NV6s_v2 is a NVSv2 family [Premium Storage capable] [Intel processor] 6 vCPUs server offered by Microsoft Azure with 6 vCPUs, 112 GiB of memory and 754 GB of storage. The pricing starts at 0.1264 USD per hour.
NVSv2 family [Premium Storage capable] [Intel processor] 6 vCPUs
Family
NVSv2
Hw Virt
-
Status
active
Observed At
2026-07-07T21:33:33.142146
Availability
REGION / ID
SPOT
ONDEMAND
South Central US (US) / southcentralus
0.1264 USD/h
0.684 USD/h
West US (US) / westus
0.1417 USD/h
0.767 USD/h
Processor
vCPUs
6
Hypervisor
Microsoft Hyper-V
CPU Allocation
Dedicated
CPU Architecture
x86_64
System Resources and Accelerators
MEMORY
Memory Amount
112 GiB
GPU
GPU Count
0.5
GPU Memory Min
0 MiB
GPU Memory Total
0 MiB
GPUs
STORAGE
Storage Size
754 GB
Storages
754 GB ssd (temp disk)
NETWORK
Inbound Traffic
0 GB/month
Outbound Traffic
0 GB/month
IPv4
0
Server Description
A memory-rich virtual machine featuring fractional GPU acceleration and high-capacity local storage for specialized database and visualization workloads.
GPU AcceleratedMemory OptimizedStorage & Database
Microsoft Azure NV6s_v2 is an x86_64 virtual machine within the NVSv2 family, running on the Microsoft Hyper-V hypervisor with dedicated Intel processors. It features 6 vCPUs and 112.0 GB of memory, providing a high memory-to-core ratio of 18.67 GB per vCPU. The instance is equipped with a fractional GPU allocation of 0.5 and includes 754 GB of local storage with Premium Storage capability. This hardware profile makes the NV6s_v2 highly suitable for memory-intensive workloads, database management, and entry-level GPU-accelerated applications that benefit from hardware acceleration without the cost of a full dedicated GPU.
Economics
Average Price per Region
Prices per Zone
Lowest Prices
Workload Profiles
Precomputed compound score for Cache Intensive workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 50% Redis RPS (pipeline=1, SET), 20% Redis RPS (pipeline=16, SET), 10% PassMark Memory Mark (composite), 10% Memory bandwidth (read, 16 MB ~ L3), 10% PassMark single-thread CPU. Rationale for component selection: In-memory key-value store workload, mixing direct Redis performance metrics with memory speed and latency benchmarks, and single-core CPU performance profiles.
Precomputed compound score for CI/CD Build workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 50% Geekbench Clang compilation (multi-core), 10% Geekbench Clang compilation (single-core), 20% stress-ng div16 best-N cores, 5% PassMark integer math, 5% PassMark compression, 5% Brotli compression (multi-core, level 0), 5% PassMark string sorting. Rationale for component selection: Build performance is mainly driven by multi-core compilation throughput, but also bundles single-core compilation speed and general CPU performance, multi-core compression and text/scripting processing.
Precomputed compound score for Compute Heavy Applications workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 15% stress-ng div16 best-N cores, 10% stress-ng div16 single core, 20% PassMark CPU Mark (composite), 10% Memory bandwidth (read, 64 MB), 15% PassMark floating point, 15% PassMark AVX/SSE/FMA (SIMD), 10% PassMark integer math, 5% PassMark physics simulation. Rationale for component selection: Number-crunching workload augmenting raw CPU performance stressing, general CPU performance benchmarks, memory bandwidth, and pure math computation speed like floating point, integer, SIMD (AVX/SSE/FMA) operations.
Precomputed compound score for Data Analysis workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 70% PassMark CPU Mark (composite), 10% Gzip compression (single-core, level 5), 10% Memory bandwidth (read, 64 MB), 10% PassMark Memory Mark (composite). Rationale for component selection: Data analysis and ETL workloads are memory-bandwidth-bound and CPU-throughput-driven. The profile combines general CPU performance and memory bandwidth/latency as the primary drivers, supplemented by single-core compression speed as a proxy for serialisation-heavy ETL tasks.
Precomputed compound score for LLM Inference workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 15% LLM text generation (SmolLM-135M, 128 tok), 15% LLM prompt processing (SmolLM-135M, 512 tok), 15% LLM text generation (Llama 7B, 128 tok), 15% LLM prompt processing (Llama 7B, 512 tok), 15% LLM text generation (Llama-3.3 70B, 128 tok), 15% LLM prompt processing (Llama-3.3 70B, 512 tok), 5% Memory bandwidth (read, 256 MB), 2% PassMark AVX/SSE/FMA (SIMD), 2% PassMark floating point. Rationale for component selection: VRAM and memory-bandwidth-bound LLM inference workload, using direct LLM speed benchmarks at three model sizes, and supplementing with raw memory bandwidth and SIMD performance benchmarks.
Precomputed compound score for Web Server workloads. A weighted average (geometric mean) of benchmark scores compared to their medians: score = ∏ (x_i / m_i)^(w_i / Σw). The score of 1.0 represents a synthetic baseline server with the median performance of each component benchmark; 0.5 means roughly half the performance; and 2.0 means twice the performance of that reference profile. Component weights: 30% Static web RPS (1 KiB, 8 conn/vCPU), 20% Static web RPS (64 KiB, 8 conn/vCPU), 20% Static web throughput (256 KiB, 8 conn/vCPU), 20% OpenSSL AES-256-CBC (16 kB blocks), 5% Gzip compression (multi-core, level 5), 5% PassMark string sorting. Rationale for component selection: Primary workloads drivers are single-process static HTTP serving speed and throughput, text processing, TLS termination, and asset compression.
NV6s_v2 is a NVSv2 family [Premium Storage capable] [Intel processor] 6 vCPUs server offered by Microsoft Azure with 6 vCPUs, 112 GiB of memory and 754 GB of storage. The pricing starts at 0.1264 USD per hour.
The NV6s_v2 server is equipped with 6 logical CPU cores on unknown number of physical CPU core(s), 112 GiB of memory, 754 GB of storage, and 0.5 GPU. Additional block storage can be attached as needed.
The pricing for NV6s_v2 servers starts at 0.1264 USD per hour, but the actual price depends on the selected region, zone and server allocation method (e.g. on-demand versus spot pricing options): currently, we track the prices in 8 regions and zones every 5 minutes, and the maximum price stands at 0.767 USD.
The NV6s_v2 server is offered by Microsoft Azure, founded in 2010, headquartered in Washington, United States. For more information, visit the Microsoft Azure homepage.
The NV6s_v2 server is available in 8 availability zones of the following 2 regions: South Central US (US), West US (US).
A memory-rich virtual machine featuring fractional GPU acceleration and high-capacity local storage for specialized database and visualization workloads.