Intel Core Ultra 5 134U -vs- Intel Core Ultra 9 185H
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Specs comparison between Intel Core Ultra 5 134U and Intel Core Ultra 9 185H
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Name | Intel Core Ultra 5 134U | Intel Core Ultra 9 185H |
Code Name?An internal name used by the manufacturer during the development of a processor architecture. It often indicates the generation or specific design of the processor. | Intel Meteor Lake-H | Intel Meteor Lake-H |
Series?The marketing name given to a specific family of processors within a brand's lineup, such as Intel Core i7 or AMD Ryzen 5. Series names help categorize processors based on performance and target market. | Intel Core Ultra Series 1 | Intel Core Ultra Series 1 |
Model Name?The marketing name given to a specific family of CPUs within a brand's lineup, such as 'Intel Ultra 5' or 'Intel Ultra 7'. Model names help categorize CPUs based on performance and target market. | Intel Core Ultra 5 | Intel Core Ultra 9 |
Instruction set?The set of commands that a processor understands and can execute. Different instruction sets support varying levels of performance and compatibility with software. | X86 | X86 |
Launch Date | 12/2023 | 12/2023 |
Vertical?The intended market segment or use case for the processor, such as desktop, laptop, server, or embedded systems. It indicates the processor's design and features tailored for specific applications. | Laptop | Laptop |
CPU | ||
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Total No. of Core?The total number of physical processing units within the processor. More cores allow the processor to handle multiple tasks simultaneously, enhancing multitasking performance. | 12 | 16 |
No. of P-Cores?The number of Performance cores (P-cores) within the processor. P-cores are designed for high-performance tasks and demanding applications. | 2 | 6 |
P-core Base Frequency?The standard operating speed of the Performance cores (P-cores), measured in gigahertz (GHz). It indicates the P-cores' baseline performance level. | 0.7 GHz | 2.3 GHz |
P-Cores Boost Frequency?The maximum speed a P-core can reach under heavy load, measured in gigahertz (GHz). It represents the P-cores' peak performance capability. | 4.4 Ghz | 5.1 Ghz |
No. of Ecore?The number of Efficiency cores (E-cores) within the processor. E-cores are designed for power efficiency and handling background tasks. | 8 | 8 |
Ecore Base Frequency?The standard operating speed of the E-cores, measured in gigahertz (GHz). It indicates the E-cores' baseline performance level. | 0.5 GHz | 1.8 GHz |
ECores Boost Frequency?The maximum speed an E-core can reach under heavy load, measured in gigahertz (GHz). It represents the E-cores' peak performance capability. | 3.6 GHz | 3.8 GHz |
No of LE-Cores?The number of Low Energy cores (LE-cores) within the processor. LE-cores are designed for very low power consumption and handling extremely light tasks. | 2 | 2 |
LE-Cores Base Frequency?The standard operating speed of the LE-cores, measured in gigahertz (GHz). It indicates the LE-cores' baseline performance level. | 0.4 GHz | 1 GHz |
LE-Cores Boost Frequency?The maximum speed an LE-core can reach under heavy load, measured in gigahertz (GHz). It represents the LE-cores' peak performance capability. | 2.1 GHz | 2.5 GHz |
No. of Threads?The number of virtual processing units a core can handle simultaneously. Threads enable a single core to process multiple instruction streams, enhancing efficiency. | 14 | 22 |
L1 Cache?The smallest and fastest cache memory level, located closest to the processor cores. It stores frequently accessed data for rapid retrieval. | 112 KB (per core) | 112 KB (per core) |
L2 Cache?A mid-level cache memory that provides a larger storage capacity than L1 cache. It stores data that is less frequently accessed than L1 but more frequently than L3. | 2 MB (per core) | 2 MB (per core) |
L3 Cache?The largest and slowest cache memory level shared by all processor cores. It stores data that is less frequently accessed than L2 but still needed for efficient operation. | 12 MB (shared) | 24 MB (shared) |
L1 Cache(E-core)?The L1 cache memory dedicated to the Efficiency cores (E-cores). It stores frequently accessed data for rapid retrieval by the E-cores. | 96 KB (per core) | 96 KB (per core) |
L2 Cache(E-core)?The L2 cache memory dedicated to the Efficiency cores (E-cores). It provides a larger storage capacity than the E-cores' L1 cache. | 2 MB (per module) | 2 MB (per module) |
Multiplier?A factor that determines the processor's clock speed by multiplying the base clock frequency. It influences the overall operating speed of the processor. | 7x | 39x |
Unlocked Multiplier?Indicates that the processor's multiplier can be adjusted, allowing for overclocking to increase performance beyond the default specifications. | No | No |
Package | ||
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Technology?The process used to create the processor, measured in nanometers (nm). Smaller manufacturing processes typically result in more efficient and powerful processors. | 7 nm | 7 nm |
Base Power Consumption?The typical power consumption of the processor under normal operating conditions, measured in Watts (W). It indicates the processor's energy efficiency. | 9 watt | 45 watt |
Max. Power Consumption?The maximum amount of power the processor can consume under heavy load, measured in Watts (W). It represents the processor's peak power usage. | 30 watt | 115 watt |
Socket?The physical interface on the motherboard where the processor is installed. The socket type determines compatibility between the processor and motherboard. | FCBGA2551 | FCBGA2049 |
Max. Temperature?The maximum safe operating temperature for the processor, measured in degrees Celsius (°C). Exceeding this temperature can lead to performance degradation or damage. | 110°C | 110°C |
IGPU | ||
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IGPU Name?The specific name given to the integrated Graphics Processing Unit (IGPU) by the processor manufacturer. It identifies the IGPU's architecture and capabilities. | Intel Graphics | Intel Arc graphics |
Base Frequency?The standard operating speed of the IGPU, measured in megahertz (MHz). It indicates the IGPU's baseline graphics processing power. | 600 MHz | 300 MHz |
Boost Frequency?The maximum speed the IGPU can reach under heavy graphics load, measured in megahertz (MHz). It represents the IGPU's peak graphics performance. | 1.75 GHz | 2.35 GHz |
Shading Units?The number of processing units within the IGPU responsible for rendering graphics. More shading units generally result in better graphics performance. | 512 | 1024 |
TMUs?Texture Mapping Units (TMUs) are processing units within the IGPU that apply textures to 3D surfaces. More TMUs improve the realism and detail of rendered graphics. | 64 | |
ROPs?Render Output Units (ROPs) are processing units within the IGPU that handle the final stage of rendering, converting pixel data into an image. More ROPs improve the frame rate and image quality. | 32 | |
Execution Units?The number of parallel processing cores within the IGPU. These units execute graphics instructions, and a higher number typically indicates better graphics performance. | 64 | 128 |
IGPU Perfomance?The overall graphics processing capability of the integrated GPU. This is measured by how well it can handle graphical tasks, such as video playback and light gaming. | 4.81 TFLOPS | |
NPU | ||
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NPU Name?The specific name given to the Neural Processing Unit (NPU) by the processor manufacturer. It identifies the NPU's architecture and AI processing capabilities. | Intel AI Boost | Intel AI Boost |
NPU TOPS?The processing power of the NPU, measured by how fast it can perform AI and machine learning operations. Higher NPU performance leads to faster AI-powered features. | 11 Tops | 11 Tops |
Display & Memory Support | ||
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Memory Support?The types and speeds of RAM that the processor is compatible with. It specifies the maximum amount and speed of RAM that can be used with the processor. | Up to LPDDR5/x 6400 MT/s | Up to LPDDR5/x 7467 MT/s Up to DDR5 5600 MT/s |
Max. Display Resolution Support?The highest resolution that the processor's integrated graphics or the processor in conjunction with a dedicated GPU can output to a display. It indicates the maximum visual fidelity the processor can support. | 7680 x 4320 @ 60Hz | 7680 x 4320 @ 60Hz |
Features | PCIe 4, Thr. Director, DL Boost, AI Boost, vPro Enterp., RPE, MMX, SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, AES, AVX, AVX2, AVX-VNNI, FMA3, SHA | PCIe 5, Thr. Director, DL Boost, AI Boost, vPro Enterprise, RPE, MMX, SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, AES, AVX, AVX2, AVX-VNNI, FMA3, SHA |
Features | Intel | Intel |
“`html Storage: Addressing Performance & Capacity Target: High-Performance Workloads NVMe SSDs: The New Standard Specification Review: The transition to Non-Volatile Memory Express (NVMe) solid-state drives (SSDs) is paramount. We specifically look for models that leverage PCIe Gen4 or Gen5 interfaces, providing significantly reduced latency and higher throughput compared to older SATA-based SSDs. Key metrics to consider include: **Sequential Read/Write Speed:** Look for sustained read/write speeds exceeding 7,000 MB/s and 6,000 MB/s respectively (ideally higher for Gen5). **Random IOPS (Input/Output Operations Per Second):** Focus on drives with high IOPS ratings; this reflects the drive’s ability to handle many small, random read/write operations. Target figures should be in the hundreds of thousands for random 4K reads/writes. **Endurance (TBW – Terabytes Written):** The Total Terabytes Written rating is a crucial indicator of the SSD’s lifespan. Higher TBW values represent better longevity. We should aim for TBW that matches expected workload characteristics. **Controller & NAND Flash Type:** A robust controller (e.g., Phison, Innogrit) and high-quality NAND Flash (TLC or better, ideally QLC with advanced error correction) contribute to performance and reliability. Capacity Considerations Target: Scalability Selecting the appropriate storage capacity is vital to future-proof systems. The growing datasets and computational demands require sufficient space. Factors include: Current Applications and Data Asses the current size of the data and forecast the growth, Expansion Slots Check if there is room to mount more storage RAID Configuration For mission-critical infrastructure, redundancy through RAID configurations (RAID 1/5/6/10) is essential. Analyze the performance impact vs. the potential for downtime. Storage Tiering:** Implement storage tiering – using faster, but potentially more expensive, storage for active data and cold storage for archival purposes. Target: Data Resiliency and Availability Implementing Hot Swappable and Redundant Components Specification Review: Maximizing uptime is critical. We should invest more time in selecting the storage and how the system is built. Hot-Swap Support: All storage components (SSDs, HDDs) should support hot-swapping, allowing the system to be serviced and repaired without requiring downtime. Redundant Power Supplies: Redundant power supplies (e.g., 1+1 or N+1) are essential to protect against single-point failures. Storage Enclosure and RAID Management:** A well designed storage enclosure should not only provide safe place to hold drives. It should also support various RAID levels and offer user-friendly management interface for online monitoring and fault detection. “`