GeForce RTX™ 4070 AERO OC V2 12G -vs- ASUS Dual GeForce RTX™ 4070 12GB GDDR6X
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Specs comparison between GeForce RTX™ 4070 AERO OC V2 12G and ASUS Dual GeForce RTX™ 4070 12GB GDDR6X
GPU Details | ||
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Name | GeForce RTX™ 4070 AERO OC V2 12G | ASUS Dual GeForce RTX™ 4070 12GB GDDR6X |
Brand?The manufacturer of the graphics card, such as Gigabyte in 'Gigabyte AORUS GeForce RTX™ 4070 MASTER 12G'. The brand often indicates the card's build quality and features. | Gigabyte | Asus |
Chip Name?The specific GPU model used in the graphics card, such as 'GeForce RTX™ 4070' in 'Gigabyte AORUS GeForce RTX™ 4070 MASTER 12G'. It defines the core architecture and performance of the card. | GeForce RTX™ 4070 AERO OC V2 12G -vs- ASUS Dual GeForce RTX™ 4070 12GB GDDR6X | GeForce RTX™ 4070 AERO OC V2 12G -vs- ASUS Dual GeForce RTX™ 4070 12GB GDDR6X |
Type?Indicates that this graphics card is designed for use in desktop computers. | Desktop | |
Release Date | 04/2023 | 04/2023 |
PCI-E?The PCI Express interface used by the graphics card, indicating its compatibility with motherboards. Common versions include PCIe 4.0 and PCIe 5.0, with newer versions offering higher bandwidth. | PCI-E 4.0 | PCI-E 5.0 |
Max. Frequency?The maximum clock speed the GPU can reach, measured in megahertz (MHz). It represents the card's peak performance capability under optimal conditions. | 2650 | 2650 |
Part No.?The unique part number assigned to the graphics card by the manufacturer. It helps identify the specific model and its specifications for ordering and support. | ||
GPU Display & Ports | ||
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Maximum Resolution?The highest display resolution that the graphics card can output, indicating its ability to drive high-resolution monitors. | 7680x4320 | 7680x4320 |
Dp Port?The number of DisplayPort connections available on the graphics card. DisplayPort is a common interface for high-resolution displays. | DisplayPort 1.4a *3 | 3 X DisplayPort 1.4a |
HDMI?The number of HDMI connections available on the graphics card. HDMI is a common interface for connecting to TVs and monitors. | 1 X HDMI 2.1 | 1 X HDMI 2.1 |
Hdcp Support?High-bandwidth Digital Content Protection (HDCP) support indicates the card's ability to display protected content, such as Blu-ray movies and streaming services. | ||
Max no. of Display?The maximum number of displays the graphics card can simultaneously output to. This indicates the card's multi-monitor capabilities. | 4 | 4 |
GPU General Specification | ||
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No. of Fan?The number of fans used for cooling the graphics card. More fans can improve cooling performance, especially under heavy load. | 3 | 2 |
RGB Lighting?Indicates whether the graphics card features customizable RGB lighting. This allows users to personalize the card's appearance. | no | yes |
PCI-E?The PCI Express interface used by the graphics card, indicating its compatibility with motherboards. Common versions include PCIe 4.0 and PCIe 5.0, with newer versions offering higher bandwidth. | PCI-E 4.0 | PCI-E 5.0 |
Recommended Power Supply?The recommended wattage of the power supply unit (PSU) needed to reliably power the graphics card. It ensures stable operation and prevents damage due to insufficient power. | 650 | 650 |
GPU Dimension | ||
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Slot Width?The number of expansion slots the graphics card occupies on the motherboard. It indicates the physical thickness of the card. | 2.56 | 2 |
Length?The physical length of the graphics card, measured in millimeters (mm). It determines the space required within the computer case to install the card. | 342 mm | 300 mm |
Width?The physical width of the graphics card, measured in millimeters (mm). It's the dimension from the component side of the card to the backplate/bracket side. | 130 mm | 153 mm |
Height?The physical height of the graphics card, measured in millimeters (mm). It's the dimension from the bottom of the PCIe connector to the top of the card. | 70.6 mm | 50.2 mm |
Graphics Processors Details
Graphics Processor | ||
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Name?The specific name of the graphics processing unit (GPU) on the card, identifying its model and capabilities. | GeForce RTX™ 4070 AERO OC V2 12G -vs- ASUS Dual GeForce RTX™ 4070 12GB GDDR6X | GeForce RTX™ 4070 AERO OC V2 12G -vs- ASUS Dual GeForce RTX™ 4070 12GB GDDR6X |
Architecture?The underlying design and structure of the GPU, defining its features and performance characteristics. | ||
Processor Size?The manufacturing process used to create the GPU, measured in nanometers (nm). Smaller processes typically result in more efficient and powerful GPUs. | ||
Transistors?The number of transistors within the GPU. More transistors generally indicate higher performance and more complex features. | ||
Die Size?The physical size of the GPU chip, measured in square millimeters (mm²). Die size can influence the GPU's performance and power consumption. | ||
GPU Type | ||
TGP?Total Graphics Power (TGP) is the maximum amount of power the graphics card is designed to consume, including the GPU and its memory. It indicates the card's overall power consumption and heat generation. | Watts | Watts |
Launch Date | ||
Clock Speed | ||
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Base Clock?The standard operating speed of the GPU, measured in megahertz (MHz). It indicates the GPU's baseline performance level. | MHz | MHz |
Boost Clock?The maximum speed the GPU can reach under heavy load, measured in megahertz (MHz). It represents the GPU's peak performance capability. | MHz | MHz |
Render Config | ||
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Shading Units?The number of processing units within the GPU responsible for rendering graphics. More shading units generally result in better graphics performance. | ||
TMUs?Texture Mapping Units (TMUs) are processing units within the GPU that apply textures to 3D surfaces. More TMUs improve the realism and detail of rendered graphics. | ||
ROPs?Render Output Units (ROPs) are processing units within the GPU that handle the final stage of rendering, converting pixel data into an image. More ROPs improve the frame rate and image quality. | ||
RT Cores?Ray Tracing cores are specialized processing units within the GPU that accelerate ray tracing, a technique for creating realistic lighting and reflections. | ||
L1 Cache?The smallest and fastest cache memory level within the GPU, located closest to the processing units. It stores frequently accessed data for rapid retrieval. | ||
L2 Cache?A mid-level cache memory within the GPU that provides a larger storage capacity than L1 cache. It stores data that is less frequently accessed than L1 but more frequently than the GPU's main memory. | ||
Memory | ||
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Memory Size?The amount of dedicated memory available to the GPU, measured in gigabytes (GB). More memory allows the GPU to handle larger and more complex graphics data. | GB | GB |
Memory Type?The type of memory used by the GPU, such as GDDR6 or GDDR6X. Newer memory types offer faster speeds and higher bandwidth, improving graphics performance. | ||
Memory Bus?The width of the data path between the GPU and its memory, measured in bits. A wider memory bus allows for faster data transfer. | ||
Bandwidth?The maximum rate at which data can be transferred between the GPU and its memory, measured in gigabytes per second (GB/s). Higher bandwidth improves graphics performance. | ||
Memory Clock Speed?The speed at which the GPU's memory operates, measured in megahertz (MHz). Higher clock speeds result in faster memory access. | ||
Features | ||
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DirectX?The version of Microsoft's DirectX API supported by the GPU, indicating its compatibility with graphics features and technologies. | ||
G-Sync/FreeSync?Indicates support for adaptive synchronization technologies like NVIDIA G-SYNC or AMD FreeSync, which reduce screen tearing and stuttering. | ||
OpenCL?Open Computing Language (OpenCL) is a framework for writing programs that execute across heterogeneous platforms, including GPUs. It enables parallel computing for various applications. | ||
OpenGL?Open Graphics Library (OpenGL) is a cross-language, cross-platform API for rendering 2D and 3D vector graphics. It's widely used in graphics applications and games. | ||
Shader Model?A set of instructions and capabilities that define the features and performance of the GPU's programmable shaders. Higher shader model versions offer more advanced graphics effects. | ||
Vulkan?The version of the Vulkan API supported by the GPU, indicating its compatibility with this low-overhead, cross-platform graphics and computing API. | ||
Extra Technology | ||
Comparison Review of GeForce RTX™ 4070 AERO OC V2 12G and ASUS Dual GeForce RTX™ 4070 12GB GDDR6X
“`html Target Hardware Review: Next-Gen Consumer Devices Processor Analysis Architecture Deep Dive Evaluating the target’s processor architecture is paramount. We’re looking for core count, clock speeds, and most importantly, the instruction set architecture (ISA) support. Modern devices increasingly rely on ARM-based SoCs (System on a Chip), but variations within the ARM ecosystem (Cortex-A, Neoverse) dictate performance. Look for advanced features like out-of-order execution, branch prediction, and integrated GPUs. Also check the fabrication node (e.g., 7nm, 5nm, or 3nm) – smaller nodes lead to higher transistor densities and potentially better power efficiency, and consider the TDP target. Performance Metrics Benchmarking relies heavily on established suites like Geekbench, Antutu, and specialized tests for graphics (3DMark, GFXBench). Focus on both single-core and multi-core performance to assess responsiveness and handle multi-threaded applications. Analyze power consumption under load (thermal throttling is a key factor), and compare these metrics against competitors within the product class. Specific consideration should go towards target of AI/ML performance and inference speed. Graphical Processing Unit (GPU) Assessment Graphics Core Performance GPU performance is critical for gaming, UI responsiveness, and general-purpose computation (GPGPU). Analyze the GPU’s core configuration (e.g., number of cores, shader units), memory bandwidth, and clock speeds. Benchmark against dedicated GPU benchmarks to establish an understanding. Consider the implementation used in different graphics APIs like Vulkan and DirectX, as these APIs can impact performance. Memory and Storage Evaluation RAM Analysis RAM configuration is crucial. Capacity, speed (e.g., DDR4, LPDDR5X), and channel configuration (single-channel, dual-channel) significantly impact multitasking and application performance. Analyze latency and bandwidth through synthetic benchmarks. The capacity has a clear impact on memory bandwidth and size limits can be considered. Storage Subsystem Investigation Storage Type and Speed Storage performance dictates boot times, application loading, and file transfer speeds. Evaluate storage type (e.g., eMMC, UFS, NVMe SSD). Benchmark read and write speeds using tools like CrystalDiskMark. Look for factors affecting performance such as overprovisioning and wear leveling algorithms, which will ensure the storage devices are running quickly. Connectivity and Power Wireless Technologies Assess Wi-Fi standards (Wi-Fi 6E, Wi-Fi 7), Bluetooth version, and cellular connectivity (5G support, band support, antenna design). Perform real-world tests for data throughput, latency, and signal strength. Assess power consumption under high bandwidth tasks. Also confirm the target meets all the necessary connectivity requirements of other devices. Power Management Battery life and charging speeds Battery capacity and power efficiency are crucial for user experience. Analyze battery life under various usage scenarios (web browsing, video playback, gaming). Evaluate charging speeds using a variety of charging methodologies (e.g., fast charging, wireless charging.) Assess power consumption during heavy workloads and idle state. Display and User Interface Display Technology Resolution And Quality Evaluate display technology (LCD, OLED – including panel type, e.g. AMOLED, its refresh rate, and resolution with associated pixel density. Assess color accuracy, brightness, contrast ratio, and viewing angles. Screen responsiveness (including touch response and latency) is very critical towards UI smoothness. Software and Operating System Software assessment Operating System Assess the version it uses (e.g. Android, iOS, Windows, etc). Check for support for the device, as well. Confirm that all software drivers will be up to date. Final Considerations Target Audience and Use Cases Throughout the review process, consider the target audience and intended use cases. Is this device meant for gaming, productivity, or general consumers? Ensure that the hardware configuration aligns with its intended purpose, and confirm all specifications against requirements. “`