LB EX

Excel单选题1、默认状态下打开Excel 2003，新建工作簿的默认文件名是___B__A) Excel1.exl B) Book1.xls C) XL1.doc D) 文档1.doc2、下列对Excel 2003工作表的描述中，正确的是__D___A) 一个工作表可以有无穷个行和列B) 工作表不能更名C) 一个工作表就是一个独立存储的文件D) 工作表是工作薄的一部分3、启动Excel 2003，系统会自动产生一个工作簿Book1，并且自动为该工作簿创建__B__张工作表。

A) 1 B) 3 C) 8 D) 104、当输入的字符串长度超过单元格的长度范围时，且其右侧相邻单元格为空，在默认状态下字符串将__D__A) 超出部分被截断删除B) 超出部分作为另一个字符串存入B1中C) 字符串显示为##### D) 继续超格显示5、在Excel 2003工作表中，不能进行操作的是__A__。

A) 恢复被删除的工作表B) 修改工作表名称C) 移动和复制工作表D) 插入和删除工作表6、在Excel 2003中，下列对于日期型数据的叙述错误的是__D___A) 日期格式有多种显示格式B) 不论一个日期值以何种格式显示，值不变C) 日期字符串必须加引号D) 日期数值能自动填充7、在Excel 2003中，为了加快输入速度，在相邻单元格中输入“二月”到“十月”的连续字符时，可使用D功能。

A) 复制B) 移动C) 自动计算D) 自动填充8、在Excel 2003中，取消所有分类汇总的操作是__D___A) 按Delete B) 在编辑菜单中选“删除”选项C) 在文件菜单中选“关闭”选项D) 在分类汇总对话框中点“全部删除”按钮9、在Excel 2003中，关于选定单元格区域的说法，错误的是__D__A) 鼠标指向选定区域左上角单元格，拖动鼠标到该区域右下角单元格B) 在名称框中输入单元格区域的名称或地址并按回车键C) 选定区域左上角单元格，再按Shift键、单击该区域右下角单元格D) 单击要选定区域的左上角单元格，再单击该区域的右下角单元格10、在Excel 2003中，选择活动单元格输入一个数字后，按住__B_键拖动填充柄，所拖过的单元格被填入的是按1递增或递减数列。

大隈公司数控车床、车削中心品种规格表系列分类特点加工直径(mm)100 200 300 400 500 600GENO S系列卧式数控车床和车削中心数控车床单刀架L250L200EL400L400E车削中心带动力刀具(M)L200-ML200E-ML300-ML300E-M可切直槽(MY)L200-MYL200E-MYL300-MYL300E-MY带副主轴(W)L300-MWL300E-MYWLBEX Ⅱ系列卧式数控车床和车削中心数控车床单刀架LB2000EXⅡLB3000EXⅡLB4000EXⅡLB35ⅢLB45Ⅲ车削中心带动力刀具(M)LB2000EXⅡ-ML200-MLB3000EXⅡ-ML300-MLB4000EXⅡ-MLB35Ⅲ-MLB45Ⅲ-M可切LB2000EXⅡ-MY LB3000EXⅡ-MYLB4000EXⅡ-MYLB35Ⅲ-MYLB45Ⅲ-MY直槽(MY ) 带副主轴(W) LB2000EXⅡ-W(MW)LB3000EXⅡ-W(MW)(MYW)LUEX 系列卧式双刀架数控车床数控车床双刀架LUS1600LU3000EX LU4000EX LU35ⅡLU45Ⅱ车削中心带动力刀具(M)LU3000EX-M LU4000EX-MLU35Ⅱ-MLU45Ⅱ-MLTEX系列卧式双刀架双主轴车削中心车削中心带动力刀具(M)LT2000EX-M LT3000EX-M可切直槽(MY)LT2000EX-MY LT3000EX-MYMULTUS BⅡ系列卧式复合车铣中心车铣中心单刀架B200ⅡB300ⅡB400ⅡB550 B750 带副主轴(W)B200ⅡW B300ⅡW B400ⅡW B750WMULTU S U系列卧式车铣中单刀架U3000 U4000复合车铣中心心双刀架U3000 U4000 带副主轴(W)U3000 U4000 大隈公司立式数控车床、车削中心品种规格表系列分类特点加工直径(mm)400 600 800 1000 1200 1600 2000 3000 3500V系列数控立式车床数控车床单主轴V40R V60R V80R V100R 双主轴2SP-V42SP-V62SP-V80VTM系列车削中心车削中心带换刀刀库VTM-65VTM-10VTM-200VTM-Y B系列车铣中心车铣中心带Y、B轴VTM-80YBVTM-1200YBVTM-200YB龙门式复合车铣中心车铣中心龙门式VTR-160AVTR-200AVTR-280AVTR-350A大隈公司加工中心品种规格表系列分类特点工作台尺寸(mm)400 500 600 700 950 1000立 No.40MB-46VA MB-56VA MB-66VA式加工中心一般加工刀柄MP-46VAMB-46VAENo.50刀柄MB-46VBMB-46VBEMB-56VB MB-66VBMILLAC761VMILLAC852VMILLAC1052V五轴加工No.40刀柄MU-400VⅡMU-500VⅡMU-5000V-LMU-6300V-LMU-8000V-LNo.50刀柄MU-5000V-LMU-6300V-LMU-8000V-L卧式加工中心分类特点工作台尺寸(mm)400×400 500×500 630×630 800×800 1000×1000 1600×1600一般加工No.40刀柄MA-400HA MA-500HIINo.50刀柄MA-500HII MA-600HII MA-800HB批量生产No.40刀柄MB-4000H MB-5000HNo.50刀柄MB-8000H MB-10000H龙门式五面体加工中心分类特点工作台尺寸(mm)1,200 1,500 2,000 2,500 3,000龙门式Z轴450mm动梁式MCV-AⅡMCV-AⅡZ轴800mm定梁式MCR-AF MCR-AF五面体Z轴800mm四个头MCR-A5CIIMCR-A5CII MCR-A5CII MCR-A5CII Z轴800mm任意头MCR-BⅢMCR-BⅢMCR-BⅢMCR-BⅢ Z轴1000mmMCR-C MCR-C MCR-C任意头。

excel计算机一级试题excel单选题1、默认情况下打开Excel 2022。

新工作簿的默认文件名为__b__a)excel1.exlb)book1.xlsc)xl1.docd)文档1.doc2、下列对excel2021工作表的描述中，正确的是__d___a)一个工作表可以有无穷个行和列b)工作表不能更名c)一个工作表就是一个独立存储的文件d)工作表是工作薄的一部分3、启动Excel 2022，系统将自动生成工作簿Boo1，并自动创建一个工作簿，用于工作表。

a） 1b）3C）8D）104。

当输入字符串的长度超过单元格的长度范围，并且右侧相邻的单元格为空时，默认情况下，字符串将为空。

\uuud_uua）多余部分被截断并删除b）多余部分作为另一个字符串存储在B1中c)字符串显示为#####d）继续hypergrid显示d)插入和删除工作表5、在Excel 2022工作表中，不能运行的是iSyaAy.a）还原删除的工作表b）修改工作表名称c）移动并复制工作表6、在excel2021中，下列对于日期型数据的叙述错误的是__d___a)日期格式有多种显示格式b)不论一个日期值以何种格式显示，值不变c）日期字符串必须被引用d)日期数值能自动填充7、在Excel 2022中，为了加快输入速度，在相邻单元中从“二月”到“十月”连续输入字符时，可以使用D函数。

a）复制b）移动C）自动计算d）自动填充8。

取消Excel 2022中的所有小计Yes Sydz Dysa a）按DeleTeb）并在编辑菜单中选择“删除”选项c)在文件菜单中选“关闭”选项d）单击“小计”对话框中的“全部删除”9、在excel2021中，关于选定单元格区域的说法，错误的是__d__a)鼠标指向选定区域左上角单元格，拖动鼠标到该区域右下角单元格b)在名称框中输入单元格区域的名称或地址并按回车键c）选择范围的左上角单元格，按shift键并单击范围的右下角单元格。

阿城继电保护装置运行异常告警信息中英文对比一、保护装置自检信息
二、发电机保护装置运行告警信息
1、差动保护（ARG-811）
2、后备保护（ARG-812）
3、差动保护装置运行告警（ARG-811）
4、后备保护装置运行告警（ARG-812）
三、并网线线路保护装置告警信息1、
2、
3、
四、主变保护装置运行告警信息
ART-811 装置动作SOE信息
序号17～ 20 是装置操作插件的内部开入。

ART-811装置开关变位信息
ART-811装置运行告警信息
ART-812装置运行告警信息
五、厂变运行告警信息
六、高压电机设备运行告警信息
ARM-853保护装置告警信息
ARM-853保护装置告警信息
七、通讯管理装置运行告警信息。

计算机一级考试Excel2003题库1、默认状态下打开Excel 2003，新建工作簿的默认文件名是_____。

A.Excel1.exlB.Book1.xlsC.XL1.docD.文档1.doc 22、在Excel 2003中，取消所有自动分类汇总的操作是_____。

A.按DeleteB.在编辑菜单中选“删除”选项C.在文件菜单中选“关闭”选项D.在分类汇总对话框中点“全部删除”按钮 43、在Excel 2003中，下列对于日期型数据的叙述错误的是_____。

A.日期格式有多种显示格式B.不论一个日期值以何种格式显示，值不变C.日期字符串必须加引号D.日期数值能自动填充 34、下列对Excel 2003工作表的描述中，正确的是_____。

A.一个工作表可以有无穷个行和列B.工作表不能更名C.一个工作表就是一个独立存储的文件D.工作表是工作薄的一部分 45、在Excel 2003中，关于选定单元格区域的说法，错误的是_____。

A.鼠标指向选定区域左上角单元格，拖动鼠标到该区域右下角单元格B.在名称框中输入单元格区域的名称或地址并按回车键C.选定区域左上角单元格，再按Shift键、单击该区域右下角单元格D.单击要选定区域的左上角单元格，再单击该区域的右下角单元格 46、下列关于Excel 2003的样式与模板的叙述，正确的是_____。

A.样式只包括单元格格式的设定，模板则包括工作表的内容与所有格式B.样式只能设定单元格格式，而模板则用来设定单元格的大小C.模板与样式不同，但都只包括单元格格式的设定D.模板就是样式的另一种叫法 17、在Excel 2003单元格中，字符型数据的默认对齐方式是_____。

A.右对齐B.左对齐C.居中D.分散对齐28、在Excel 2003单元格中，若要将数值型数据500显示为500.00，应将该单元格的单元格格式设置为_____。

A.常规B.数值C.自定义D.特殊29、当输入的字符串长度超过单元格的长度范围时，且其右侧相邻单元格为空，在默认状态下字符串将_____。

更新日志表：（大约每次更新间隔为两天到一个星期因为临近考试没什么时间的……）小毬库特来谷叶留佳西园铃BAD 铃END追加Refrain完成踌躇最后三线……经过四天奋战沙耶双线测验翻译测验完毕并追加沙耶学园革命线！修正佐佐美来谷沙耶通常理树笨蛋理树错误追加真人END。

库特来古第二个END追加将漏掉的攻略顺序填补感谢报错同学文章整理增加建议一点鸣谢以下报错同学：davislove、linxinchencc、leafzz、藤林的牡丹推荐游戏方式：每完成一条线True End后选择New game 这样将会有部分剧情变化而且人物属性也会有所成长注意不是继承日文攻略在这里本人的翻译文本就是他：[url]/game/key/littlebustersEX.html[/url]目前进度为小毬线：完成库特线：完成叶留佳：完成来谷线：完成西园线：完成铃BAD ：完成铃END ：完成refrain：完成佐佐美：完成沙耶线：通常理树完成：笨蛋理树完成：学园革命完成佳奈多：完成真人线：完成推荐攻略顺序：1.世界的秘密不知道的情况下：[小毬or库特or叶留佳or来谷or西园or铃BAD]→铃→Refrain→[库特2&来谷CG回收orRefrain]→沙耶or佳奈多or佐佐美2.世界的秘密知道的情况下：（沙耶、佐佐美、佳奈多可以在Refrain前攻略）铃线仍需5线和铃BAD做前置前置5线任意顺序3 本人建议：小球→库特→来谷→西园→铃BAD→叶留佳→Refrain→Refrain→来古CG回收→库特2→佳奈多→沙耶通常V→沙耶笨蛋V→学员革命→佐佐美（叶留佳线后貌似会出现叶留佳接球失误或受伤推出训练的情况所以把她放在没有棒球赛的Refrain前面了）P.S 棒球练习中来谷周围如果有小猫（多路基不算）来谷将无视掉所有飞来的球P.S 棒球练习中铃在与佐佐美棒球对决后打小猫（多路基不算）会增加铃的怒气怒气积累到一定程度就会觉醒新球技注意雷神喵喵球和真雷神喵喵球会消耗怒气但每次练习结束并不会将怒气清零但是连续使用雷神球可能会将怒气消耗至零怒气为零后短期内不会使用雷神球或者不消耗怒气P.S 开启与佐佐美对战小技巧可以一开始闲逛的时候使用save load方法来遇见铃并输给她然后让铃的排位超过理树然后下一次闲逛再次不断使用此法来遇见铃然后不申请对战选择交换东西注意不是接受赠品然后将自己的好属性的物品给铃注意哑铃等右下角还有UP字样的只对理树有效这样铃就可能能赢佐佐美这个所有周目都适用只不过后面即使没什么物品打佐佐美也很容易了P.S 众猫名字希特勒法布尔爱因斯坦成龙勇作亚里士多德奥熏丽科班北斋盖茨菲德尔手？多路基P.S 关于棒球赛因为能力成长只有理树和铃所以要从一开始就做好准备请开启对战排位赛然后每次闲逛前保存注意不要让真人参加到战斗真人不参加到战斗的话有一定几率装备中出现哑铃握力器铁哑铃之类的道具这些道具只针对理树有效可以在每天过后增加理树的力量体力等所以闲逛之后如果真人戴上了这个道具就等下次与他交换到吧没带上就多Save Load几次总之一直换到三个铁哑铃就差不多了（看Rp了吧我到现在还没弄到这么多过）小毬线5.14 Mon出声招呼不怎么好不怎么好不怎么好不怎么好5.15 Tue借去找她（找找看）就这么看着用别笔记的代替5.16 Wed追铃暂时看着（CG回收）赶紧找人接受去凑热闹（CG回收）结束吧（不结束并不影响剧情，可以增加队员能力增长）帮忙找5.17 Thu找找看沉默追铃暂时看着去屋顶(棒球练习中多路基出现一只肥肥不明生物体。

VPL-EX4353,200 lumens XGA compact projectorOverviewPresent clear, bright images, with flexible connectivity and low running costs The VPL-EX435 projector is ideal for mid-sized classrooms and meeting rooms.Quiet, compact and powerful, it delivers XGA images with 3,200 lumens colour light output and high 20,000:1contrast ratio, with Sony's 3LCD technology assuring natural, vivid colours. Image quality is further improvedcompared with previous models, with a new colour/white balance setting for crisp reproduction of on-screen text and a new 'Vivid' picture mode ensuring even richer, more vibrant colours.The VPL-EX435 is an ideal partner for today's integrated AV/IT environments, expanding your connectivity options with dual HDMI ports and Direct USB Display connection. A convenient input label function makes life simpler,confirming on screen the name of connected devices.Add the VPL-EX435 to a network and see presentations from up to four connected PC/Mac computers simultaneously. Slip in an optional Wi-Fi dongle and present directly wirelessly from laptops.A range of energy-saving features plus up to 10,000 hours recommended lamp replacement time contribute to low ownership costs. Routine maintenance is quick and easy with a convenient rear lamp access feature.Features•Bright, clear images with maximum 3,200 lumens colour light outputWith a 3,200 lumen maximum light output (in high mode), the VPL-EX435 delivers crisp, high-contrastpresentations that can be seen clearly in bright rooms or on larger screens. There’s a choice of threebrightness modes to suit any environment, from bright daylight to darkened rooms.•3LCD BrightEra™ technologyThe efficient 3LCD panel system is enhanced by advanced BrightEra™ technology for impressively bright, consistent, high resolution images with excellent colour accuracy and impressive reliability.•XGA resolutionXGA (1024 x 768) 4:3 display resolution gives plenty of crisp detail: ideal for making presentations direct froma laptop, mobile device or DVD player.•Powerful 16W audioThe powerful built-in 16W speaker (mono) lets your audience hear video soundtracks with no need foradditional amplification.•Energy efficient with long-lasting lamp life up to 10,000 hoursHigh-performance lamp technology offers reduced ownership costs plus reduced maintenance, with arecommended lamp replacement time of approx. 10,000 hours (with brightness in low mode - may varydepending on environment or how the projector is used).•Advanced energy-saving featuresAdvanced lamp technology enables a range of energy-saving features. Auto Light Dimming mode saves energy when the projector is left on without being used. Auto Picture Mode automatically adjusts lightoutput to suit the projected scene. Touching a button on the remote mutes the picture temporarily,dramatically reducing power consumption.•Quiet operationNear-silent projector fan ensures discreet, unobtrusive operation in classrooms and meeting rooms.Lamp mode : 35dB / Standard 33dB / Low 29dB•Auto power onSave time and start presenting faster: the projector automatically turns on when signals are detected from a connected PC.•Quick goDon't waste time when you're in a hurry to leave the room: turn off the projector and unplug immediately, with no lengthy waiting for cool-down.•Networked and wireless presentationsProject presentations from PC or Mac via network and wireless. Up to four users can project PC/Mac images simultaneously, while up to eight users can connect to one projector. The Projector Station for NetworkPresentation application for Windows/Mac is included.•Control and management from any networked PCProjector functions and status can be managed and monitored remotely from any networked PC, using the included Projector Station for Network Control application.•Remote Control app for iOS/AndroidDownload the free Projector Remote app and control the projector from anywhere in the room with your handheld device, with simple easy-to-read buttons on your phone or tablet screen.•USB media viewerSlip in a USB drive and display photos, images and graphics with no PC needed.•Dual HDMI inputsTwo HDMI input terminals make it easy to connect HDMI-equipped devices like PCs and media streaming devices.•IP control sync for easy system expansionControl signals (power on/off, input select) from a master projector can be distributed over an IP network to additional 'sub' projectors.•USB Display function for easy one-cable PC connectionPresent pictures and audio* from a connected PC or Mac with a single USB cable - you don't even need to install a software driver.* There may be a time lag between video and audio. For low-latency applications it is recommended to use projector's line-in or HDMI-in connection.•Customised input naming labelsDefine your own input labels like 'BD Player', 'PC' and 'Document Camera', making it easier to see on screen what devices are connected and being used.•Easy maintenanceConvenient lamp access at the rear of the projector body makes lamp swaps simpler when the projector is hanging from a ceiling mount.Display System• Display System 3 LCD systemDisplay device• Size of effective display area0.63” (16mm) x 3 BrightEra LCD Panel Aspect ratio 4:3• Number of pixels2,359,296 (1024x768 x 3) pixelsProjection lens• Focus Manual• Zoom Powered/Manual Manual• Zoom - Ratio Approx. x 1.2• Throw Ratio 1.47:1 to 1.77:1Light source• Type Ultra high pressure mercury lamp• Wattage225 W typeRecommended lamp replacement time *3• Lamp mode: High4000 H• Lamp mode: Standard6000 H• Lamp mode: Low10000 HFilter cleaning / replacement cycle (Max.)• Filter cleaning / replacement cycle (Max.)10,000HScreen size• Screen size30" to 300" (0.76 m to 7.62 m) (measured diagonally)Light output *1• Lamp mode: High3200 lm • Lamp mode: Standard2300 lm • Lamp mode: Low1800 lmColor light output *1• Lamp mode: High3200 lm • Lamp mode: Standard2300 lm • Lamp mode: Low1800 lmContrast ratio (full white / full black) *2• Contrast ratio (full white / full black) *220000:1 Speaker• Speaker Speaker 16 W (monaural)Displayable scanning frequency• Horizontal15 kHz to 92 kHz• Vertical48 Hz to 92 HzDisplay resolution• Computer signal input Maximum display resolution: 1600 x 1200 dots, fV:60Hz• Video signal input NTSC, PAL, SECAM, 480/60i, 576/50i, 480/60p, 576/50p, 720/60p, 720/50p, 1080/60i, 1080/50i,1080/60p, 1080/50pColour system• Colour system NTSC3.58, PAL, SECAM, NTSC4.43, PAL-M, PAL-N, PAL60Keystone Correction (Max) *4• Vertical+/-30 degreesOSD languages• OSD languages 27-languages (English, French, German, Italian, Spanish, Portuguese, Japanese, Simplified Chinese, Traditional Chinese, Korean, Russian, Dutch, Norwegian, Swedish, Thai, Arabic ,Turkish, Polish, Vietnamese, Farsi, Finnish, Indonesian, Hungary, Greek, Czech, Slovakia, Romania)INPUT OUTPUT (Computer/Video/Control)• INPUT A RGB / Y PB PR inputconnector: Mini D-sub 15 pin femaleAudio input connector: Stereo mini jack• INPUT B RGB input connector: Mini Dsub 15 pin femaleAudio input connector: Stereo mini jack• INPUT C HDMI input connector: HDMI 19-pin, HDCP supportAudio input connector: HDMI audio support• INPUT D HDMI input connector: HDMI 19-pin, HDCP supportAudio input connector: HDMI audio support• S VIDEO IN S Video input connector: Mini DIN 4-pin• VIDEO IN Video input connector: Phono jack• OUTPUT MONITOR output connector: Mini D-sub 15 pin femaleAudio output connector: Stereo mini jack• REMOTE D-sub 9-pin male/RS232C• LAN RJ-45, 10BASE-T/100BASE-TX• USB Type-A• USB Type-B• MICROPHONE IN Microphone jack: Mini JackAcoustic Noise *5• Lamp mode: Low29dBOperating temperature / Operating humidity• Operating temperature / Operating humidity0°C to 40°C (32°F to 104°F) /20-80% (no condensation)Storage temperature / Storage humidity• Storage temperature /Storage humidity-10 °C to +60°C (14°F to +140°F) /20% to 80% (no condensation)Power requirements• Power requirements AC 100 V to 240 V, 3.4 A to 1.5 A, 50 Hz / 60 HzPower consumption• AC 100 V to 120 V Lamp mode: High 333 W• AC 220 V to 240 V Lamp mode: High 320 WPower Consumption (Standby Mode)• AC 100 V to 120 V0.50 W (when “Standby mode” is set to “Low”）• AC 220 V to 240 V0.50 W (when “Standby mode” is set to “Low”）Power Consumption (Networked Standby Mode)• AC 100 V to 120 V 5.5W (LAN)6.0W (optional WLAN module)6.2W (ALL Terminals and Networks Connected, when "Standby Mode" is set to "Standard")• AC 220 V to 240 V 5.8W (LAN)6.3W (optional WLAN module)6.6W (ALL Terminals and Networks Connected, when "Standby Mode"is set to "Standard")Standby Mode Networked Standby Mode Activated• Standby Mode Networked Standby Mode Activated Approx. 10 Minutes Wireless Network(s) On/Off Switch• Wireless Network(s) On/Off Switch1) Press the MENU button, then select [Connection/Power]2) [WLAN Settings]3) [WLAN Connection]4) Select On or OffHeat dissipation• AC 100 V to 120 V1136 BTU/h• AC 220 V to 240 V1092 BTU/hDimensions (W x H x D)• Dimensions (W x H x D) (without protrusions)Aprox. 365 x 96.2 x 252mm (14 3/8 x 3 25/32 x 9 29/32”)Mass• Mass Approx. 3.9kg (8.6 lb)Supplied accessories• Remote commander RM-PJ8Wireless LAN Module• Optional Lamp LMP-E221• Optional Accessories IFU-WLM3Notes• *1The values are estimate• *2This value is average with lamp dimming.• *3The figures are approximate. They vary depending on the environment or how the projector is used.• *4The picture quality may deteriorate when the V Keystone function is used for it is an electrical correction.• *5The figures are approximate. They vary depending on the environment or how the projector is used.LMP-E221Replacement Lamp for the VPL-E300/E400/E500 SeriesLampsAccessories。

DLX指令集,BYU版本注意8条指令已经加入到此版本的指令集中。

这些指令既没有出现在Hennessy和Patterson的课本中，也没有列在Sailer和Kaeli合编的"The DLX Instruction Set Architecture Handbook"一书中。

新的指令是：sgeu,sgtu,sleu,sltu--all compares using unsigned values--along with an immediate form of each.The new instructions were added to simplify the DLX backend for lcc.标记符号意义x_y bit y of xx_y..z bits y to z of x(right justified)x^y xx....x(x repeated y times)x##y xy(x concatenated with y)IR指令寄存器IAR中断地址寄存器PC程序计数器R[rega]整数寄存器[IR_6..10]R[regb]整数寄存器[IR_11..15]R[regc]整数寄存器[IR_16..20]F[frega]浮点寄存器[IR_6..10]F[fregb]浮点寄存器[IR_11..15]F[fregc]浮点寄存器[IR_16..20]D[drega]double register[IR_6..10]D[dregb]double register[IR_11..15]D[dregc]double register[IR_16..20]imm16value of(IR_16)^16##IR_16..31uimm16value of0^16##IR_16..31imm26value of(IR_6)^6##IR_6..0fps floating point status bit<--a32-bit transfer<--n an n-bit transfer注意/假设∙Bits are numbered from0(the most significant bit)to31(the least significant bit).∙All transfers are32bits unless otherwise specified,with the exception of double precision fp operations which are64bit transfers unless otherwise noted.∙All integer operations are on32-bit integers.∙All assignments to integer register[x]are conditional on x not being zero.Register0has a hardwired{\em zero}value and cannot be modified.∙Double register[x]is a64bit quantity that represents the same storage as fp register[x]and fp register[x+1].Only even values of x are allowed(double register addresses are aligned).Single precision floating point is32bits and double precision floating point is64bits.The exact floating point format used is that of the machine on which the simulator is running.∙The specifications for branches and jumps assume that the PC has not yet been incremented(for the next instruction)when the specified actions are performed.Note that this does not represent the actual behavior in any reasonable pipelined implementation;it is assumed merely to simplify the description.∙Memory will be stored in big endian format and all effective addresses must be aligned with the data type.InstructionsaddEx:add r1,r2,r3R[regc]<--R[rega]+R[regb]All are signed integers.adddEx:addd f4,f4,f6D[dregc]<--D[drega]+D[dregb]All are double precision floating point numbers.addfEx:addf f3,f4,f5F[fregc]<--F[frega]+F[fregb]All are single precision floating point numbers.addiEx:addi r5,r2,#5R[regb]<--R[rega]+imm16All are signed integers.adduEx:addu r2,r3,r4R[regc]<--R[rega]+R[regb]All are unsigned integers.adduiEx:addui r2,r3,#28R[regb]<--R[rega]+uimm16All are unsigned integers.andEx:and r2,r3,r4R[regc]<--R[rega]&R[regb]All are unsigned integers.Logical`and'is performed on a bitwise basis.andiEx:andi r3,r4,#5R[regb]<--R[rega]&uimm16All are unsigned integers.Logical`and'is performed on a bitwise basis.beqzEx:beqz r1,labelif(R[rega]==0)PC<--PC+imm16+4bfpfEx:bfpf labelif(fps==0)PC<--PC+imm16+4fps is the floating point status bit.bfptEx:bfpt labelif(fps==1)PC<--PC+imm16+4fps is the floating point status bit.bnezEx:bnez r1,labelif(R[rega]!=0)PC<--PC+imm16+4cvtd2fEx:cvtd2f f1,f4F[fregc]<--(float)D[drega]Converts double precision floating point value to single precision floating point value.cvtd2iEx:cvtd2i f1,f0F[fregc]<--(int)D[drega]Converts double precision floating point value to integer.cvtf2dEx:cvtf2d f4,f9D[dregc]<--(double)F[frega]Converts single precision float to double.cvtf2iEx:cvtf2i f3,f4F[fregc]<--(int)F[frega]Converts single precision float to integer.cvti2dEx:cvti2d f2,f9D[dregc]<--(double)F[frega]Converts a signed integer to double precision float.cvti2fEx:cvti2f f2,f5F[fregc]<--(float)F[frega]Converts a signed integer to single precision float.divEx:div f2,f2,f3F[fregc]<--F[frega]/F[fregb]All are signed integers.divdEx:divd f4,f4,f6D[dregc]<--D[drega]/D[dregb]All are double precision floats.divfEx:divf f2,f3,f6F[fregc]<--F[frega]/F[fregb]All are single precision floats.divuEx:divu f2,f3,f4F[fregc]<--F[frega]/F[fregb]All are unsigned integers.eqdEx:eqd f2,f4if(D[drega]==D[dregb])fps=1else fps=0Both are double precision floats.eqfEx:eqf f3,f5if(F[frega]==F[fregb])fps=1else fps=0Both are single precision floats.Ex:ged f8,f6if(D[drega]>=D[dregb])fps=1else fps=0Both are double precision floats.gefEx:gef f3,f6if(F[frega]>=F[fregb])fps=1else fps=0Both are single precision floats.gtdEx:gtd f8,f6if(D[drega]>D[dregb])fps=1else fps=0Both are double precision floats.gtfEx:gtf f3,f6if(F[frega]>F[fregb])fps=1else fps=0Both are single precision floats.jEx:j labelPC<--PC+imm26+4Unconditionally jumps relative to the PC of the next instruction.imm26 is a26-bit signed integer.jalEx:jal labelR31<--PC+8;PC<--PC+imm26+4Saves a return address in register31and jumps relative to the PC of the next instruction.imm26is a26-bit signed integer.jalrEx:jalr r2R31<--PC+8;PC<--R[rega]Saves a return address in register31and does an absolute jump to the target address contained in R[rega].jrEx:jr r3PC<--R[rega]R[rega]is treated as an unsigned integer.Does an absolute jump to the target address contained in R[rega].Ex:lb r1,40-4(r2)R[regb]<--(sign extended)M[imm16+R[rega]]One byte of data is read from the effective address computed by adding signed integer imm16and signed integer R[rega].The byte from memory is then sign extended to32-bits and stored in register R[regb].lbuEx:lbu r2,label-786+4(r3)R[regb]<--0^24##M[imm16+R[rega]]One byte of data is read from the effective address computed by adding signed integer imm16and signed integer R[rega].The byte from memory is then zero extended to32bits and stored in register R[regb].ldEx:ld f2,240(r1)D[dregb]<--64M[imm16+R[rega]]Two words of data are read from the effective address computed by adding signed integer imm16and unsigned integer R[rega]and stored in double register D[dregb].This is equivalent to two lf instructions:F[fregb]<--M[imm16+R[rega]]F[freg(b+1)]<--M[imm16+R[rega]+4]where F[freg(b+1)]is the next fp register after F[fregb]in sequence,and all values are simply copied and not converted.)ledEx:led f8,f6if(D[drega]<=D[dregb])fps=1else fps=0Both are double precision floats.lefEx:lef f3,f6if(F[frega]<=F[fregb])fps=1else fps=0Both are single precision floats.lfEx:lf f6,76(r4)F[fregb]<--M[imm16+R[rega]]One word of data is read from the effective address computed by adding signed integer imm16and signed integer R[rega]and stored in fp register F[fregb].lhEx:lh r1,32(r3)R[regb]<--(sign extended)M[imm16+R[rega]]Two bytes of data are read from the effective address computed by adding signed integer imm16and signed integer R[rega].The address must be half-word aligned.The half-word from memory is then sign extended to32bits and stored in register R[regb].lhiEx:lhi r3,#-40R[regb]<--imm16##0^16Loads the16bit immediate value imm16into the most significant half of an integer register and clears the least significant half.lhuEx:lhu r2,-40+4(r3)R[regb]<--0^16##M[imm16+R[rega]]Two bytes of data are read from the effective address computed by adding signed integer imm16and signed integer R[rega].The address must be half-word aligned.The half-word from memory is then zero extended to32bits and stored in register R[regb].ltdEx:ltd f8,f6if(D[drega]<D[dregb])fps=1else fps=0Both are double precision floats.ltfEx:ltf f3,f6if(F[frega]<F[fregb])fps=1else fps=0Both are single precision floats.lwEx:lw r19,label+63(r8)R[regb]<--M[imm16+R[rega]]One word is read from the effective address computed by adding signed integer imm16and unsigned integer R[rega]and is stored in R[regb].movdEx:movd f2,f4D[dregc]<--D[drega]Copies two words from double register D[drega]to double register D[dregc].movfEx:movf f1,f2F[fregc]<--F[frega]Copies one word from fp register F[frega]to fp register F[fregc].movfp2iEx:movfp2i r3,f0R[regc]<--F[frega]Copies one word from fp register F[frega]to integer registerR[regc].movi2fpEx:movi2fp f0,r3F[fregc]<--R[rega]Copies one word from integer register R[rega]to fp registerF[fregc].movi2sEx:movi2s r1UnspecifiedCopies one word from integer register R[rega]to a special register.movs2iEx:movs2i r2UnspecifiedCopies one word from a special register to integer register R[rega].multEx:mult f2,f3,f4F[fregc]<--F[frega]*F[fregb]All are signed integers.multdEx:multd f2,f4,f6D[dregc]<--D[drega]*D[dregb]All are double precision floats.multfEx:multf f3,f4,f5F[fregc]<--F[frega]*F[fregb]All are single precision floats.multuEx:multu f2,f3,f4F[fregc]<--F[frega]*F[fregb]All are unsigned integers.Ex:ned f8,f6if(D[drega]!=D[dregb])fps=1else fps=0Both are double precision floats.nefEx:nef f3,f6if(F[frega]!=F[fregb])fps=1else fps=0Both are single precision floats.nopEx:nopIdles one cycle.orEx:or r2,r3,r4R[regc]<--R[rega]|R[regb]All are unsigned integers.Logical`or'is performed on a bitwise basis.oriEx:ori r3,r4,#5R[regb]<--R[rega]|uimm16All are unsigned integers.Logical`or'is performed on a bitwise basis.rfeEx:rfeUnspecifiedReturn from exception.sbEx:sb label-41(r3),r2M[imm16+R[rega]]<--8R[regb]_24..31One byte of data from the least significant byte of register R[regb] is written to the effective address computed by adding signed integer imm16and signed integer R[rega].sdEx:sd200(r4),f6M[imm16+R[rega]]<--64D[dregb]Two words from double register D[dregb]are written to the effective address computed by adding signed integer imm16and signed integer R[rega].Ex:seq r1,r2,r3if(R[rega]==R[regb])R[regc]<--1else R[regc]<--0All are signed integers.seqiEx:seqi r14,r3,#3if(R[rega]==imm16)R[regb]<--1else R[regb]<--0All are signed integers.sfEx:sf121(r3),f1M[imm16+R[rega]]<--F[fregb]One word from fp register F[fregb]is written to the effective address computed by adding signed integer imm16and signed integer R[rega].sgeEx:sge r1,r3,r4if(R[rega]>=R[regb])R[regc]<--1else R[regc]<--0All are signed integers.sgeiEx:sgei r2,r1,#6if(R[rega]>=imm16)R[regb]<--1else R[regb]<--0All are signed integers.sgeuEx:sgeu r1,r3,r4if(R[rega]>=R[regb])R[regc]<--1else R[regc]<--0All are unsigned integers.sgeuiEx:sgeui r2,r1,#6if(R[rega]>=uimm16)R[regb]<--1else R[regb]<--0All are unsigned integers.sgtEx:sgt r4,r5,r6if(R[rega]>R[regb])R[regc]<--1else R[regc]<--0All are signed integers.sgtiEx:sgti r1,r2,#-3000if(R[rega]>imm16)R[regb]<--1else R[regb]<--0All are signed integers.sgtuEx:sgtu r4,r5,r6if(R[rega]>R[regb])R[regc]<--1else R[regc]<--0All are unsigned integers.sgtuiEx:sgtui r1,r2,#3000if(R[rega]>uimm16)R[regb]<--1else R[regb]<--0All are unsigned integers.shEx:sh421(r3),r5M[imm16+R[rega]]<--16R[regb]_16..31Two bytes of data from the least significant half of register R[regb] are written to the effective address computed by adding signed integer imm16and unsigned integer R[rega].The effective address must be halfword aligned.sleEx:sle r1,r2,r3if(R[rega]<=R[regb])R[regc]<--1else R[regc]<--0All are signed integers.sleiEx:slei r8,r5,#345if(R[rega]<=imm16)R[regb]<--1else R[regb]<--0All are signed integers.sleuEx:sleu r1,r2,r3if(R[rega]<=R[regb])R[regc]<--1else R[regc]<--0All are unsigned integers.sleuiEx:sleui r8,r5,#345if(R[rega]<=uimm16)R[regb]<--1else R[regb]<--0All are unsigned integers.sllEx:sll r6,r7,r11R[regc]<--R[rega]<<R[regb]_27..31All are unsigned integers.R[rega]is logically shifted left by thelow five bits of R[regb].Zeros are shifted into theleast-significant bit.slliEx:slli r1,r2,#3R[regb]<--R[rega]<<uimm16_27..31All are unsigned integers.R[rega]is logically shifted left by the low five bits of uimm16.Zeros are shifted into theleast-significant bit.(Actually only the bottom five bits ofR[regb]are used.)slt Ex:slt r3,r4,r5if(R[rega]<R[regb])R[regc]<--1else R[regc]<--0All are signed integers.sltiEx:slti r1,r2,#22if(R[rega]<imm16)R[regb]<--1else R[regb]<--0All are signed integers.sltuEx:sltu r3,r4,r5if(R[rega]<R[regb])R[regc]<--1else R[regc]<--0All are unsigned integers.sltuiEx:sltui r1,r2,#22if(R[rega]<uimm16)R[regb]<--1else R[regb]<--0All are unsigned integers.sneEx:sne r1,r2,r3if(R[rega]!=R[regb])R[regc]<--1else R[regc]<--0All are signed integers.sneiEx:snei r4,r5,#89if(R[rega]!=imm16)R[regb]<--1else R[regb]<--0All are signed integers.sraEx:sra r1,r2,r3R[regc]<--(R[rega]_0)^R[regb]##(R[rega]>>R[regb])_R[regb]..31 R[rega]and R[regc]are signed integers.R[regb]is an unsigned integer.R[rega]is arithmetically shifted right by R[regb].Thesign bit is shifted into the most-significant bit.(Actually uses only the five low order bits of R[regb].)sraiEx:srai r2,r3,#5R[regb]<--(R[rega]_31)^uimm16##(R[rega]>>uimm16)_uimm16..31 R[rega]and R[regc]are signed integers.uimm16is an unsigned integer.R[rega]is arithmetically shifted right by R[regb].The sign bit is shifted into the most-significant bit.(Actually uses only the five low order bits of uimm16.)srlEx:srl r15,r2,r3R[regc]<--R[rega]>>R[regb]_27..31All are unsigned integers.R[rega]is arithmetically shifted right by R[regb].Zeros are shifted into the most significant bit.srliEx:srli r1,r2,#5R[regb]<--R[rega]>>uimm16_27..31All are unsigned integers.R[rega]is arithmetically shifted right by uimm16.Zeros are shifted into the most significant bit.subEx:sub r3,r2,r1Ex:R[regc]<--R[rega]-R[regb]All are signed integers.subdEx:subd f2,f4,f6D[dregc]<--D[drega]-D[dregb]All are double precision floats.subfEx:subf f3,f4,f6F[fregc]<--F[frega]-F[fregb]All are single precision floats.subiEx:subi r15,r16,#964R[regb]<--R[rega]-imm16All are signed integers.subuEx:subu r3,r2,r1R[regc]<--R[rega]-R[regb]All are unsigned integers.subuiEx:subui r1,r2,#53R[regb]<--R[rega]-uimm16All are unsigned integers.swEx:sw21(r13),r6M[imm16+R[rega]]<--R[regb]One word from integer register R[regb]is written to the effective address computed by adding signed integer imm16and unsigned integer R[rega].trapEx:trap#3Execute trap with number in immediate fieldSaves state and jumps to an operating system procedure located at an address in the interrupt vector table.In our systems,this is simulated by calling the procedure corresponding to the trap number.xorEx:xor r2,r3,r4R[regc]<--F[rega]XOR R[regb]All are unsigned integers.Logical'xor'is performed on a bitwise basis.xoriEx:xori r3,r4,#5R[regb]<--R[rega]XOR uimm16All are unsigned integers.Logical'xor'is performed on a bitwise basis.Instruction EncodingThe general instruction layout for DLX is shown on page99of H&P(2nd Ed.).This specifies the encodings(the6-bit opcode and the11-bit function code)assumed in the BYU ECEn Department's tool set.(This is not intended to be compatible with DLX tools from any other source.Encodings were chosen to keep things simple.)The following is a portion of an include file used by the assembler and simulator.Note that it defines a struct for each instruction,specifying(1)the mnemonic used by the assembler and disassemblers,(2)the6bit opcode value,(3)the value used in the func bits./*---------------------dlxdef.h-------------------------*/ struct mapper{char*name;int op;int func;int optype;};struct mapper mainops[]={{"special",0x00,0x00,UNIMP},{"fparith",0x01,0x00,UNIMP},{"addi",0x02,0x00,REG2IMM},{"addui",0x03,0x00,REG2IMM},{"andi",0x04,0x00,REG2IMM},{"beqz",0x05,0x00,REGLAB},{"bfpf",0x06,0x00,LEXP16},{"bfpt",0x07,0x00,LEXP16},{"bnez",0x08,0x00,REGLAB},{"j",0x09,0x00,LEXP26},{"jal",0x0a,0x00,LEXP26},{"jalr",0x0b,0x00,IREG1},{"jr",0x0c,0x00,IREG1},{"lb",0x0d,0x00,LOADI},{"lbu",0x0e,0x00,LOADI},{"ld",0x0f,0x00,LOADD},{"lf",0x10,0x00,LOADF},{"lh",0x11,0x00,LOADI},{"lhi",0x12,0x00,REG1IMM},{"lhu",0x13,0x00,LOADI},{"lw",0x14,0x00,LOADI},{"ori",0x15,0x00,REG2IMM},{"rfe",0x16,0x00,UNIMP},{"sb",0x17,0x00,STRI},{"sd",0x18,0x00,STRD},{"seqi",0x19,0x00,REG2IMM},{"sf",0x1a,0x00,STRF},{"sgei",0x1b,0x00,REG2IMM},{"sgeui",0x1c,0x00,REG2IMM},/*added instruction*/ {"sgti",0x1d,0x00,REG2IMM},{"sgtui",0x1e,0x00,REG2IMM},/*added instruction*/ {"sh",0x1f,0x00,STRI},{"slei",0x20,0x00,REG2IMM},{"sleui",0x21,0x00,REG2IMM},/*added instruction*/{"slli",0x22,0x00,REG2IMM},{"slti",0x23,0x00,REG2IMM},{"sltui",0x24,0x00,REG2IMM},/*added instruction*/ {"snei",0x25,0x00,REG2IMM},{"srai",0x26,0x00,REG2IMM},{"srli",0x27,0x00,REG2IMM},{"subi",0x28,0x00,REG2IMM},{"subui",0x29,0x00,REG2IMM},{"sw",0x2a,0x00,STRI},{"trap",0x2b,0x00,IMM1},{"xori",0x2c,0x00,REG2IMM},{"la",0x30,0x00,PSEUDO}};struct mapper spec[]={{"nop",0x00,0x00,NONEOP},{"add",0x00,0x01,REG3IMM},{"addu",0x00,0x02,REG3IMM},{"and",0x00,0x03,REG3IMM},{"movd",0x00,0x04,DREG2a},{"movf",0x00,0x05,FREG2a},{"movfp2i",0x00,0x06,IF2},{"movi2fp",0x00,0x07,FI2},{"movi2s",0x00,0x08,UNIMP},{"movs2i",0x00,0x09,UNIMP},{"or",0x00,0x0a,REG3IMM},{"seq",0x00,0x0b,REG3IMM},{"sge",0x00,0x0c,REG3IMM},{"sgeu",0x00,0x0d,REG3IMM},/*added instruction*/ {"sgt",0x00,0x0e,REG3IMM},{"sgtu",0x00,0x0f,REG3IMM},/*added instruction*/ {"sle",0x00,0x10,REG3IMM},{"sleu",0x00,0x11,REG3IMM},/*added instruction*/ {"sll",0x00,0x12,REG3IMM},{"slt",0x00,0x13,REG3IMM},{"sltu",0x00,0x14,REG3IMM},/*added instruction*/ {"sne",0x00,0x15,REG3IMM},{"sra",0x00,0x16,REG3IMM},{"srl",0x00,0x17,REG3IMM},{"sub",0x00,0x18,REG3IMM},{"subu",0x00,0x19,REG3IMM},{"xor",0x00,0x1a,REG3IMM}};struct mapper fpops[]={{"addd",0x01,0x00,DREG3},{"addf",0x01,0x01,FREG3},{"cvtd2f",0x01,0x02,FD2},{"cvtd2i",0x01,0x03,FD2},{"cvtf2d",0x01,0x04,DF2},{"cvtf2i",0x01,0x05,FREG2a},{"cvti2d",0x01,0x06,DF2},{"cvti2f",0x01,0x07,FREG2a},{"div",0x01,0x08,FREG3},{"divd",0x01,0x09,DREG3},{"divf",0x01,0x0a,FREG3},{"divu",0x01,0x0b,FREG3},{"eqd",0x01,0x0c,DREG2b},{"eqf",0x01,0x0d,FREG2b},{"ged",0x01,0x0e,DREG2b},{"gef",0x01,0x0f,FREG2b},{"gtd",0x01,0x10,DREG2b},{"gtf",0x01,0x11,FREG2b},{"led",0x01,0x12,DREG2b},{"lef",0x01,0x13,FREG2b},{"ltd",0x01,0x14,DREG2b},{"ltf",0x01,0x15,FREG2b},{"mult",0x01,0x16,FREG3},{"multd",0x01,0x17,DREG3},{"multf",0x01,0x18,FREG3},{"multu",0x01,0x19,FREG3},{"ned",0x01,0x1a,DREG2b},{"nef",0x01,0x1b,FREG2b},{"subd",0x01,0x1c,DREG3},{"subf",0x01,0x1d,FREG3}};Last updated on26February1997。

关于二次设计中电缆编号以及端子号的相关说明为便于二次施工设计的统一，现对电缆编号以及端子号作如下说明：一、间隔号：1．主变：1B（#1主变）、2B（#2主变）；2．电压互感器：EYH（220kV电压互感器）、YYH（110kV电压互感器）、UYH（35kV电压互感器）、SYH（10kV电压互感器）；3．线路：EX（220kV线路）、YX（110kV线路）、UX（35kV线路）、SX（10kV线路）；4．电容器：UC（35kV电容器）、SC（10kV电容器）；5．电抗器：UK（35kV电抗器）、SK（10kV电抗器）；6．接地变及消弧线圈：UQ（35kV接地变）、SQ（10kV接地变）；7．所用变：1SB（#1所变）、2SB（#2所变）；8．母联：EML（220kV母联）YML（110kV母联）、UML（35kV母联）、SML（10kV母联）；9．母分：EFD（220kV母分）、YFD（110kV母分）、UFD（35kV母分）、SFD（10kV母分）；10．母差：EMB（220kV母差）、YMB（110kV母差）、UMB（35kV母差）；11．其他：ZL（直流）；SD（交流）；GY（公用）；LB（录波）；BZT（备自投）；JR（加热）；12．稳控：WK；二、电缆号：1．101~129：继保室至室内和室外配电场所，开头为电流电压电缆编号；2．131~149：继保室之间的电缆编号；3．151~159：室内配电场所之间的电缆编号；4．160~169：电容器（接地变）成套设备电缆编号，160为电流或者电压电缆编号；6．170~179：主变本体电缆编号，170为电流电缆编号（零序和间隙用A、B加以区分）；7．180A、B、C：户外电流互感器电缆编号；8．181~189：户外配电场所电缆编号（断路器）；9．190A、B、C：户外电压互感器电缆编号；10．191~199：户外配电场所电缆编号（隔离开关）；末位1表示1G，2表示2G、3表示3G、4表示4G、每个机构中的电缆编号加A、B、C、D、E用以区分；注：当用于三圈变时，电缆首位1表示高压侧，2表示中压侧，3表示低压侧。