NVIDIA RTX 3500 Mobile Ada Generation vs NVIDIA RTX 3000 Mobile Ada Generation Comparison

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RTX 3500 Mobile Ada Generation

12 GB | 15.82 TFLOPS

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RTX 3000 Mobile Ada Generation

8 GB | 15.62 TFLOPS

RTX 3500 Mobile Ada Generation vs RTX 3000 Mobile Ada Generation Comparison Overview

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RTX 3000 Mobile Ada...

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In this review, we will be comparing RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation, two GPUs by NVIDIA. RTX 3500 Mobile Ada Generation was introduced to market in March and was launched in March . Both RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation were launched within the same month so we are expecting this to be a fair comparison regarding age and available technology level.

RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation are members of NVIDIA's Quadro Ada-M (x000A) series of GPUs. Below you can find the latest models from this series.

NVIDIA Quadro Ada-M (x000A) Series History

Model	Release Date	Fabrication Process	Performance
RTX 2000 Max-Q Ada Generation Compare	March 2023	5 nm	8.940 TFLOPS
RTX 2000 Mobile Ada Generation Compare	March 2023	5 nm	12.99 TFLOPS
RTX 3000 Mobile Ada Generation	March 2023	5 nm	15.62 TFLOPS
RTX 3500 Mobile Ada Generation	March 2023	5 nm	15.82 TFLOPS
RTX 4000 Mobile Ada Generation Compare	March 2023	5 nm	24.72 TFLOPS
RTX 5000 Max-Q Ada Generation Compare	March 2023	5 nm	32.69 TFLOPS
RTX 5000 Mobile Ada Embedded Compare	March 2023	5 nm	41.15 TFLOPS
RTX 5000 Mobile Ada Generation Compare	March 2023	5 nm	41.15 TFLOPS

Here is a brief look at the main features of RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation before getting into our more detailed comparison.

RTX 3500 Mobile Ada Generation Key Specs

Launched in Mar 21st, 2023
Brand: NVIDIA
GPU: AD104
Tecnology: 5 nm
Clock: 1110 MHz
12 GB Ram
Mem. Clock: 2250 MHz 18 Gbps effective

RTX 3000 Mobile Ada Generation Key Specs

Launched in Mar 21st, 2023
Brand: NVIDIA
GPU: AD106
Tecnology: 5 nm
Clock: 1395 MHz
8 GB Ram
Mem. Clock: 2000 MHz 16 Gbps effective

Let's read on the following sections in order to better understand in detail how and compares and decide which one is better for you.

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Reasons to choose RTX 3500 Mobile Ada Generation over RTX 3000 Mobile Ada Generation

Transistors	35,800 million vs 22,900 million	Has more transistors
Thermal Design Power (TDP)	100 W vs 115 W	Requires less cooling
Memory Size	12 GB vs 8 GB	4 GB more RAM
Memory Clock	2250 MHz vs 2000 MHz	250 MHz faster Memory Clock
Memory Bus Bits	192 bit vs 128 bit	More Memory Bits
Memory Bandwidth	432.0 GB/s vs 256.0 GB/s	Wider Memory Bandwith
Render Config Shading Units (RCSU)	5120 vs 4608	Better Visual Effects Performance
Texture Mapping Units (TMU)	160 vs 144	Better Texture Performance
Ray Tracing (RT) Cores	64 vs 48	Better 3D Performance
Raster Operations Pipeline (ROP)	40 vs 36	Better Optical Effects Performance
L2 Cache Memory	48 MB vs 32 MB	More Cache Memory
Pixel Rate	98.88 GPixel/s vs 81.36 GPixel/s	Better Pixel Rate
Texture Rate	247.2 GTexel/s vs 244.1 GTexel/s	Better Texture Performance
Performance	15.82 TFLOPS vs 15.62 TFLOPS	More processing power
Tensor Cores	160 vs 144	Better AI field performance
Streaming Multiprocessor (RM) Count	40 vs 36	Better in parallel computing performance

Reasons to choose RTX 3000 Mobile Ada Generation over RTX 3500 Mobile Ada Generation

GPU Base Clock	1395 MHz vs 1110 MHz	285 MHz faster Base Clock
GPU Boost Clock	1695 MHz vs 1545 MHz	150 MHz faster Boost Clock

Common Strengths of RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation

Process Size	5 nm vs 5 nm	Latest Process Technology
Memory Size	12 GB vs 8 GB	Both GPUs have more than 4 GB Memory
Memory Clock Speeds	2250 MHz vs 2000 MHz	Over Average Memory Clock Speeds
Bus Interface	PCIe 4.0 x16 vs PCIe 4.0 x16	Both have latest Bus type

Common Weaknesses of RTX 3500 Mobile Ada Generation and RTX 3000 Mobile Ada Generation

Launch Dates	2023-03-21 vs 2023-03-21	GPUs are older than 1 year

PERFORMANCE

FLOPS

FLOPS is commonly used for measuring GPU performance in 32-bit floating-point operations, essential for scientific computing, data analysis, machine learning, and graphics tasks. A higher value indicates faster and more complex calculations, vital for scientific research, simulations, and high-performance computing.

RTX 3500 Mobile Ada Generation performs above average with 15.82 TFLOPS provides more performance overall GPU's in its class.

RTX 3000 Mobile Ada Generation performs above average with 15.62 TFLOPS provides more performance overall GPU's in its class.

FLOPS Comparison (TFLOPS)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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GPU BASE and BOOST CLOCK SPEED

The GPU base clock speed is the standard operating frequency, while the boost clock speed represents the maximum dynamic frequency the GPU can achieve under increased demand. These clock speeds influence the GPU's performance, with the base clock setting the standard level and the boost clock allowing for extra power when needed, enhancing overall responsiveness in demanding applications like gaming.

The base clock speed of the RTX 3500 Mobile Ada Generation is below average, which could be a sign of lower performance potential.

Base Clock Comparison (MHz)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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Boost Clock Comparison (MHz)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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MEMORY SIZE and MEMORY CLOCK SPEED

GPU memory size refers to the storage capacity for visual data. This capacity is crucial for tasks like gaming and graphic-intensive work. Memory clock speed affects how quickly the GPU's memory operates. Faster memory speed improves performance, especially in high-resolution gaming. Balancing memory size and clock speed is vital for a GPU's graphics handling capabilities..

The base clock speed of the RTX 3000 Mobile Ada Generation is below average, you may evaluate it further for your decision.

Memory Size Comparison (GB)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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Memory Clock Comparison (MHz)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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GPU THERMAL DESIGN POWER (TDP)

GPU TDP, or Thermal Design Power, quantifies the maximum heat a graphics processing unit (GPU) generates under load. It's vital for selecting appropriate cooling solutions and power efficiency. Higher TDP GPUs require better cooling, while lower TDP GPUs are more power-efficient. Understanding TDP aids in choosing the right GPU for a system.

RTX 3500 Mobile Ada Generation has nearly highest TDP with 100.00 W in its class.

RTX 3000 Mobile Ada Generation has nearly highest TDP with 115.00 W in its class.

TDP Comparison (Watts)

mobile type GPUs

RTX 3500 Mobile Ada Generation

RTX 3000 Mobile Ada Generation

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RTX 3500 Mobile Ada Generation vs RTX 3000 Mobile Ada Generation: Specs Comparison Table

In this section, we will be comparing the specifications the RTX 3500 Mobile Ada Generation and the RTX 3000 Mobile Ada Generation.

Processor
Model	RTX 3500 Mobile Ada Generation	RTX 3000 Mobile Ada Generation
Generation	Quadro Ada-M (x000A)	Quadro Ada-M (x000A)
Predecessor	Quadro Ampere-M	Quadro Ampere-M
Release Date	2023-03-21	2023-03-21
Brand	NVIDIA	NVIDIA
GPU Name	AD104	AD106
Architecture	Ada Lovelace	Ada Lovelace
Foundry	TSMC	TSMC
Process Size	5 nm	5 nm
Number of Transistors	35,800 million	22,900 million
Density of Transistors	121.8M / mm²	121.8M / mm²
Die Size	294 mm²	188 mm²
GPU Base Clock Speed	1110 MHz	1395 MHz
GPU Clock Speed	1545 MHz	1695 MHz

Memory
Memory	12 GB	8 GB
Memory Type	GDDR6	GDDR6
Memory Frequency	2250 MHz	2000 MHz
Memory Bus	192 bit	128 bit
Memory Bandwith	432.0 GB/s	256.0 GB/s
Bus Interface	PCIe 4.0 x16	PCIe 4.0 x16

Render Configurations
Shading Units	5120	4608
TMUs	160	144
ROPs	64	48
RT Cores	40	36
SM Count	40	36
Tensor Cores	160	144
L1 Cache	128 KB (per SM)	128 KB (per SM)
L2 Cache	48 MB	32 MB

Performance and Features
Pixel Rate	98.88 GPixel/s	81.36 GPixel/s
Texture Rate	247.2 GTexel/s	244.1 GTexel/s
DirectX	12 Ultimate	12 Ultimate
OpenGL	4.6	4.6
OpenCL	3.0	3.0
Vulkan	1.3	1.3
Shader Model	6.7	6.7
FP16 Half	15.82 TFLOPS (1:1)	15.62 TFLOPS (1:1)
FP32	15.82 TFLOPS	15.62 TFLOPS
FP64 double	247.2 GFLOPS (1:64)	244.1 GFLOPS (1:64)
CUDA	8.9	8.9