – those realistic shadows in crevices? Performance killers. Lower the quality or disable them entirely if needed.

Volumetric lighting – think fog, smoke, and those awesome light shafts. Looks amazing but demanding. Turn down the quality or density. Motion blur is another culprit. It’s a cinematic effect, but it’s often unnecessary and takes a toll. Disable it for a significant FPS boost.

Finally, render scaling. This one is a game changer. Running at a lower resolution and upscaling it with a good technique will give you a significant FPS increase while maintaining a pretty sharp image. It’s a bit of a dark art, but well worth exploring for better performance. Remember, even a small drop in settings can make a big difference!

Does a better graphics card help with FPS?

Yeah, a better graphics card, or GPU, is a HUGE deal for FPS. Think of it like this: your CPU is the brain, figuring out what’s happening, but the GPU is the artist, painting the picture on your screen. A more powerful GPU can handle higher resolutions, more complex shaders (that’s the fancy word for the visual effects), and more objects on screen all at once without stuttering. That translates directly to higher frame rates, smoother gameplay, and less tearing (that annoying visual glitch). You’ll notice the difference especially in graphically intensive games, and even older games can benefit from improved visuals and performance. It’s not just about raw FPS though; a better GPU allows for higher settings like anti-aliasing, making everything look sharper and cleaner, further enhancing the experience. So yeah, upgrading your GPU is almost always worth it for a better gaming experience. Keep in mind though that CPU bottlenecks can limit the gains from a top-tier GPU, so balance is key.

Does a better graphics card give you better FPS?

A better graphics card almost always translates to higher FPS, but it’s not a simple one-to-one relationship. The impact depends heavily on other system components and game settings.

GPU Bottlenecks: A powerful GPU paired with a weak CPU or insufficient RAM can still result in performance limitations. The CPU might struggle to feed the GPU enough data, creating a bottleneck and limiting FPS gains. Similarly, insufficient VRAM (video RAM) can force the GPU to use slower system RAM, significantly impacting performance.

Game Engine Optimization: Some games are better optimized than others. A top-tier graphics card might show marginal improvements in a poorly optimized title compared to a significantly larger jump in a well-optimized game.

Resolution and Settings: Higher resolutions (like 4K) and increased graphical settings (high textures, ray tracing, etc.) demand far more processing power. A better graphics card is crucial for maintaining high FPS at these settings. Lowering settings can drastically improve FPS on less powerful hardware.

Specific Examples:

Ray Tracing: This demanding rendering technique significantly impacts FPS, and a powerful GPU is absolutely essential for acceptable performance.
High Refresh Rate Monitors: To fully utilize a 144Hz or 240Hz monitor, you need a graphics card capable of consistently delivering frame rates above the refresh rate to avoid screen tearing.

In short: Yes, a better graphics card generally leads to better FPS. However, achieving optimal performance requires a balanced system, smart game settings, and an understanding of potential bottlenecks.

Is native resolution best for gaming?

Unlock the ultimate gaming experience by playing at your monitor’s native resolution! This is the resolution your screen is designed for, resulting in the sharpest, crispiest image possible. Think of it like this: it’s the difference between a perfectly printed photograph and a blurry photocopy.

Why Native Resolution Reigns Supreme:

Unmatched Clarity: Every pixel is used exactly as intended, avoiding any scaling or interpolation that can blur details.
Enhanced Detail: See textures, characters, and environments in their full glory. Notice those subtle details you might miss at lower resolutions.
Improved Performance (Sometimes): While it might seem counterintuitive, playing at native resolution *can* sometimes improve performance, especially on lower-end systems, by reducing the processing load of upscaling.

Downsides of Non-Native Resolutions:

Blurriness and Jaggies: Scaling up from a lower resolution introduces blurriness and jagged edges, detracting from the visual experience.
Increased Processing Load: Your GPU has to work harder to upscale the image, potentially impacting frame rates.
Performance Bottlenecks: This increased processing can create noticeable stutters and lag, ruining the flow of gameplay.

When to Consider Non-Native Resolutions:

While native resolution is generally best, you might compromise if your hardware struggles to maintain a smooth frame rate at native resolution. Consider lowering settings before dropping the resolution.

Does higher FPS mean better quality?

Let’s dive deep into the FPS rabbit hole. A higher frame rate (FPS) means more frames are displayed per second. Think of it like this: each frame is a single image. Higher FPS = more images per second = smoother motion. This directly translates to a superior visual experience, drastically reducing that annoying motion blur you see in lower frame rate footage. It’s the difference between watching a flipbook with 10 pages versus 100 – the latter is fluid and natural, while the former feels jerky and discontinuous.

Now, the impact on “quality” is multifaceted. It’s not just about smoothness. Higher FPS allows for more accurate representation of fast-paced action. Imagine trying to film a racing car at 24 FPS versus 120 FPS. At 24 FPS, the car might appear blurry and its movement difficult to track. At 120 FPS, you capture every detail of the car’s movement, enhancing the overall perception of quality and realism. The implications ripple into other areas like post-processing and editing; having more frames to work with gives you far more flexibility.

Conversely, low FPS results in the dreaded choppiness, that stuttering effect that kills immersion and makes the visuals look cheap. The motion appears unnatural, and the reduction in detail during motion makes the image appear less crisp. It’s a significant drop in visual fidelity. While image resolution (like 1080p or 4K) dictates sharpness, FPS governs how smoothly that sharpness is displayed over time. They work together, but FPS is the crucial factor for fluid motion.

In short: Higher FPS isn’t *just* about better quality, it’s about superior motion clarity, reduced blur, increased visual fidelity, and a more immersive viewing experience. Low FPS compromises all of this.

How to optimize GPU for FPS?

Alright, listen up, rookies. Optimizing your GPU for FPS isn’t some casual Sunday stroll; it’s a hardcore overclocking marathon. Forget gentle nudges; we’re talking aggressive performance boosts.

First, the basics:

Max out your thermal limits. Your card’s got to breathe fire; don’t choke it. But monitor temps religiously – hitting thermal throttling means you’ve pushed too hard. Use monitoring software, not just in-game overlays.
Power Limit Bump: A 10% increase is a starting point. Some cards handle more, some less. This directly impacts how much juice your GPU can draw and therefore how hard it can push.
Core Clock Boost: Start with a +50MHz bump. This is where the real gains are. But listen to your hardware – instability shows up as crashes, artifacts, or outright freezes. Don’t ignore warnings.

Fine-tuning is key:

Stress Test: Use a robust tool like OCCT or FurMark (but be cautious; high temps are expected, but sustained high temps are dangerous). Run it for at least 30 minutes at your target resolution and settings. Monitor temperatures and stability.
Incremental Adjustments: If stable, increase the core clock by 10MHz increments and repeat the stress test. This meticulous approach is the only way to discover your GPU’s sweet spot. It’s a slow process but crucial for long-term stability.
Memory Clock Tuning (Advanced): Don’t forget about memory overclocking! Similar incremental increases can yield further performance gains, but this often needs more precise control and is more prone to instability. Only attempt if comfortable with advanced tuning.
Voltage Tweaking (Expert): This is the final boss. Increasing voltage can help push clocks higher, but it significantly increases heat and power consumption. Proceed with extreme caution; improper voltage adjustments can damage your hardware permanently. Only for experienced overclockers who understand the risks.

Remember: Every GPU is unique. What works for one might brick another. Always prioritize stability over raw clock speed. A stable, slightly lower clock is far better than an unstable, super-high one. And always back up your BIOS settings!

Should I prioritize FPS or resolution?

It’s a classic gamer dilemma, FPS vs. resolution. For competitive games, like shooters or fighting games, higher FPS is king. That extra smoothness translates directly to better reaction time and a competitive edge. Think 144Hz or even higher refresh rate monitors – the difference is night and day. You’ll spot enemies quicker, react faster, and generally play more effectively. The visual fidelity takes a backseat; you’re prioritizing performance.

On the other hand, single-player RPGs or adventure games often benefit more from higher resolution. The increased detail in textures and environments enhances immersion. A buttery smooth 60fps is usually enough; you’re not aiming for lightning-fast reactions here. Stunning visuals are the focus. It’s all about what kind of experience you’re chasing.

Ultimately, the “best” setting depends on the game and your hardware. High-end systems can often handle both, but budget builds usually require compromises. Experiment with different settings to find the sweet spot where the visual quality is good enough without sacrificing too much performance. Many games have built-in benchmarks to help you optimize settings. Don’t forget about other settings too – shadows, anti-aliasing, and texture quality are all big performance hitters.

What bitrate for resolution and FPS?

Bitrate selection for esports streaming hinges on resolution and frame rate, directly impacting viewer experience and bandwidth consumption. A suboptimal bitrate can lead to noticeable compression artifacts or buffering issues.

720p (1280×720): This resolution offers a balance between quality and bandwidth efficiency. A standard 24-30fps stream comfortably sits around 6.5Mbps. However, for smoother gameplay crucial in fast-paced esports titles, increasing the frame rate to 48-60fps necessitates a higher bitrate, ideally 9.5Mbps. Even with this increase, 720p remains a viable option for viewers with lower bandwidth.

1080p (1920×1080): While delivering superior visual fidelity, 1080p demands significantly higher bitrates. Expect 12-15Mbps for 30fps and 18-24Mbps for 60fps. This increased bitrate is justified by the enhanced detail, vital for discerning quick movements and subtle tactical elements often present in competitive gaming.

4K (2160p): 4K is increasingly relevant in esports, providing breathtaking visuals, but comes at a substantial bandwidth cost. Low frame rates (24-30fps) require 44-56Mbps, while high frame rates (60fps and above) necessitate 65-85Mbps or even higher. This high bitrate requirement is often a limiting factor, especially for viewers with limited internet connectivity. Careful consideration must be given to the target audience and their average bandwidth capabilities.

Factors Beyond Resolution & FPS:

Encoder: Different encoders (x264, x265, NVENC, etc.) have varying compression efficiency, influencing the required bitrate for a given quality level.
Content Complexity: Scenes with rapid motion, significant detail (e.g., explosions, particle effects), and high color variations demand higher bitrates to prevent artifacting.
Adaptive Bitrate Streaming (ABR): ABR dynamically adjusts the bitrate based on viewer bandwidth, providing a smoother viewing experience across diverse internet connections. This is crucial for maximizing audience reach.

Practical Recommendations: Start with slightly lower bitrates and gradually increase until you find the optimal balance between visual quality and bandwidth efficiency. Regularly monitor your stream’s performance metrics to identify any potential issues and optimize accordingly.

Is VSync good or bad?

Vertical Synchronization (VSync) is a feature that synchronizes your monitor’s refresh rate with your GPU’s frame rate. This means your GPU will only render a frame when your monitor is ready to display it. This prevents screen tearing, a visual artifact where the top and bottom halves of the screen display different parts of the same frame, resulting in a jagged, unpleasant look. For games where visual fidelity is crucial, like cinematic experiences or story-driven adventures, VSync’s elimination of tearing is a huge benefit, leading to a smoother, more visually appealing experience. Think of games with stunning landscapes or detailed character models – VSync really shines here.

However, VSync introduces input lag. This delay between your input (e.g., pressing a button) and the game’s response is caused by the synchronization process. The delay might be only a few milliseconds, but in fast-paced games like competitive first-person shooters or fighting games, where reaction time is critical for success, even a small amount of lag can significantly impact your performance. The difference between winning and losing can hinge on those precious milliseconds. For these types of games, disabling VSync is almost universally recommended, prioritizing responsiveness over perfect visuals.

The impact of VSync also depends on your monitor’s refresh rate. A higher refresh rate (e.g., 144Hz or higher) will generally result in less noticeable input lag, as the synchronization intervals are shorter. Conversely, lower refresh rates (e.g., 60Hz) will often result in more noticeable input lag.

Consider alternative technologies like Adaptive VSync (available in some games and graphics drivers). Adaptive VSync attempts to balance the benefits of VSync (preventing tearing) with minimizing input lag by only activating VSync when the frame rate drops below the refresh rate. This allows for tear-free visuals at lower frame rates while maintaining low latency at higher frame rates.

Ultimately, the “good” or “bad” of VSync depends entirely on your priorities and the type of game you’re playing. Prioritize visual quality for story-driven and cinematic titles, and prioritize responsiveness for competitive, fast-paced games.

Does resolution quality affect FPS?

So, does resolution impact FPS? Duh, yeah! Higher resolutions like 1440p and 4K are gorgeous, but they’re *brutal* on your GPU. Think of it like this: more pixels = more work for your graphics card. It’s got to render everything sharper, more detailed. That extra workload directly translates to lower frames per second, especially if your GPU isn’t a beast.

The higher the resolution, the more demanding the game. A game that runs at a buttery smooth 144fps at 1080p might only hit 60 or even 30 at 4K, even with the same settings. This is why you see pros sometimes dropping resolution to gain a competitive edge; more FPS means faster reaction times.

It’s not just the resolution; it’s the overall graphical settings too. Higher settings like high-resolution textures, advanced shadows, and ray tracing all pile on to that GPU workload, further impacting FPS, regardless of your resolution. You might need to tweak settings to find the sweet spot between visual fidelity and performance.

Think about your monitor’s refresh rate too. A 144Hz monitor is useless if your game is only outputting 60fps. You’ll only ever see 60. Make sure your settings allow your GPU to push as close to that refresh rate as possible at your chosen resolution.

Ultimately, it’s a balancing act. You gotta decide what’s more important: eye candy or smooth gameplay. Experiment with different settings to find the perfect blend for *your* system.

How to increase 99% FPS?

Yo, hitting that 99% FPS sweet spot? Let’s get real, that’s practically impossible, but we can *definitely* boost your frame rates. Forget those basic tips – let’s dive into some serious optimization.

Beyond the Basics:

Windows Game Mode (duh): Yeah, enable it. But *really* understand its limitations. It’s a nice little nudge, not a miracle worker.
Resolution: Lowering it is obvious, but consider *downsampling*. Render at a higher resolution then scale down. It’s smoother, sharper, and surprisingly effective.
Video Settings: Don’t just blindly crank everything low. Experiment! Shadows and anti-aliasing are huge FPS hogs, but sometimes tweaking textures or effects gives you bigger performance gains.
Driver Updates (and more!): Keep your drivers *up-to-date*, but also ensure they’re *the right ones*. Sometimes older drivers surprisingly perform better. And consider using tools like MSI Afterburner to monitor your GPU usage and temps. Overclocking (carefully!) can be a significant boost.
Background Processes: Yeah, close unused programs. But use Task Manager to identify sneaky resource hogs – those background processes you didn’t even know existed.
Wi-Fi is a Lie: Wired connection. Always. Especially for online gaming.
Refresh Rate: Match your monitor’s refresh rate to your in-game FPS. Going above your monitor’s capability is pointless.

Pro-Level Tweaks:

Overclocking (Proceed with Caution): Slightly overclocking your CPU and GPU can offer noticeable gains, but monitor your temps closely! Stability is key. Use monitoring software and don’t push it too far.
SSD vs. HDD: An SSD drastically reduces load times, impacting your overall gameplay experience, indirectly boosting your ‘feel’ of higher FPS. It’s more about smoothness than raw numbers.
Game-Specific Optimizations: Many games have built-in optimization options. Don’t ignore them! Look for settings related to physics, particle effects, or crowd density.
Reinstall the Game (Last Resort): Corrupted game files are a silent killer. A fresh install can sometimes resolve performance issues surprisingly effectively.

What is the best video resolution and frame rate?

Alright guys, so you’re asking about the best resolution and framerate? It’s a bit of a rabbit hole, but here’s the seasoned gamer’s take. For most games, especially those with a focus on storytelling and atmosphere, 4K at 30 FPS is a sweet spot. Think cinematic, gorgeous visuals, that really let you soak in the detail. It’s buttery smooth, usually, and your GPU won’t scream in protest.

But, if you’re playing something fast-paced, like a first-person shooter or a racing game, you’ll want to bump that framerate up. 4K at 60 FPS is the gold standard here. The smoother motion really makes a difference in those twitch-reaction moments. It’s easier to track targets and react quickly. The extra frames significantly reduce motion blur, making the action far clearer. The downside? It’ll really test your rig, you might need a top-tier graphics card to pull this off consistently at 4K. You could also consider 1440p at 120 or 144fps if your hardware is holding you back at 4K/60. Think of it as a compromise between visual fidelity and performance.

Ultimately, the best resolution and frame rate depends on your hardware and the type of game you’re playing. Experiment and see what your system can handle while maintaining a good balance between visual quality and smooth gameplay.

What graphics card gives best FPS?

Let’s be real, “best” is subjective, depends heavily on the game and your budget. But for raw FPS bang for your buck at 1440p, the Arc A580 currently takes the crown. It’s a budget beast, surprising many with its performance. It’s a sleeper hit, don’t sleep on it.

Following closely, we have the reliable RX 6600. A solid performer, always a safe bet. It’s consistent across titles, less prone to the wild swings in performance you might see in some others.

Next up, the Arc A750. A step up from the A580, offering a noticeable FPS boost, but at a higher price. Consider the jump worthwhile if you need that extra headroom for competitive titles.

Then we have the RX 6800. More power, more price. If 1440p 144Hz+ is your target, this one is a strong contender, especially for games that are heavily GPU bound. Remember ray tracing performance will vary.

Finally, the RTX 4060. Nvidia’s offering. It’s in the mix, competing strongly depending on the specific game. Ray tracing is its forte, but raw rasterization performance can be beaten by others in this list at this price point. It’s worth checking benchmarks for individual games you play.

Key takeaway: Don’t just look at raw FPS numbers. Check benchmarks for *your* games. Driver support is crucial – some cards have better optimization for specific titles. And remember, CPU bottlenecks can significantly impact your overall frame rates.

Does 1080p give more FPS?

1080p? Nah, that’s entry-level stuff, but it’s a solid starting point. Higher FPS at 1080p? Absolutely, but it hinges entirely on your GPU. A budget card will choke at higher settings, limiting your frame rate. You need the horsepower to push those pixels. Think of it like this: 1080p is your baseline. It’s the resolution where you can really dial in your settings without needing a top-tier card to hit playable FPS. Want buttery smooth gameplay? Yeah, you’ll get higher frame rates here than at higher resolutions like 1440p or 4K, assuming your system can handle it. Don’t expect miracles with a potato GPU though. You’ll need a decent card to maximize its potential. Upgrade your graphics card first, then optimize settings – that’s the golden rule for FPS gains at any resolution.

The sweet spot for cost versus performance? Usually 1080p. You’ll get competitive framerates without breaking the bank. But remember, it’s about the whole build. Your CPU, RAM, and drivers also play a role. A bottleneck anywhere will kill your FPS.

How much is 7700xt FPS per dollar?

The 7700 XT’s price-to-performance ratio, at approximately $6.79 per frame based on a $419 price point, is remarkably competitive. While the 4060 Ti 8GB boasts a slightly lower figure at $6.719 per frame (considering a $385 baseline), this difference is negligible and practically within the margin of error for benchmarking fluctuations.

Crucially, the 7700 XT’s advantage in rasterization significantly impacts the overall value proposition, particularly for competitive esports titles. This translates to a smoother, more responsive gaming experience crucial for maintaining a competitive edge. The one-dollar-per-frame advantage, though seemingly small, aggregates considerably over extended playtime, representing a tangible saving in the long run.

Factors affecting the FPS/dollar ratio include:

Game Engine Optimization: Certain game engines favor AMD or Nvidia architectures. This inherent advantage can skew benchmark results.
Driver Updates: Regular driver updates often improve performance. Consistent driver support is vital to maintaining optimal FPS.
Specific Game Titles: High-fidelity titles demand more processing power, impacting the FPS/dollar ratio differently than less demanding esports titles.
Resolution & Settings: Higher resolutions and graphical settings drastically reduce the frames per second, altering the FPS/dollar ratio substantially. Esports often utilizes lower settings for better performance.

For esports professionals, the subtle but consistent advantage of the 7700 XT in rasterization, coupled with its competitive price, makes it a compelling option. The marginal cost savings accumulate over time, providing a tangible financial advantage while maintaining a high-performance standard necessary for competitive gaming.

The one-dollar difference between the two GPUs in rasterization-heavy games could be the difference between victory and defeat in close matches.

Is 1440p better than 1080p for FPS?

So, you’re wondering about 1440p vs. 1080p for FPS? It’s a common question. Generally, you’ll see a significant drop in frames per second (FPS) when moving from 1080p to 1440p. We’re talking roughly half the FPS in many cases. This is because 1440p (2560×1440) has almost double the pixels of 1080p (1920×1080). Your GPU has to work twice as hard to render those extra pixels.

However, it’s not a simple “half the FPS” rule. Your specific hardware plays a massive role. A top-tier GPU will handle the jump to 1440p much better than a budget card. Let’s break that down:

GPU Power: The most important factor. A stronger GPU can maintain higher FPS at 1440p. A weaker GPU might struggle to even hit playable frame rates.
CPU Bottleneck: If your CPU is outdated or weak, it can become a bottleneck, limiting your FPS regardless of your GPU’s capabilities. This is especially true at higher resolutions.
Game Optimization: Some games are better optimized than others. A well-optimized game at 1440p might perform surprisingly well, while a poorly optimized one could tank your FPS.
In-Game Settings: Don’t forget about settings! Lowering graphical settings like shadows, anti-aliasing, and texture quality can significantly boost your FPS at both 1080p and 1440p.

Think of it this way:

High-end PC: The performance difference between 1080p and 1440p might be manageable, maybe a 30-40% reduction in FPS, still delivering a smooth gaming experience.
Mid-range PC: You’ll likely see a more noticeable drop, perhaps 50-70%, requiring adjustments to in-game settings to maintain acceptable FPS.
Low-end PC: Going to 1440p might be unplayable, resulting in extremely low and choppy frame rates.

The Bottom Line: While 1440p generally means lower FPS than 1080p, the actual impact depends entirely on your hardware and game settings. Don’t just assume you’ll lose half your FPS – benchmark your system and adjust accordingly.

Can you get 120 FPS with 1080p?

Alright folks, so the question is 120fps at 1080p? Absolutely! This monitor can definitely hit 120fps at both 1080p and even 1440p. Now, keep in mind, this isn’t a 4K display, so don’t even try pushing for that resolution at that frame rate – you’ll be disappointed. The sweet spot for smooth, buttery gameplay on this thing is definitely 1080p or 1440p at 120hz. If you’re aiming for those high refresh rates, make sure your graphics card is up to snuff. A good mid-range card should handle most modern titles at 1080p/120fps on medium to high settings. You might need to tweak some settings depending on the game, but that’s part of the optimization fun, right? Remember to check your in-game settings, as well as your monitor’s refresh rate settings to ensure it’s actually running at 120Hz, not just reporting it.

And for those wondering about the difference… well, 120fps is noticeably smoother than 60fps. It’s a massive improvement for responsiveness and reduces motion blur. It’s a game-changer, especially for fast-paced games like shooters or racing games where every millisecond counts. 1440p will look sharper than 1080p, but remember the frame rate may drop a bit depending on your hardware. Experiment and find the perfect balance!

Does native resolution affect FPS?

Nah, native res doesn’t directly tank your FPS. It’s the *scaling* that’s the real killer. Your GPU’s gotta work harder upscaling or downscaling, especially with demanding titles. Running below native (like 720p on a 1440p monitor) forces the GPU to upscale, adding processing overhead – you’ll see blurry textures and potentially lower FPS if your GPU can’t handle it. Conversely, forcing a higher resolution than native (supersampling) is a *massive* GPU load. It renders at a higher resolution than your display, then downsamples, leading to crisper visuals but often significant FPS drops. Think of it as rendering at 4K then squishing it down to 1080p; gorgeous, but brutal on your hardware. Basically, stick to native for optimal balance of visuals and performance unless you’re rocking a beast of a rig and want to experiment.