Figure 3 shows the network stream throughput and CPU utilization for the bidirectional scalability test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图3显示双向可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 6 shows the network stream throughput and CPU utilization for the bidirectional scalability test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图6显示双向可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 12 shows the network stream throughput and CPU utilization for the test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图12显示测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 11 shows the network stream throughput and CPU utilization for the netperf scalability test runs while utilizing the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图11显示netperf可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 4 shows the network stream throughput and CPU utilization for the netserver scalability test runs while utilizing the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图4显示netserver可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 10 shows the network stream throughput and CPU utilization for the netserver scalability test runs while utilizing the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图10显示netserver可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 1 shows the network stream throughput and CPU utilization for the netserver scalability test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图1显示netserver可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 5 shows the network stream throughput and CPU utilization for the netperf scalability test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图5显示netperf可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 7 shows the network stream throughput and CPU utilization for the netserver scalability test runs while using the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图7显示netserver可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 8 shows the network stream throughput and CPU utilization for the netperf scalability test runs while utilizing the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图8显示netperf可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Figure 2 shows the network stream throughput and CPU utilization for the netperf scalability test runs while utilizing the system board Ethernet adapters on 1, 2, and 4 nodes of the SUT.
图2显示netperf可伸缩性测试的网络流吞吐量和系统cpu利用率,分别使用SUT中1、2和4个节点上的系统板载以太网适配器。
Buses also link the CPU to various other components on the system board.
巴士也连接的CPU系统板上的各种其他组件。
This paper presents a new design method of CPU Board for microcomputer relay protection.
本文提出一种用于微机继电保护的CPU主板的新设计方法。
In order to solve the test and fault diagnosis problem of airborne CPU board, fault relationship method, function encode method and so on are put forward.
针对某机载CPU板硬件检测与故障诊断的问题,提出了故障关联、功能点编码等检测方法。
The super CPU main board monitors the operation in real time. If any abnormal situation occurs, it automatically brakes and records the malfunctions code.
超强的CPU主板电脑控制,实时监控运行状况,发现异常及时自动停止,即时自动记录并显示故障代码。
Features are: reduced occupancy rate of CPU in main board and in standby board, and raised backup efficiency.
主、备用板上的传输接口连接,在主用板和备用板间传输数据。
The on-board CPU is enhanced 80c320, which can implement complicated measuring and control tasks as desire and is suitable to the measuring and control automation demands of power system.
在板cpu为高性能单片机80c32 0,可根据用户需求完成复杂的测量控制任务。很适合电力系统的测控自动化需求。
We are currently executing commands on the CPU so we are using its on board memory.
我们目前正在执行命令的CPU所以我们使用板上存储器。
From here is main board, CPU, memory, display card, external storage and power supply.
依次是主板,中央处理器,内存,显卡,外部存储器,和电源。
Based upon the multi-CPU modularized hardware, the software of this system is divided into several parts. Each part performs a special task in cooperation with the corresponding hardware board.
基于多cpu模块化硬件结构,控制系统的软件结构也是模块化的,各软件模块配合相应的硬件模块完成专门的任务。
The controller main-board is designed with TMS320F2812 as its CPU, and also sets the serial interface and input and output of the switching value on it .
利用TMS320F2812作为CPU设计了控制器主板,同时引出了串口和开关量输入输出模块。
The module with an embedded CPU has a data acquiring board based on detecting waveform peaks and high speed data compression for capturing the signal of the outburst failure.
采用嵌入式单片机作为在线监控系统的核心芯片,设计了基于波峰检测的高速数据压缩的数据采集模块,捕获突发的故障波形。
The module with an embedded CPU has a data acquiring board based on detecting waveform peaks and high speed data compression for capturing the signal of the outburst failure.
采用嵌入式单片机作为在线监控系统的核心芯片,设计了基于波峰检测的高速数据压缩的数据采集模块,捕获突发的故障波形。
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