RTX 3500 Ada Generation Embedded GPU vs GeForce RTX 3060 Laptop GPU
RTX 3500 Ada Generation Embedded GPU
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GeForce RTX 3060 Laptop GPU
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Performance Spectrum - GPU
About G3D Mark
G3D Mark is a standard benchmark that measures graphics performance in real-world gaming scenarios. It simplifies comparing cards from different brands, where higher scores directly correlate with better fps and smoother gaming experiences.
Value Upgrade Path
This is the official ChipVERSUS Value Rating, comparing raw performance (G3D Mark) per dollar. Components placed above yours deliver better value for money.
Avg price is the current average price collected from markets across the web.
Performance Per Dollar RTX 3500 Ada Generation Embedded GPU
Performance Per Dollar GeForce RTX 3060 Laptop GPU
Performance Comparison
About G3D Mark🏆 Chipversus Verdict
🚀 Performance Leadership
The RTX 3500 Ada Generation Embedded GPU is the superior choice for raw performance. It leads with a 91.9% higher G3D Mark score and 100% more VRAM (12 GB vs 6 GB). This advantage makes it significantly better for higher resolutions (1440p/4K) and graphic-intensive titles compared to the GeForce RTX 3060 Laptop GPU.
| Insight | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| Performance | ✅Leading raw performance (+91.9%) | ❌Lower raw frame rates (-91.9%) |
| Longevity | 🏆Elite Architecture (Ada Lovelace (2022−2024) / 5nm) | 🔮Strong Longevity (Ampere (2020−2025) / 8nm) |
| Ecosystem | ✨ DLSS 3/4 + Frame Gen Support | ✨ DLSS 2 Upscaling |
| VRAM | 🎮 High Capacity (12 GB) | 🎮 High Capacity (6 GB) |
| Efficiency | 💡 Excellent Perf/Watt | ⚡ Higher Power Consumption |
| Case Fit | 📏 Compact / SFF Friendly | — |
💎 Value Proposition
While current pricing data is unavailable, the RTX 3500 Ada Generation Embedded GPU remains the clear technical winner. Check real-time availability to determine if the performance gap justifies the market price.
Performance Check
Real-world benchmarks and performance projections based on comprehensive hardware analysis and comparative metrics. Values represent expected performance on High/Ultra settings at 1080p, 1440p, and 4K. Modeled using a Ryzen 7 7800X3D reference profile to minimize specific CPU bottlenecks.
Note: Performance behavior can vary per game. Specific architectures may perform better or worse depending on game engine optimizations and API implementation.
Technical Specifications
Side-by-side comparison of RTX 3500 Ada Generation Embedded GPU and GeForce RTX 3060 Laptop GPU
RTX 3500 Ada Generation Embedded GPU
The RTX 3500 Ada Generation Embedded GPU is manufactured by NVIDIA. It was released in March 21 2023. It features the Ada Lovelace architecture. The core clock ranges from 975 MHz to 1500 MHz. It has 5120 shading units. The thermal design power (TDP) is 115W. Manufactured using 5 nm process technology. It features 40 dedicated ray tracing cores for enhanced lighting effects. G3D Mark benchmark score: 25,267 points.
GeForce RTX 3060 Laptop GPU
The GeForce RTX 3060 Laptop GPU is manufactured by NVIDIA. It was released in October 12 2022. It features the Ampere architecture. The core clock ranges from 1320 MHz to 1777 MHz. It has 3584 shading units. The thermal design power (TDP) is 170W. Manufactured using 8 nm process technology. It features 28 dedicated ray tracing cores for enhanced lighting effects. G3D Mark benchmark score: 13,170 points.
Graphics Performance
In G3D Mark, the RTX 3500 Ada Generation Embedded GPU scores 25,267 versus the GeForce RTX 3060 Laptop GPU's 13,170 — the RTX 3500 Ada Generation Embedded GPU leads by 91.9%. The RTX 3500 Ada Generation Embedded GPU is built on Ada Lovelace while the GeForce RTX 3060 Laptop GPU uses Ampere, both on 5 nm vs 8 nm. Shader units: 5,120 (RTX 3500 Ada Generation Embedded GPU) vs 3,584 (GeForce RTX 3060 Laptop GPU). Raw compute: 15.82 TFLOPS (RTX 3500 Ada Generation Embedded GPU) vs 12.74 TFLOPS (GeForce RTX 3060 Laptop GPU). Boost clocks: 1500 MHz vs 1777 MHz. Ray tracing: 40 RT cores (RTX 3500 Ada Generation Embedded GPU) vs 28 (GeForce RTX 3060 Laptop GPU) with 160 Tensor cores vs 112.
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| G3D Mark Score | 25,267+92% | 13,170 |
| Architecture | Ada Lovelace | Ampere |
| Process Node | 5 nm | 8 nm |
| Shading Units | 5120+43% | 3584 |
| Compute (TFLOPS) | 15.82 TFLOPS+24% | 12.74 TFLOPS |
| Boost Clock | 1500 MHz | 1777 MHz+18% |
| ROPs | 64+33% | 48 |
| TMUs | 160+43% | 112 |
| L1 Cache | 5 MB+43% | 3.5 MB |
| L2 Cache | 48 MB+1500% | 3 MB |
| Ray Tracing Cores | 40+43% | 28 |
| Tensor Cores | 160+43% | 112 |
Advanced Features (DLSS/FSR)
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| Upscaling Tech | FSR 1.0 (Software) | DLSS 2.0 |
| Frame Generation | Not Supported | FSR 3 / AFMF (Compatible) |
| Ray Reconstruction | No | No |
| Low Latency | NVIDIA Reflex | NVIDIA Reflex |
Video Memory (VRAM)
The RTX 3500 Ada Generation Embedded GPU comes with 12 GB of VRAM, while the GeForce RTX 3060 Laptop GPU has 6 GB. The RTX 3500 Ada Generation Embedded GPU offers 100% more capacity, crucial for higher resolutions and texture-heavy games. Memory bandwidth: 432 GB/s (RTX 3500 Ada Generation Embedded GPU) vs 336 GB/s (GeForce RTX 3060 Laptop GPU) — a 28.6% advantage for the RTX 3500 Ada Generation Embedded GPU. Bus width: 192-bit vs 192-bit. L2 Cache: 48 MB (RTX 3500 Ada Generation Embedded GPU) vs 3 MB (GeForce RTX 3060 Laptop GPU) — the RTX 3500 Ada Generation Embedded GPU has significantly larger on-die cache to reduce VRAM reliance.
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| VRAM Capacity | 12 GB+100% | 6 GB |
| Memory Type | GDDR6 | GDDR6 |
| Memory Bandwidth | 432 GB/s+29% | 336 GB/s |
| Bus Width | 192-bit | 192-bit |
| L2 Cache | 48 MB+1500% | 3 MB |
Display & API Support
DirectX support: 12 Ultimate (12_2) (RTX 3500 Ada Generation Embedded GPU) vs 12 Ultimate (GeForce RTX 3060 Laptop GPU). Vulkan: 1.3 vs 1.4. OpenGL: 4.6 vs 4.6. Maximum simultaneous displays: 4 vs 4.
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| DirectX | 12 Ultimate (12_2) | 12 Ultimate |
| Vulkan | 1.3 | 1.4+8% |
| OpenGL | 4.6 | 4.6 |
| Max Displays | 4 | 4 |
Media & Encoding
Hardware encoder: NVENC 8th Gen (RTX 3500 Ada Generation Embedded GPU) vs NVENC (7th Gen) (GeForce RTX 3060 Laptop GPU). Decoder: NVDEC 5th Gen vs NVDEC (5th Gen). Supported codecs: H.264,H.265,AV1 (RTX 3500 Ada Generation Embedded GPU) vs H.264,HEVC,AV1 (Decode),VP9 (GeForce RTX 3060 Laptop GPU).
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| Encoder | NVENC 8th Gen | NVENC (7th Gen) |
| Decoder | NVDEC 5th Gen | NVDEC (5th Gen) |
| Codecs | H.264,H.265,AV1 | H.264,HEVC,AV1 (Decode),VP9 |
Power & Dimensions
The RTX 3500 Ada Generation Embedded GPU draws 115W versus the GeForce RTX 3060 Laptop GPU's 170W — a 38.6% difference. The RTX 3500 Ada Generation Embedded GPU is more power-efficient. Recommended PSU: 650W (RTX 3500 Ada Generation Embedded GPU) vs 500W (GeForce RTX 3060 Laptop GPU). Power connectors: PCIe-powered vs Mobile. Typical load temperature: 85 vs 75°C.
| Feature | RTX 3500 Ada Generation Embedded GPU | GeForce RTX 3060 Laptop GPU |
|---|---|---|
| TDP | 115W-32% | 170W |
| Recommended PSU | 650W | 500W-23% |
| Power Connector | PCIe-powered | Mobile |
| Length | 105mm | — |
| Height | 82mm | — |
| Slots | 0 | — |
| Temp (Load) | 85 | 75°C-12% |
| Perf/Watt | 219.7+183% | 77.5 |
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