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HighPoint’s SSD7105 is the fastest and most versatile NVMe RAID storage upgrade for PCIe Gen3 computing platformsMay 2022, Fremont, CA- HighPoint launches the SSD7105; the industry’s fastest bootable PCIe 3.0 x16 4x M.2 NVMe RAID solution. The SSD7105 is an ideal storage upgrade for any PCIe Gen3 desktop, workstation and server platform, and introduces several new features designed to streamline integration workflows, including a high-efficiency cooling system with full fan control, comprehensive Linux support, a new 1-Click Diagnostic solution, and our innovative Cross-Sync RAID technology.The compact controller is smaller than your average GPU yet can directly host up to four off-the-shelf2242/2260/2280/22110 double or single-sided M.2 NVMe SSDs, in one or more bootable RAID configurations. A single SSD7105 can support up to 32TB of storage at 14,000MB/s. Two SSD7105’s in a Cross-Synced RAID configuration can double these numbers; up to 64TB @ 28,000MB/s; faster than most PCIe Gen4 NVMe controllers!Replace aging SAS/SATA Infrastructure with Proven NVMe TechnologyNow is the best time to replace aging SAS/SATA storage infrastructure. NVMe technology is no longer restricted to niche applications or exotic hardware platforms; it is now well established and readily available.M.2 NVMe media, in particular, is more versatile and affordable than ever before. In many cases, M.2 SSDs are less expensive than their SAS/SATA counterparts. M.2 NVMe SSDs are now available with up to 8TB of capacity, and the performance advantages are immediately obvious; you would need 5 of today’s fastest SAS/SATA SSDs to keep up with your average M.2 drive, and 20 or more to match a simple 4x M.2 RAID 0 configuration hosted by theSSD7105! And thanks to the lack of moving parts, NVMe media is inherently more efficient and reliable than platter-based hard disk drives.All-in-one Performance and Security upgrade for any PCIe 3.0 Workstation & ServerThe vast majority of computing platforms in service today rely on PCIe 3.0 host connectivity. And the reason is simple - PCIe 3.0 is tried and true. The technology is mature; cost-effective, highly reliable and still capable of delivering excellent performance. Compatibility concerns are minimal, and solutions are available for nearly any application, budget and working environment.The SSD7105 allows you to squeeze every last drop out of your PCIe Gen3 host platform without compromising reliability – in fact, it can drastically improve efficiency and uptime of your server or workstation. In addition to the massive performance boost made possible by NVMe technology, the SSD7105’s Redundant RAID 1 and 10 capability can shield your bootable volume and mission critical data against the threat of hardware failure. Industry’s Only Bootable 4-Port PCIe 3.0 x16 NVMe RAID ControllerThe SSD7105 is the industry’s fastest bootable NVMe RAID solution for PCIe Gen3 host platforms. It is capable of delivering up to 14,000MB/s of transfer performance using off the shelf M.2 SSDs. The four independent ports and dedicated PCIe bandwidth ensure each SSD can operate at full speed, concurrently.And unlike most bootable NVMe controllers, which are restricted to specific platforms or configurations, the SSD7105 is no one-trick pony; it is an independent, multi-purpose, bootable NVMe RAID solution, and is capable of accommodating an enormous number of high-performance storage applications.For example, an administrator could configure each SSD to operate independently as a stand-alone boot drive. This type of configuration could be used to host a cost-effective Virtualization solution based around Hyper-V or Proxmox.The SSD7105 is also capable of hosting multi-RAID configurations, such as a secure, bootable RAID 1 volume alongside a blazing fast RAID 0 array tailored for a specific software suite or application. The possibilities are nearly endless!Need more than 14,000MB/s?HighPoint’s Cross-Sync Technology delivers Gen4 performance in a Gen3 package!HighPoint’s revolutionary Cross-Sync NVMe RAID technology allows administrators to combine two independent PCIe 3.0 RAID controller cards to function as a single device; effectively doubling your transfer bandwidth and storage capability!The process is seamless and entirely transparent to the host system. The Windows or Linux OS will recognize the two 4-port cards as a single 8-Port NVMe device. A dual-card Cross-Synced SSD7105 configuration can host up to 64TB of storage and deliver up to 28,000 MB/s of transfer performance – exactly what you would expect from today’s fastest 8-port PCIe Gen4 controllers!Works with all Major Windows and Linux PlatformsThe SSD7105 is fully compatible with all major Windows and Linux based operating systems. Comprehensive device driver support is available for Windows 11 and 10, Server 2022 and 2019, and Linux Distributions such as RHEL, Debian, Ubuntu, Fedora, Arch, Proxmox and Xenserver.In addition, we offer Binary driver development services, and Open-Source driver packages for other or non-standard distributions.Linux Binary Driver Packages are developed specifically for a particular distribution and kernel. Binary drivers are easy to install, even for novice Linux users.Linux Open-Source Package with Auto-Compilation packages are ideal driver for most Linux applications. The administrator need only install the root package; the driver will handle all future updates automatically, such as checking/monitoring the status of kernel releases, preparing the system environment, recompiling a new driver, and installation.macOS Support for Non-bootable storage configurations - SSD7105 is compatible with 2019 Mac Pro’s and legacy 5,1 workstation platforms, and can be used to host non-bootable NVMe SSDs and RAID arrays. Device drivers are available for macOS 10.x and 11.x.Advanced NVMe RAID EngineThe SSD7105’s advanced NVMe RAID engine is capable of supporting bootable RAID 0, 1, 10, arrays and single-drives, including mixed configurations of single-disks and arrays, multiple arrays, multiple boot volumes, and boot + storage configurations.RAID 0 (Striping) - Also known as a “stripe” array, this mode delivers Maximum Performance and capacity by linking multiple NVMe SSD's together to act as a single storage unit.RAID 1 (Mirroring) - This mode creates a hidden duplicate of the target SSD, and is ideal for applications that require an extra layer of data security.RAID 10 (Security & Speed) - RAID 10 offers the best of both worlds. Two RAID 1 arrays are striped together to maximize performance. RAID 10 is capable of delivering read performance on par with RAID 0, and is superior to RAID 5 for NVMe applications. Unlike RAID 5, RAID 10 doesn’t necessitate additional parity related write operations, which reduce the DWPD/TBW life span of NVMe SSDs.Ultra-Quiet Active Cooling Solution with Full Fan ControlThe SSD7105’s advanced cooling system combines a full-length anodized aluminum heat sink with an ultra-durable, near-silent fan, and high-conductivity thermal pad. This compact, ultra- efficient solution rapidly transfers waste heat away from critical NVMe and controller componentry, without introducing unwanted distraction into your work environment.Full Fan Control – By default, the SSD7105’s cooling system will automatically adjust fan speed to ensure NVMe media operates within their recommended temperature thresholds. However, advanced administrators can opt for full manual control. The WebGUI management suite provides 3 selectable speed settings, including an option to fully disable the fan. This feature is ideal for media and design applications that require low-noise or silent working environments, and utilize platforms already equipped with robust cooling systems.Thunderbolt™ Compliant NVMe RAID SolutionThe SSD7105 is fully Thunderbolt™ compliant, and is compatible with PCIe expansion chassis capable of hosting a standard full-height, full-length PCIe device such as the RocketStor 6661A. This enables the SSD7105 to host data-only SSD and RAID configurations for Mac platforms with Thunderbolt™ 3 connectivity.Comprehensive Monitoring & Management SuiteHighPoint believes that you should not need a professional IT background to configure, monitor and maintain NVMe and RAID storage configurations. Two comprehensive user interfaces are included with each SSD7105 RAID controller.The WebGUI is a simple, intuitive graphical user interface designed to work with all modern Web Browsers. It is equipped with Wizard-like quick configuration menus as well as a suite of advanced tools for expert administrators.The CLI (Command Line Interface) is ideal for seasoned administrators or platforms that do not utilize graphical operating systems.The WebGUI’s SHI Feature (Storage Health Inspector) allows administrators to instantly check the operating status of NVMe SSDs in real-time, such as temperature, voltage and TBW (Total Bytes Written). TBW tracking in particular, is essential for maintaining the long-term health of NVMe storage configurations. NVMe media have finite write capability; once the TBW threshold has been reached, the NVMe SSD should be replaced to avoid the risk of a write failure.Event & Error Logging with Email Notification: Each interface includes automated event logging with configurable Email Event NotificationIntelligent 1-Click Self-Diagnostic Solution: HighPoint’s Web-based graphical management suite (WebGUI) now includes a host of automated diagnostic tools designed to streamline the troubleshooting process, even for novice administrators. Customers no longer have to manually assemble a collection of screenshots, logs and status reports when submitting support inquiries. 1-click enables the interface to gather all necessary hardware, software and storage configuration data and compile it into a single file, which can be transmitted directly to our FAE Team via our Online Support Portal.Pricing and AvailabilityThe SSD7105 is slated for release in late May of 2022, and will be available direct from the Highpoint eStore and our North American Resale and Distribution partners.SSD7105 4xM.2 Bootable PCIe 3.0 x16 NVMe RAID Controller: MSRP: USSD$399.00。
集成显卡的显存相关知识 DVMT 动态显存技术电脑资料我们知道,许多应用程序(包括操作系统在内)都要求显卡的内存容量达到最低要求值时才能正常运行(甚至才能完全运行),因此,集成显卡的芯片组都使用了一些智能技术,在需要的时候用共享内存的方法来增加显存的容量,达到能运行应用程序的目的,一、HyperMemoryHyperMemory是ATI提出的允许图形卡和CPU共享系统内存,同时将可能出现的性能冲突降到最低的一项技术,HyperMemory技术的主要特点在于允许核心通过SystemBusInterface利用PCIExpress 总线庞大的带宽直接访问系统内存,在需要时将数据置于系统内存中进行操作,并通过新添加的MemoryController对本地显存和系统内存的访问与操作进行协调管理,使核心能更加合理、充分地利用本地显存和系统内存的资源,达到最终扩展总显存容量的目的。
以下为映泰TA690GAM2主板搭配512MB、1GB、2GB内存,在采用HyperMemory技术后,能分配的容量。
BIOS设置UMAFrameBufferSize为Auto时,物理内存总容量为2GB时候的测试图:注:上表列出了BIOS设置的各种情况下,通过HyperMemory技术显存所分配的系统内存的值。
当然,这只是最大限制值,实际使用仍然是按需获取的。
二、DVMT动态显存技术那么基于Intel845G/865G/915G/945G/965G芯片组的集成显卡又能共享多少系统内存呢?答案是:视情况而定,显存容量大小取决于系统以及动态分配共享显存技术(DVMT)设置的预分配内存。
DVMT用于动态分配系统内存作为显存,以确保最有效地利用可用资源来获得最佳2D/3D图形性能。
所分配的显卡内存容量取决于操作系统要求的内存量,当不再需要内存时,将它返还操作系统供其它应用程序或系统功能使用。
DVMT根据系统需求分配内存。
BIOS选项(DVMT/FIXEDMemory),用于调整可用于DVMT的内存容量。
它能做什么五核心异构x86 SoC英特尔Lakefield技术解析英特尔Lakefield技术是英特尔最新推出的一款五核心异构x86 SoC(系统片上系统),它采用了先进的Foveros三维封装技术,集成了多种不同架构的处理器核心,使得它在性能、功耗和整体体积上都有了非常大的突破。
下面我们来详细解析一下英特尔Lakefield 技术能做什么以及它的五个核心异构x86 SoC的特点。
英特尔Lakefield技术能够实现更高的性能和更低的功耗。
英特尔Lakefield技术集成了一个高性能的Sunny Cove核心和四个低功耗的Tremont核心,它们可以在不同的场景下合作工作,实现更高的性能和更低的功耗。
在性能密集型任务下,Sunny Cove核心可以提供更高的处理能力;而在轻负载的任务下,Tremont核心可以提供更高的能效比,从而延长设备的续航时间。
英特尔Lakefield技术能够实现更小的整体体积。
由于采用了先进的Foveros三维封装技术,英特尔Lakefield技术可以将不同架构的处理器核心集成在一块芯片上,从而大大减小了整体体积。
这对于轻薄笔记本、可穿戴设备和智能手机等移动设备来说,意味着可以在更小的空间内集成更多的功能,使得设备更轻更薄更便携。
第四,英特尔Lakefield技术能够实现更好的图形性能。
英特尔Lakefield技术集成了英特尔的第11代显卡核心,可以提供更好的图形处理能力。
这对于轻薄笔记本和可穿戴设备来说,意味着可以实现更好的图形渲染、更流畅的游戏体验和更高的多媒体处理能力。
英特尔Lakefield技术是一款五核心异构x86 SoC,在性能、功耗、整体体积、灵活应用和连接性能等方面都有了非常大的突破。
它可以广泛应用于轻薄笔记本、可穿戴设备、智能手机和平板电脑等移动设备,能够满足用户对于高性能、高能效比和便携性的多重需求。
相信随着英特尔Lakefield技术的不断演进和应用,它将为移动设备带来全新的体验和创新。
intel cpu型号大全2009年12月24日星期四 15:12intel cpu型号大全按照处理器支持的平台来分,Intel处理器可分为台式机处理器、笔记本电脑处理器以及工作站/服务器处理器三大类;下面我们将根据这一分类为大家详细介绍不同处理器名称的含义与规格。
由于Intel产品线跨度很长,不少过往产品已经完全或基本被市场淘汰(比如奔腾III和赛扬II),为了方便起见,我们的介绍也主要围绕P4推出后Intel发布的处理器产品展开。
台式机处理器Pentium 4(P4)第一款P4处理器是Intel在2000年11月21日发布的P4 1.5GHz处理器,从那以后到现在近四年的时间里,P4处理器随着规格的不断变化已经发展成了具有近10种不同规格的处理器家族。
在这里面,“P4 XXGHz”是最简单的P4处理器型号。
这其中,早期的P4处理器采用了Willamette核心和Socket 423封装,具256KB二级缓存以及400MHz前端总线。
之后由于接口类型的改变,又出现了采用illamette核心和Socket478封装的 P4产品。
而目前我们所说的“P4”一般是指采用了Northwood核心、具有400MHz前端总线以及512KB二级缓存、基于Socket 478封装的P4处理器。
虽然规格上不一样,不过这些处理器的名称都采用了“P4 XXGHz”的命名方式,比如P4 1.5GHz、P4 1.8GHz、P4 2.4GHz。
Pentium 4 A(P4 A)有了P4作为型号基准,那么P4 A就不难理解了。
在基于Willamette核心的P4处理器推出后不久,Intel为了提升处理器性能,发布了采用Northwood 核心、具有 400MHz前端总线以及512KB二级缓存的新一代P4。
由于这两种处理器在部分频率上发生了重叠,为了便于消费者辨识,Intel就在出现重叠的、基于Northwood核心的P4处理器后面增加一个大写字母“A”以示区别,于是就诞生了P4 1.8A GHz、P4 2.0A GHz这样的处理器产品。
它能做什么五核心异构x86 SoC英特尔Lakefield技术解析英特尔Lakefield是一种创新的SoC(系统芯片),它拥有五核心异构的设计,集成了x86架构处理器以及协处理器,能够为用户提供强大的计算性能和出色的功耗控制。
本文将对Lakefield技术进行深度解析,从其五核心异构设计、性能表现、能耗控制、应用场景以及未来发展前景等方面进行分析,帮助读者更加全面地了解这一新型芯片。
一、五核心异构设计Lakefield芯片拥有一个Sunny Cove核心和四个Tremont核心。
Sunny Cove核心采用了英特尔最新的10纳米制程工艺,拥有强大的计算能力和高效的性能表现。
而Tremont核心是一种低功耗、高效能的核心,可以为系统提供良好的功耗控制和节能表现。
通过这种异构设计,Lakefield在保证了高性能的也能够实现出色的功耗控制,为移动设备带来了更长的续航时间和更好的用户体验。
除了处理器核心,Lakefield还集成了英特尔的图形处理器以及专门用于加速人工智能计算的协处理器。
这种多核心异构设计使得Lakefield能够更好地适应不同的应用场景,同时也为其提供了更多的扩展性和灵活性。
二、性能表现在性能方面,Lakefield拥有出色的计算能力和多任务处理能力。
Sunny Cove核心能够提供强大的单线程性能,适用于高性能计算任务和对处理器性能要求较高的应用。
而Tremont核心则可以提供稳定的多任务处理能力,适用于日常办公、网页浏览等轻办公场景。
Lakefield还配备了英特尔的集成图形处理器,能够提供流畅的图形表现和良好的游戏体验。
而协处理器则可以加速人工智能计算,为用户提供更快速、更智能的应用体验。
Lakefield在性能表现上有着出色的表现,能够满足不同用户的多样化需求,同时也为移动设备带来了更多的创新可能性。
三、能耗控制Lakefield还具备智能功耗管理功能,能够根据不同的使用场景自动调整功耗模式,实现更加精准的功耗控制。
intel cpu fivr 原理摘要:1.Intel CPU FIVR 简介2.FIVR 的工作原理3.FIVR 的优势4.FIVR 的应用领域正文:【Intel CPU FIVR 简介】Intel CPU FIVR,全称为Intel CPU Flexible Intel Virtual RAID,是英特尔公司推出的一种存储技术。
它是一种软件RAID 解决方案,允许用户在英特尔处理器上创建虚拟RAID 阵列。
【FIVR 的工作原理】FIVR 的工作原理是在计算机系统中创建一个虚拟的RAID 控制器,然后将本地硬盘或SSD 划分为多个虚拟硬盘。
这些虚拟硬盘可以根据用户的需求组成不同的RAID 级别,如RAID 0、RAID 1 或RAID 5 等。
用户可以在这些虚拟硬盘上安装操作系统或存储数据。
【FIVR 的优势】FIVR 具有以下优势:1.灵活性:用户可以根据自己的需求创建不同大小的虚拟硬盘,并且可以根据需要更改RAID 级别。
2.易于管理:FIVR 通过英特尔AMT(Active Management Technology)提供远程管理功能,使得用户可以方便地管理虚拟硬盘。
3.高性能:FIVR 支持英特尔Turbo Boost 技术,可以提高硬盘性能。
【FIVR 的应用领域】FIVR 广泛应用于服务器领域,特别是在数据中心和云计算环境中。
它提供了一种灵活、高性能的存储解决方案,可以满足这些领域对存储的需求。
【结语】总的来说,Intel CPU FIVR 是一种灵活、高性能的存储技术,它可以帮助用户在英特尔处理器上创建虚拟RAID 阵列,满足不同场景的存储需求。
龙源期刊网 DVMT技术让集成显卡“少吃饭多干活”作者:晓峰来源:《电脑爱好者》2008年第05期用集成显卡的朋友多有这样一个疑问:现在内存越来越大,为什么“显存”调整到最大,也“只有”256MB?而且,显存再大,显示性能也没有什么提升,这是怎么回事呢?原来,有这类问题的读者朋友多使用着英特尔965G芯片组主板,这款主板芯片组采用了Intel研发的DVMT技术(Dynamic Video Memory Technology,动态显存技术)。
DVMT是英特尔针对集成图形芯片所提出的一项内存存取技术,它会根据目前系统正在执行的程序而释放所需要的内存容量。
为了充分合理地分配显存,英特尔集成显示核心将可以作为显存的系统内存划分为两个部分。
一部分是较小的GPU的独占空间,操作系统无法使用,大小从8MB到32MB;另一部分是通过DVMT技术划分给显示核心。
在BIOS设置中,DVMT有三种模式:Fixed、DMVT和Both(Fixed+DMVT模式)。
在Fixed模式中,一部分固定容量大小的系统内存将被分配到图形核心。
它只能供图形核心使用,它的容量大小可以设置为64MB或128MB。
在DMVT模式中,显示核心的驱动程序可以像操作系统或其他应用程度一样使用系统内存。
如果运行一款大型的3D游戏,图形纹理、几何数据等都需要占用大量的显存资源,当此前分配的共享内存不能满足应用程序需要时,就会自动向系统发出指令,要求将内存供给图形核心使用。
而当GPU不再需要使用那么多内存时,它会自动将不用到的内存再还给操作系统。
在这种模式下,显示核心的最大共享内存可以达到224MB(包括专门为GPU分配的内存空间)。
而在Both(Fixed+DVMT)模式中,显示核心本身独占一个128MB的内存空间,而后还有128MB的动态内存分配空间,这样显示核心最少有128MB而最大有256MB的存储空间。
如果您的内存较小,建议设置成DVMT模式,系统会自动分配显存容量的大小,从而在针对不同的应用中都会有不错的表现(比如在文本处理的时候可以释放更多的内存,而在密集的3D运算的时候则会把显存容量提升到最高)。
