AMD Radeon Vega 8 vs AMD Radeon Vega 11 Comparison

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Radeon Vega 8

System Shared | 1,280 GFLOPS

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Radeon Vega 11

System Shared | 1.971 TFLOPS

Radeon Vega 8 vs Radeon Vega 11 Comparison Overview

Radeon Vega 8

Radeon Vega 11

Radeon Vega 8

Radeon Vega 11

In this review, we will be comparing Radeon Vega 8 and Radeon Vega 11, two GPUs by AMD. Radeon Vega 8 was introduced to market in July and was launched in September . There is only 3 months difference between Radeon Vega 8 and Radeon Vega 11 so we are expecting this to be a fair comparison regarding age and technology level.

Radeon Vega 8 and Radeon Vega 11 are members of AMD's Vega IGP (Picasso) series of GPUs. Below you can find the latest models from this series.

AMD Vega IGP (Picasso) Series History

Model	Release Date	Fabrication Process	Performance
Radeon RX Vega 11 Compare	July 2019	12 nm	1.971 TFLOPS
Radeon Vega 11	September 2019	12 nm	1.971 TFLOPS
Radeon Vega 3 Compare	November 2019	12 nm	422.4 GFLOPS
Radeon Vega 3 Embedded Compare	June 2025	12 nm	384.0 GFLOPS
Radeon Vega 3 Embedded Compare	June 2025	12 nm	460.8 GFLOPS
Radeon Vega 8	July 2019	12 nm	1,280 GFLOPS

Here is a brief look at the main features of Radeon Vega 8 and Radeon Vega 11 before getting into our more detailed comparison.

Radeon Vega 8 Key Specs

Launched in Jul 7th, 2019
Brand: AMD
GPU: Picasso
Tecnology: 12 nm
Clock: 300 MHz
System Shared Ram
Mem. Clock: System Shared

Radeon Vega 11 Key Specs

Launched in Sep 30th, 2019
Brand: AMD
GPU: Picasso
Tecnology: 12 nm
Clock: 300 MHz
System Shared Ram
Mem. Clock: System Shared

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 Radeon Vega 8 over Radeon Vega 11

Reasons to choose Radeon Vega 11 over Radeon Vega 8

GPU Boost Clock	1400 MHz vs 1250 MHz	150 MHz faster Boost Clock
Render Config Shading Units (RCSU)	704 vs 512	Better Visual Effects Performance
Texture Mapping Units (TMU)	44 vs 32	Better Texture Performance
Pixel Rate	11.20 GPixel/s vs 10.00 GPixel/s	Better Pixel Rate
Texture Rate	61.60 GTexel/s vs 40.00 GTexel/s	Better Texture Performance
Performance	1.971 TFLOPS vs 1,280 GFLOPS	More processing power

Common Strengths of Radeon Vega 8 and Radeon Vega 11

TDP	15 W vs 15 W	Good Thermal Performance

Common Weaknesses of Radeon Vega 8 and Radeon Vega 11

Launch Dates	2019-07-07 vs 2019-09-30	GPUs are older than 1 year
Process Size	12 nm vs 12 nm	Process thickness is not the latest
GPU Clock Speeds	300 MHz vs 300 MHz	Below the average in this 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.

Radeon Vega 8 performs above average with 1.28 TFLOPS provides more performance overall GPU's in its class.

Radeon Vega 11 has nearly top performance with 1.97 TFLOPS in its class.

FLOPS Comparison (TFLOPS)

integrated type GPUs

Radeon Vega 8

Radeon Vega 11

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Average

Max

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.

Base Clock Comparison (MHz)

integrated type GPUs

Radeon Vega 8

Radeon Vega 11

Min

Average

Max

Boost Clock Comparison (MHz)

integrated type GPUs

Radeon Vega 8

Radeon Vega 11

Min

Average

Max

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 memory of both Radeon Vega 8 and Radeon Vega 11 are system-shared, which means that memory-based performance values depend on the system.

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.

Radeon Vega 8 has nearly highest TDP with 15.00 W in its class.

Radeon Vega 11 has nearly highest TDP with 15.00 W in its class.

TDP Comparison (Watts)

integrated type GPUs

Radeon Vega 8

Radeon Vega 11

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Average

Max

Radeon Vega 8 vs Radeon Vega 11: Specs Comparison Table

In this section, we will be comparing the specifications the Radeon Vega 8 and the Radeon Vega 11.

Processor
Model	Radeon Vega 8	Radeon Vega 11
Generation	Vega IGP (Picasso)	Vega IGP (Picasso)
Successor	Vega II IGP	Vega II IGP
Predecessor	GCN 3.0 IGP	GCN 3.0 IGP
Release Date	2019-07-07	2019-09-30
Brand	AMD	AMD
GPU Name	Picasso	Picasso
Architecture	GCN 5.0	GCN 5.0
Foundry	GlobalFoundries	GlobalFoundries
Process Size	12 nm	12 nm
Number of Transistors	4,940 million	4,940 million
Density of Transistors	23.5M / mm²	23.5M / mm²
Die Size	210 mm²	210 mm²
Package	µOPGA-1331	µOPGA-1331
IGP Variants	Ryzen 3 3200G: 1250 MHz	Ryzen 5 PRO 3400G: 1400 MHz
GPU Base Clock Speed	300 MHz	300 MHz
GPU Clock Speed	1250 MHz	1400 MHz

Memory
Memory	System Shared	System Shared
Memory Type	System Shared	System Shared
Memory Frequency	System Shared z	System Shared z
Memory Bus	System Shared	System Shared
Memory Bandwith	System Dependent	System Dependent
Bus Interface	IGP	IGP

Render Configurations
Shading Units	512	704
TMUs	32	44
ROPs	8	8
Config Units	8	11

Performance and Features
Pixel Rate	10.00 GPixel/s	11.20 GPixel/s
Texture Rate	40.00 GTexel/s	61.60 GTexel/s
DirectX	12	12
OpenGL	4.6	4.6
OpenCL	2.1	2.1
Vulkan	1.3	1.3
Shader Model	6.7	6.7
FP16 Half	2.560 TFLOPS (2:1)	3.942 TFLOPS (2:1)
FP32	1,280 GFLOPS	1.971 TFLOPS
FP64 double	80.00 GFLOPS (1:16)	123.2 GFLOPS (1:16)