TPSMP6.8中文资料

Application Specification860635357Jan 2018 Rev B8-Position Unshielded Slim-Line Modular Plug (MP-6AU)To obtain information on CommScope ® products,visit our website at /SupportCenter©2017 CommScope, Inc. All Rights ReservedThis product is covered by one or more U.S.patents or their foreign equivalents. For patents, see /ProductPatent/ProductPatent.aspxAll numerical values are in metric units [with U.S. customary units in brackets]. Dimensions are in millimeters [and inches]. Figures and illustrations are for identification only and are not drawn to scale.1. INTRODUCTIONThis specification covers the requirements for application of Category 5e/6/6A Unshielded Slim-Line Modular RJ45 Plug Connectors (MP-6AU). These requirements are applicable to hand or automaticmachine terminating tools. Cables approved for use with these connectors are round, twisted-pair cables, unshielded, 24-26 AWG stranded conductors and 23-26 AWG solid conductors. The insulated conductor outside diameter must be between 0.69mm and 1.09mm. The cable jacket outside diameter must be between 4.80mm and 7.90mm.When corresponding with CommScope Connectivity Personnel, use the terminology provided in thisspecification to facilitate your inquiries for information. Basic terms and features of components are provided in Figure 1.Figure 1: Basic terms and featuresMP-6AUUnshielded Slim-Line Modular Plug RJ45 Connector AssemblyOptionalSold Separately2. REFERENCE MATERIAL2.1. Revision SummaryThis paragraph is reserved for a revision summary of changes and additions made to this specification. The following changes were made for this revision:Removed references to discontinued tooling.2.2. Customer AssistanceReference Part Numbers 6-2843007 (Catalog No. MP-6AU-PLUG-A) and 6-2843008 (Catalog No. MP-6AU-PLUG-B) are representative numbers of 8-position Category 5e/6/6A Unshielded Slim-Line Modular RJ45 Plug Connectors. Use of these numbers will identify the product line and expedite your inquires through a service network established to help you obtain product and tooling information. Such information can be obtained through a local CommScope Connectivity Representative (Field Sales Engineer, Field Applications Engineer, etc.).2.3. DrawingsCustomer Drawings for specific products are available from the service network. The information contained in the Customer Drawings takes priority if there is a conflict with this specification or with any other technical documentation supplied by CommScope Connectivity.2.4. SpecificationsProduct Specification 108-131013 provides product performance requirements. Product Qualification Test Report 501-131013 provides test results.2.5. Instructional MaterialThe following list includes available instruction sheets (408-series) and customer manuals (409-series) that provide operation, maintenance, and repair of tooling. In addition, follow the instructions and procedures outlined in Paragraph 3.2 of this specification for product assembly procedures.Document Number Document Title408-4389 Crimp Height Gage 904170-1408-9767 Modular Plug Hand Tool Assembly X-231652-X.3. REQUIREMENTS3.1. StorageA. Ultraviolet LightProlonged exposure to ultraviolet light may deteriorate the chemical composition used in the connector components.B. Shelf LifeAll components products should remain in the shipping containers until ready for use to preventdamage. These products should be used on a first in, first out basis to avoid storage contamination.C. Chemical ExposureDo not store connector components near any chemicals listed below, as they may cause stresscorrosion cracking in the product.SulfurCompoundsCitratesPhosphatesAmmonia CitratesAlkaliesNitritesTartratesSulfurAminesNitritesCarbonatesWhere the above environmental conditions exist, phosphor-bronze contacts are recommended if available.3.2. CableA. Cable Specifications1. Cable Type: Round jacketed, Unshielded, four twisted pairs.2. Conductor Type:a. Stranded Conductor: 24-26 AWGb. Solid Conductor: 23-26 AWG3. Conductor Insulation Outside Diameter: 0.69mm -1.09mm [.027-.043] for any one conductor.See section 7 Ordering Guide.4. Cable Jacket Insulation Diameter: 4.80mm – 7.40mm [.189 - .291]. See section 7 OrderingGuide.5. Unshielded Type: With or without cable central filler3.3. Terminated Connector Requirements and ProcessCable Pair Arrangement: The arrangement of color-coded pairs within the cable jacket applicable to TIA/EIAT568B wiring and the termination procedures described in this specification is shown in Figure 3. Cable endA applies to one end of the cable and cable endB to the opposite end. For TIA/EIA T568A wiring ortermination of cables with pair arrangements other than TIA/EIA T568B, contact the responsibleCommScope Connectivity Engineering Department.3.4. Terminated Connector InstructionThis section provides instruction for assembly and terminated of twisted pairs cable to MP-6AU modularplug, see the following process steps below. Note that step 6 on which pairs to have no-twist and add-twistwithin plug boot manager section is only reference. Note that depending on the electrical characteristics ofthe customer twisted pair cable the no-twist and add-twist of what pair method maybe different then shownin step 6. Additionally, the position of the pairs in the pair manger described in steps 3 and 4 may alsoneed to be altered to achieve the ultimate performance. It is the responsibility of the user to determine the optimum twist and pair layout depending upon the cable being terminated.1.25 INCHCut away filler strip from end of cable jacket. Cut as close as you can to the edge of the cable jacket Strip cable jacket back to dimension 1.25 inch. Insert cable jacket and wire pairs into boot/ pair manager with Blue wire pair on top.On the reverse latch side; Orange , Green , and wire pairs are positioned as shown.On reverse latch side wire pairs; Orange , Blue , are positioned as shown. 03a04aOpposite end of cordage, position Green wire pair on top. Blue Pair on TopFront ViewPair on TopFront View011.25 inchesO WW 0506Slide wire pairs into load bar until wire insulationreaches ending point. Make sure wires are allthe way into load bar housing. 09 Push the plug housing over the load bar through the boot pair manger all the way until it latches to the boot. Terminate plug contacts to wire pairs with termination tool to seat the contacts.W Push cable jacket to dimension 0.25 +/- 0.02 inch. Cut wires to dimension 0.20 +/- 0.01 inch.10Vertical Walls3.4. Terminated Connector RequirementsFigure 2 shows a cutaway side view of a typical terminated plug and the required location of the plug contact. A visual check through the plastic plug housing and load bar should reveal whether the conductors are within the acceptable location.For optimum transmission performance (acceptable location), it is preferred that all conductors be fully inserted into the plug load bar housing with the ends of the conductors bottomed against the inside front surface of the plug load bar housing. For reliable electrical termination, the conductors must at least be inserted past the plug contact within the load bar housing.Proper crimp height can be inspected using an indicator with needle-point probes or equivalent. The crimp height shall be measured at the front of the contact as shown in Figure 16.Figure 23.5. Repair/ReplacementDamaged components must not be used. If a damaged component is evident, it must be replaced with a new one.4. QUALIFICATIONSThe Modular Plug Connectors are not required to be Listed or Recognized by Underwriters Laboratories Inc. (UL), or Certified to the Canadian Standards Association (CSA).5. TOOLINGThis section provides information on the hand tool to be used with these plugs.HAND TOOL (DOCUMENT) Hand Terminator HAND TOOL DIE SET ONLY X-231652-X (408-9767)1-853400-5Figure 3: ToolingModular Plug Die Set:MP-6AU Die Only (PINK DOT) 1-853400-5Modular Plug Hand Tool:Hand Tool with MP-6AU Die (PINK DOT) 3-231652-7Hand Tool with No Die 2-231652-05.1 TOOLING MODULE MODIFICATION, IF EXISTING PART NUMBERS BELOWThis section provides instruction for modification of existing dual terminating module with the following Part Numbers: [NOTE: Terminating equipment has been discontinued]Module 1-856196-1 comes with two Primary Stuffer strain relief blocks per below in Figure 19. Remove the two Primary Stuffer strain relief blocks from module and if require replace the two #8-32UNC socket cap screws with shorter length screws.Module 856196-2 comes with two Primary Stuffer strain relief blocks and two Secondary Stuffer strain relief blocks per below in Figure 4. Remove the two Primary Stuffer strain relief blocks and two Secondary Stuffer strain relief blocks from module and if require replace the two #8-32UNC socket cap screws with shorter length screws.Figure 4: Tooling6. VISUAL AIDFigure 5 shows typical applications of Modular Plug Connectors. These illustrations should be used by production personnel to ensure a correctly applied product. Applications which DO NOT appear correct should be inspected using the information in the preceding pages of this specification and in the instructional material shipped with the product or tooling.Figure 5: Visual Aid7. Ordering Information:MP-6AU Plug Housing with wire manager is ordered as a kit depending upon conductor diameter. MP-6AU-Boot is ordered separately based on cable diameter. See Figure 6, Both the Plug Housing/Wire Manager Kit and the Integrated Boots are sold in bags of 100.Figure 6: Visual AidCatalog NumberDescriptionConductor Insulation Diameter6-2843007-1 MP-6AU-Plug-A-1Plug Housing with 0.99 mmWire-Manager 1.09 mm-0.89 mm [0.043 in – 0.035 in] 6-2843008-1 MP-6AU-Plug-B-1Plug Housing with 0.79 mmWire-Manager0.89 mm - 0.69 mm [0.035 in – 0.027 in]Catalog NumberDescriptionCable Diameter2843018-3 MP-6AU-Boot-71-1 Integrated Boot and Manager, 7.1 mm 7.40 mm - 6.80 mm [0.291 in – 0.268 in] 2843020-3 MP-6AU-Boot-59-1 Integrated Boot and Manager, 5.9 mm 6.20 mm -5.60 mm [0.244 in – 0.220 in] 2843021-3 MP-6AU-Boot-54-1 Integrated Boot and Manager, 5.4 mm 5.70 mm - 5.10 mm [0.224 in – 0.201] 2843023-3MP-6AU-Boot-51-1Integrated Boot and Manager, 5.1 mm5.40 mm - 4.80 mm [0.212 in – 0.189 in]Figure 7:860635357Rev B 11 of 118. Plug Accessories (Sold Separately)8.1 Color Coding ClipFigure 8 shows typical applications of Modular Plug Connector with Color Coding Clip. The color coding clip simply snaps onto the plug boot in the field by the customer and is exchangeable, latch around the plug boot. The color clips is offered in bags of 50 and come in nine (9) different colors. After the color coding clip is latch onto the plug boot, make sure color clip latches are flush to plug boot surface on each side.Figure 8: Modular Plug MP-6AU and MP-6AU-Boot with Color Coding ClipMID Color ClipsBoot Compatibility2843022-1 MP-ColorClip-Almond-50 MP-6AU-Boot MP-BOOT-S-SL MP-5EU-Boot2843022-2 MP-ColorClip-Black-50 2843022-3 MP-ColorClip-White-50 2843022-4 MP-ColorClip-Gray-50 2843022-5 MP-ColorClip-Orange-50 2843022-6 MP-ColorClip-Blue-50 2843022-7 MP-ColorClip-Red-50 2843022-8 MP-ColorClip-Yellow-50 2843022-9MP-ColorClip-Green-50Figure 9:。

Installation, Operationand Maintenance ManualVisit us at 21. ReceivingUpon the receipt of the shipment, check the contents against the packing slip and for damage. Immediately inform EnerSys ® of any missing or damaged items. EnerSys is not responsible for shipment damage or shortages that the receiver does not report to the carrier.2. Storage2.1. Storage Conditions and TimeIf a battery cannot be installed immediately it should be stored in a clean, cool and dry area. During storage products lose capacity through self-discharge. High temperatures increase the rate of self-discharge and reduce the storage life.2.1.1. The maximum storage time before a refresh charge is required and therecommended OCV audit intervals are:+15 / +59256+20 / +68184+25 / +77124+30 / +9693+35 / +9562+40 / +104422.1.2. Products must be given a refresh charge when the OCV approaches the equivalent of 2.10 Volts per cell or when the maximum storage time is reached, whichever occurs first.2.2. Refresh ChargeCharge at a constant voltage equivalent to 2.29 - 2.40Vpc with a minimum 0.1C 10 Amps available for a period of 24 hours.2.3. Commissioning ChargePrior to commencement of operation, the battery must be given a commissioning charge. This shall consist of a 24 hour charge at a voltage equivalent to 2.40Vpc at 20°C with no load connected.3. Battery LocationThe battery compartment/room must have adequate ventilation to limit hydrogen accumulation. Batteries must be installed in accordance with the IEC 62485-2 standard and any other local/national laws and regulations.4. InstallationPowerSafe SBS XC+ batteries can be mounted in any orientation except inverted.However, in cyclic/hybrid applications, EnerSys recommend to install 2 Volt DIN-size cells in horizontal orientation. In such configuration the instructions below must be complied with.• Do not use terminal posts to lift or handle cells.• Do not install the cells in such a way that the box-lid seal is resting on a runner.•Always ensure that the arrow on the lid of each unit is pointing in vertical orientation.torque value is indicated on the product label.Place the insulating covers in position immediately after tightening the fasteners.5. OperationPowerSafe SBS XC+ products are specifically designed for controlled hybrid partial state of charge operation (PSoC).The battery will give the best performance and service life when working at a temperature of 20°C. The maximum operating temperature range is -40°C to +50°C.5.1. Fast Charge OperationThe inherently high charge acceptance of the TPPL technology used in thePowerSafe SBS XC+ is suited for applications which require a fast time to repeat duty.The rectifier output voltage should be set at 2.40Vpc at 20°C. Temperature compensation for charge voltage should be applied as follows: • +3mV per cell per °C below 20°C •-3mV per cell per °C above 20°C Where rectifier voltage cannot be adjusted to values >2.40Vpc to compensate for temperatures below 20°C, the time for recharge will be increased.HandlingPowerSafe ® SBS XC+ batteries are supplied in a charged condition and are capable of extremely high short circuit currents. Take care to avoid short-circuiting terminals of opposite polarity.ImportantPlease read this manual immediately on receipt of the battery before unpacking and installing. Failure to comply with these instructions will render any warranties null and void.Care for your safetyKeep flames awayIn case of accidental overcharge a flammable gas can leak off the safety vent.Discharge any possible static electricity from clothes by touching an earth connected part.ToolsUse tools with insulated handles.Do not place or drop metal objects on the battery.Remove rings, wristwatch and articles of clothing with metal parts that may come into contact with the battery terminals.No smoking, no naked flames, no sparksShield eyesReadinstructionsDangerRecycle scrap batteries. Contains leadClean all acid splash in eyes or on skin with plenty of clean water. Then seek medical help. Acid on clothing is to be washed with waterWarning: Risk of fire, explosion, or burns. Do not disassemble, heat above 60°C (140°F), or incinerate. Metallic partsunder voltage are present on the battery, avoid short circuit. Do not place tools or items on top of the battery.California Proposition 65 Warning - Battery posts, terminals, and related accessories contain lead and lead compounds, chemicals known to the State of California to cause cancer and reproductive harm. Wash hands after handling.5.2. Charging CurrentDue to their very low internal resistance PowerSafe SBS XC+ batteries will acceptunlimited current during recharge. The rectifier current can be limited to the loadplus 0.2C10 Amps (minimum).5.3. DischargingBatteries must not be left in a discharged condition after supplying the load butmust immediately return to recharge mode.Failure to observe these conditions may result in greatly reduced service life.5.4. Accidental Deep DischargeIn order to protect the battery it is advisable to have system monitoring and lowvoltage cut-out. A low voltage disconnect of 1.93Vpc (80% DoD) should beapplied to protect the battery from abusive over discharge.Abusive deep discharge can result in premature deteriation of the battery and anoticeable reduction in the life expectancy.5.5. Operation in Hybrid Controlled Partial State of ChargeFor advice about this topic, please refer to the PowerSafe® SBS XC+ operationguide for hybrid applications.6. Data RecordingIt is recommended that as a minimum, the following information be recorded bymeans of regular data logging. The user must make this available to EnerSys inorder to validate any warranty claim.1) Records of the commission charge.2) The number of cycles performed and the depth of discharge of each cycle.3) The duration of each discharge and charge cycle, and the Ah in and out (Whin and out).4) Full details of the recharge voltage/current profile for the last 50 cycles.5) A full history of the ambient and battery surface temperatures, recorded atregular intervals throughout battery operation and life.6) The time and date of each “event” (an “event” is defined as the start/stop ofthe battery discharge, the start/stop of the battery recharge, the start stop ofany generator input power or other input power source, etc).Contact EnerSys if you have any questions regarding maintenance.7. DisposalPowerSafe SBS XC+ batteries are recyclable. Scrap batteries must be packagedand transported in accordance with prevailing transportation rules and regulations.Scrap batteries must be disposed of in compliance with local and national laws bya licensed or certified lead acid battery recycler.39 1 0 2 y l u J -2 0 0 -M O I -。

Data SheetFujitsu TP8 Model Axxx All-In-One PoS The next generation in PoS Technology■Future-proof performance: Intel® 6th and 7th Generation Processors and the fastest PCIENVME SSD storage■The most modular all-in-one PoS terminal, with field swappable LCD (15”, 18.5”) andPC module■Super sleek AIO suits any counter on adjustable stand or with built-in VESA pole-mount support■Highly reliable and serviceable: External access to memory and storage; quickrelease from stand■Maximum Flexibility: Common design supports same software image on AIO andmodular PoS■Low TCO over a reliable 10+ years’ service life, 5+ Years’ make plus extra 5+Years’ serviceIntroductionThe new Fujitsu TP8 All-In-One (AIO) PoS terminal is a next generation point-of-sale solution for retailers who want the best performance, functionality, reliability, serviceability, and maximum ROI to create an attractive world-class shopping environment. The TP8 Model A6xx with Intel® 6th Generation “Skylake” CPUs, from Celeron® “A610” to Intel® Core™ i5 “A650”; protects investments in Windows® 7 and 8.x environments with migration to Windows 10. The TP8 Model A7xx with 7th Generation “Kaby Lake” CPUs up to Intel® Core™ i5 “A750”, gives maximum Windows 10 performance. With up to 32 GB RAM, options for 2.5” SATA3 heritage drives and the new, ~3x faster M.2 PCIE NVME SSD drives, the TP8 is a future-proof PoS platform or even a genuine store server. The TP8 combines leading performance, peripheral and network connectivity in a super sleek package.The TP8 PoS is a family of AIO and Modularsystems, sharing key parts so the samesoftware image runs on both, for flexibledeployment and reduced support costs. TheTP8 is one of the most modular AIOs available,with easily field-swappable LCDs (15”, 18.5”)and PC module, further reducing support costsand simplifying migration to future modulesand technology – all while extending the life ofexisting components like the LCD.The sleek and stylish design of the TP8 AIO hasmodern aesthetics that easily blend with a fullrange of retail environments - from fashionableand sophisticated to extremely rugged. Thedual-hinge stand enables flat-folding for cleancounters, adjustability to suit variable heightoperators and 150° tilting from vertical to pasthorizontal for easy cable/connector access,while hiding cables for best aesthetics andsecurity. Retailers want the flexibility of asingle platform that supports multiple in-storetouch points, reducing installation and servicecosts, and providing fast, easy customertransactions for the ultimate shoppingexperience. The TP8 AIO installs easily oncounter-top, pole, wall and in kiosks.The TP8 continues the TeamPoS® tradition ofsuperior quality and reliability. Intelligentpower management and advanced thermaldesigns, including blade-server heat-sink andfan, ensure cool reliable operation in theharshest retail conditions. High quality drivesprotect data and boost uptime, e.g. 1x 2.5”SATA3, or up to 2x M.2 PCIE SSDs with RAID1mirroring. The TP8 is easy to service with fasttool-free access to many key parts and a screw-driver to access the rest, e.g. external access toRAM and storage, thumb-screw removal of AIOfrom stand. Support for Intel® Active18.5” LCD15” LCDManagement Technology (AMT), vPro™ and SMBIOS enables remote management by leading enterprise suites.Customer-focused applications such as registration, promotions, and loyalty programs can be deployed easily with the TP8 AIO customer-facing display that can be integrated or dispersed for maximum flexibility. Fujitsu offers a full set of leading-edge PoS peripheral options that have gone through extensive compatibility and reliability testing to maximize system scalability and flexibility. This robust peripheral portfolio gives retailers the ability to extend the useful life of the TP8 AIO through incremental modifications as business requirements change.High Performance and Connectivity:■Latest Intel® processors, Celeron® to Core™ i5; Q170 chipset■32 GB RAM max. 2x high speed DDR4SO-DIMM■Up to 2x M.2 PCIe NVME SSD, up to 3x faster than SATA3■1” x 2.5” bay for optional SATA3 drive■Gigabit LAN: Optional WLAN, WWAN(region dependent)■Peripheral ports: 2x video, 10 USB (6x5V, 3x12V, 1x24V), 1x Serial DB9 0/5/12V, audio, cash drawer Versatility:■Sleek contemporary design■Counter-top and VESA options available■15” and 18.5” modular PCap Touch LCD (field swappable)■Open architecture; wide operatingsystem supportGreen:■Processor and LED backlight power-saving modes■Efficient power supply supportingmultiple peripherals■Green recyclable materials: WEEE andROHS compliant■Eco-friendly packaging andminimal documentationGeneral Specifications ProcessorIntel® 6th Generation “Skylake” 35W, supporting Windows 7, 8.x and 10: ■A610: Celeron® G3900TE 2.3GHz, 2 core / 2 threads, 2MB, No AMT■A650: Intel® Core™ i5-6500TE 2.3-3.3GHz, 4 core / 4 threads, 6MB, AMT and Intel® vPro™Intel® 7th Generation “Kaby Lake” 35W, supporting Windows 10 only:■A710: Intel® Celeron® G3930TE 2.5GHz, 2 core / 2 threads, 2MB, No AMT■A750: Intel® Core™ i5-7500T 2.7-3.3GHz, 4 core / 4 threads, 6MB, AMT and Intel® vPro™Chipset Intel® Q170 Express, Intel Active Management Technology (Intel® AMT v11.6) and Intel® vPro™ on Intel® Core™ i5,TPM v2.0Operator Display 15” 4:3 and 18.5” 16:9 LCD size options, with Projected Capacitive Multi-Touch Gesturing Memory 4GB memory in all base models. 32GB max supported; 2 slots total. Optional 4GB, 8GB and 16GB modules BIOS AMI µEFI BIOS with Remote BIOS Flash Audio TAC97-compliant high-definition audioGraphics Integrated Intel high-definition graphics controllerConnectivity High-speed Gigabit LAN RJ-45 10/100/1000 Mbps with Wake On LAN.Storage Standard 1x 2.5” 128GB SATA3 SSD in base modelsOptional: 1x or 2x M.2 PCIe NVME SSD 128 or 256GB w/ RAID 0/1; or 2.5” 500GB SATA3 HDDI/O Ports 10 USB (4x 5W USB 3.1 gen1, USB2: 2x5V, 3x12V, 1x24V), 1x Serial DB9 0/5/12V, 2x DisplayPort, 1x cash drawer RJ-12(Y-cable option for 2nd cash drawer), 1x line out, 1x mic inPower Supply220W AC Adapter supporting maximum powered peripheral configurationSystem Management Intel Active Management Technology (AMT) and Intel® vPro™, Desktop Management Interface (DMI), Pre-boot Execution Environment (PXE), Advanced Power Management (APM), Advanced Configuration and Power Interface(ACPI), Wake on LAN (WOL), System Management BIOS, TPM v2.0ColorBlackDimensions 14.8”(W) x 2.6” (D) x 12.4” (H) | 367.6mm (W) x 67mm (D) x 315.8 (H) (width and depth with counter-top base with15” display; depth is AIO head unit only) Weight24 lb / 10.9 KgCertificationsFCC, CSA, RSM, CE (TBD); CCC (TBD), VCCI (TBD) Green Compliance WEEE, ROHSOptionsSupports all popular standard retail peripheralsAIO Mounting Countertop Stand, dual hinge for excellent adjustability, with connector & cable covers. 3rd party VESA stands also ConnectivityWireless LAN 802.11 a/b/g/n Mini PCIe Card with Wake On LANCustomer Display Optional 15” colour customer-facing LCD, XGA 1024x768. Non-Touch 400cd/m2 , PCap Touch 350cd/m 2Customer VFD Alpha-numeric (20 digits x 2 lines) 245 (W) x 40 (D) x 100 (H) mm non-integrated pole/remote mount (tilt/swivel) Printers Epson®: TM-H6000, TM-H2000, TM-T88, TM-T70. Fujitsu CT-11, FP-2000 Keyboards Fujitsu 133-key keyboards and Fujitsu 110-key keyboards MSR3-Track Magnetic Stripe Reader (MSR) Cash Drawers Standard, Compact and Flip-Top SoftwareOperating Systems POSReady 7 32/64bit, Windows 7 Pro 32/64bit, Windows 8.1, Windows 10 IoT Ent. 2016 LTSB Value, SUSE® Linux® 12 API’sSupports UPOS 1.14 (OPOS, JPOS) and ESC-POS based applicationsFujitsu recommends Windows.Technical detailsAbout Fujitsu AmericasFujitsu America, Inc. is the parent and/or management company of a group of Fujitsu-owned companies operating in North, Central and South America and Caribbean, dedicated to delivering the full range of Fujitsu products, solutions and services in ICT to our customers in the Western Hemisphere. These companies are collectively referred to as FujitsuAmericas. Fujitsu enables clients to meet their business objectives through integrated offerings and solutions, including consulting, systems integration, managed services, outsourcing and cloud services for infrastructure, platforms and applications; data center and field services; and server, storage, software and mobile/tablet technologies. For more information, please visit: /us and /fujitsuamericaContactFUJITSU AMERICA, INC.Address: 1250 East Arques Avenue Sunnyvale, CA 94085-3470, U.S.A.Telephone: 800 831 3183 or 408 746 6000Website: Contact Form: /contact Haveaquestion?Emailusat:*********************.comFujitsu recommends Windows.。

SMP产品介绍2月, 2006年编4月, 2006年译The information contained in this document is accurate at the time of printing. Allot Communications makes no representations or warranties, express or implied, concerning the content, completeness or accuracy of the information containedtherein.© Allot Communications 2006 all rights reserved.NetEnforcer® and NetXplorer® is a registered trademark of Allot. Other product names and logos mentioned herein may be trademarks and/or registeredtrademarks of their respective companies.No part of this may be reproduced, disclosed or used except as authorized by contract or other express written permission by Allot.目录1专业术语以及简称 (1)2先进的基于宽带用户的服务－综述 (1)2.1 介绍 (1)2.2 目的 (2)3系统功能介绍 (2)3.1 监视 (3)3.1.1宽带用户分布报告 (3)3.1.2最活跃的用户的协议 (3)3.1.3流行性报告 (3)3.1.4基于使用情况的报告 (4)3.2 分级服务 (4)4宽带用户管理系统架构 (5)4.1 综述 (5)4.2 信息流 (6)4.2.1创建服务 (6)4.2.2验证和服务起动的过程 (6)4.2.3服务器与SMF流程 (9)4.2.4NX记帐流程 (9)4.3 系统部署 (10)4.3.1Server / Module Layout 服务器/模块层 (10)5集成和整合功能 (13)5.1 与RADIUS服务器集成 (13)5.2 与DHCP 集成 (13)5.3 与OSS系统集成 (14)5.4 记帐 / 综合营帐系统的整合 (14)1 专业术语以及简称ARPU 平均宽带用户收入BW 带宽NE NetEnforcer设备NX NetXplorer 软件OPEX 操作成本OSS 运营支持系统P2P 点对点SMF 宽带管理功能－这个模块的功能是建立宽带用户－》动态IP地址->和服务计划之间的映射关系。

8 Channel High Power Stereo Speaker SelectorPSS8Read all documentations carefully before operating the equipment.Retain this manual for future reference. Congratulations for purchasing the PSS88 Channel High Power Stereo Speaker Selector. It lets you connect up to eight separate pairs of speakers to your stereo receiver/ampli er. The control center is especially convenient if you have speaker sets in di erent rooms and want to turn them on and o independently.You can enjoy the convenience and exibility o istening to multiple speaker pairs simultaneously.Terminal Buttons Protection ButtonsThe control center lets you use one to eight sets of speakers at a time, and is designed to operate with a stereo receiver/ampli er that has a maximum of 100 watts per channel, and with speaker systems that have a minimum impedance of 8 ohms (see "Impedance Chart" on page 5)PREPARATIONS• Use the PYLE PRO Speaker Selectors only with amplifiers rated at 100 watts perchannel or less.• Your PYLE PRO Speaker Selector is designed to accept any size cable up to 14 gauge non-terminated speaker wire. If you're using non-terminated speaker wire, do not use any speaker wire that is larger than 14 gauge. The lower the gauge number, the larger the cable (e.g., 12 gauge is larger in actual physical size than 14 gauge).• Do not hook the outputs of one selector into the inputs of another speakerselector together.2 3MAKING THE CONNECTIONSThe control center divides the power from your receiver/ampli er di erently to its speaker terminals. (This is especially noticeable when you connect only one pair of speakers. If you connect more than one pair of speakers, see "Impedance Chart " on page 5 to selector the best terminals to connect.) For the best performance, make the connections based on how frequently you use each set of speakers. Cautions:To avoid damaging your speakers or receiver/ampli er:• Be sure your receiver/amplifier's power is turned off before you make the connections.• Never let the speaker wire's bare ends touch each other or the adjacent terminals on the control center.• Do not connect more than one pair of sepakers to each set of terminals.Press open the desired SPK terminals on the control center. Insert the speakers' positive (+) wires in the positive (red) terminals, and negative (-) wires into thenagative (black) terminals, according to the respective L (left) and R (right) terminals.Then press the tabs to close them.Press open the AMP terminals on the control center, then insert your receiver/ampli- er's positive (+) wires into the positive (red) terminals, and negative (-) wires in the nagative (black) terminals. Then press the tabs to close them.Notes:• If your receiver/ampli er has more than one set of speaker terminal (A and B),connect only one or the other to the control center.• For the best results, we recommend 14-gauge, two conductor speaker wire (notsupplied) for most connections. If you plan to located the speakers further than 80 feet from the control center, use a heavier gauge of wire.OPERATIONCautions:• To avoid damaging your receiver/ampli er, set its volume to the lowest settingbefore changing the control center's settings.• To turn on a pair of speakers connected to the control center, simply press in the desired button. For example, to turn on the set of speakers connected to SPKA,press A.• To turn o a pair of speakers, press the button again so it is in the "out" position. Note:If no speakers are connected to a set of terminals, do not press in the corresponding control button.IMPEDANCE CHARTImpedance is a measurement of the load placed on your receiver/ampli er by the speakers. The load placed on your receiver/ampli er from the control center will vary depending on how many pairs of speakers you turn ON at one time, and on which speakers you turn ON. The chart below shows the impedance for all possible combinations of 8-ohm speakers.4IMPEDANCE CHART56This products can expose you to a chemical or group of checmicals, which may include ”Nickel Carbonate” which is known in the state of California to cause cancer, birth defects, or other reproductive harm. For more info, go to https:///.7Features:• Multi-Channel High Powered Ampli er• Individual Speaker Volume Control• Support Two Stereo Ampli ers• Rugged & Durable Housing Construction, Cabinet Heatsink• Control Powered 8 Channel Ampli er• Plug and Play Easy Install• Up To 8 Separate Speakers Pair To Your Stereo System.• Accepts Speaker Wires Up To 14-Gauge.• Handles 100 Watts Per Channel With Speaker Systems That Have A Minimum • Protection Circuitry Keeps It Running SmoothlyWhat’s in the Box:• Power Stereo Speaker SelectorTechnical Specs:• Power Output:8 x 25 Watts• Minimum Impedance: 4 Ohms• Frequency Response: 20Hz - 20KHz• Speaker Terminal Wire Size: 14-22 gauge• Max. Amplifier Input: 100W RMS, 150W AVG• Max. Output per Speaker: 18W RMS, 50W AVG• Dimensions 12.8'' X 2.04'' X 6.12'' -inchesQuestions? Issues?We are here to help! Phone: (1) 718-535-1800Email: *******************。

MPLAB® Code Configurator SMPS Library Release NotesWhat is the MPLAB Code Configurator SMPS LibraryThe MPLAB Code Configurator SMPS Library allows quick and easy configuration, and code generation for 8-bit PIC SMPS applications.System Requirements1.MPLAB® X IDE v5.40 or later2.MCC v4.0.1 or later3.MCC Core v5.0.0 or later4.MCC PIC10 / PIC12 / PIC16 / PIC18 MCU Library 1.81.6 or later5.XC8 compiler v2.20 or laterRelated Hardware and Documentation SupportMPLAB Code Configurator Switch Mode Power Supply Library User's GuideCIP Hybrid Power Starter KitInstalling the MPLAB Code Configurator SMPS Library1.To install the MPLAB® Code Configurator Plugin:1.1.In the MPLAB X IDE, select Plugins from the Tools menu1.2.Select the Available Plugins tab1.3.Check the box for the MPLAB® Code Configurator v4, and click on Install2.To install the SMPS Library:2.1.In the MPLAB X IDE, select Options from the Tools menu2.2.Select the MPLAB® Code Configurator 4.x tab from Plugins option2.3.Click on Install Library/Open Library Folder2.4.Add SMPSPowerLibrary_vX.X.X.jar2.5.Restart MPLAB X IDE (optional)3.To load different SMPS Library version:3.1.Open MPLAB® Code Configurator v4 from the Tools menu3.2.Expand the Versions tab under Software/SMPS Power Library (loaded version is indicated by thegreen mark)3.3.Right click on the desired version of the library and select Mark for load3.4.Click on the Load Selected Libraries button to load the libraryWhat’s New•v1.4.0–Compatibility update with MCC Plugin v4.0.1 and MCC Core v5.0.0–Various output pin fixes•v1.3.0–Added CIP Hybrid Starter Kit (PCMC/VMC) Demo modules–Added a CIP SEPIC LED Driver Demo module•v1.2.1–Removed local peripheral modules–Added dependency to the MCC 8bit PIC Library•v1.2.0–Added support for PIC16(L)F176x devices–Updated the Compensator Block module with an override setting–Updated the Fault Block module with CIN- pin options–Updated the PCMC Control Mode module with LED dimming options –Added the Pulse Modulator Block module–Added the SEPIC_LED Topology module–Added up to four instances of each SMPS Library module•v1.0.0–Initial release with support for a Synchronous Buck Topology moduleSupported Families•8-bit Families–PIC16(L)F177x–PIC16(L)F176xTable of ContentsWhat is the MPLAB Code Configurator SMPS Library (1)1.System Requirements (1)2.Related Hardware and Documentation Support (1)3.Installing the MPLAB Code Configurator SMPS Library (1)4.What’s New (1)5.Supported Families (2)The Microchip Website (4)Product Change Notification Service (4)Customer Support (4)Microchip Devices Code Protection Feature (4)Legal Notice (5)Trademarks (5)Quality Management System (6)Worldwide Sales and Service (7)The Microchip WebsiteMicrochip provides online support via our website at /. This website is used to make files and information easily available to customers. Some of the content available includes:•Product Support – Data sheets and errata, application notes and sample programs, design resources, user’s guides and hardware support documents, latest software releases and archived software•General Technical Support – Frequently Asked Questions (FAQs), technical support requests, online discussion groups, Microchip design partner program member listing•Business of Microchip – Product selector and ordering guides, latest Microchip press releases, listing of seminars and events, listings of Microchip sales offices, distributors and factory representativesProduct Change Notification ServiceMicrochip’s product change notification service helps keep customers current on Microchip products. Subscribers will receive email notification whenever there are changes, updates, revisions or errata related to a specified product family or development tool of interest.To register, go to /pcn and follow the registration instructions.Customer SupportUsers of Microchip products can receive assistance through several channels:•Distributor or Representative•Local Sales Office•Embedded Solutions Engineer (ESE)•Technical SupportCustomers should contact their distributor, representative or ESE for support. Local sales offices are also available to help customers. A listing of sales offices and locations is included in this document.Technical support is available through the website at: /supportMicrochip Devices Code Protection FeatureNote the following details of the code protection feature on Microchip devices:•Microchip products meet the specifications contained in their particular Microchip Data Sheet.•Microchip believes that its family of products is secure when used in the intended manner and under normal conditions.•There are dishonest and possibly illegal methods being used in attempts to breach the code protection features of the Microchip devices. We believe that these methods require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data Sheets. Attempts to breach these codeprotection features, most likely, cannot be accomplished without violating Microchip’s intellectual property rights.•Microchip is willing to work with any customer who is concerned about the integrity of its code.•Neither Microchip nor any other semiconductor manufacturer can guarantee the security of its code. Code protection does not mean that we are guaranteeing the product is “unbreakable.” Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our products.Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act.If such acts allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.Legal NoticeInformation contained in this publication is provided for the sole purpose of designing with and using Microchip products. Information regarding device applications and the like is provided only for your convenience and may be superseded by updates. It is your responsibility to ensure that your application meets with your specifications.THIS INFORMATION IS PROVIDED BY MICROCHIP “AS IS”. MICROCHIP MAKES NO REPRESENTATIONS OR WARRANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED, WRITTEN OR ORAL, STATUTORY OR OTHERWISE, RELATED TO THE INFORMATION INCLUDING BUT NOT LIMITED TO ANY IMPLIED WARRANTIES OF NON-INFRINGEMENT, MERCHANTABILITY, AND FITNESS FOR A PARTICULAR PURPOSE OR WARRANTIES RELATED TO ITS CONDITION, QUALITY, OR PERFORMANCE.IN NO EVENT WILL MICROCHIP BE LIABLE FOR ANY INDIRECT, SPECIAL, PUNITIVE, INCIDENTAL OR CONSEQUENTIAL LOSS, DAMAGE, COST OR EXPENSE OF ANY KIND WHATSOEVER RELATED TO THE INFORMATION OR ITS USE, HOWEVER CAUSED, EVEN IF MICROCHIP HAS BEEN ADVISED OF THE POSSIBILITY OR THE DAMAGES ARE FORESEEABLE. 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No licenses are conveyed, implicitly or otherwise, under any Microchip intellectual property rights unless otherwise stated.TrademarksThe Microchip name and logo, the Microchip logo, Adaptec, AnyRate, AVR, AVR logo, AVR Freaks, BesTime, BitCloud, chipKIT, chipKIT logo, CryptoMemory, CryptoRF, dsPIC, FlashFlex, flexPWR, HELDO, IGLOO, JukeBlox, KeeLoq, Kleer, LANCheck, LinkMD, maXStylus, maXTouch, MediaLB, megaAVR, Microsemi, Microsemi logo, MOST, MOST logo, MPLAB, OptoLyzer, PackeTime, PIC, picoPower, PICSTART, PIC32 logo, PolarFire, Prochip Designer, QTouch, SAM-BA, SenGenuity, SpyNIC, SST, SST Logo, SuperFlash, Symmetricom, SyncServer, Tachyon, TempTrackr, TimeSource, tinyAVR, UNI/O, Vectron, and XMEGA are registered trademarks of Microchip Technology Incorporated in the U.S.A. and other countries.APT, ClockWorks, The Embedded Control Solutions Company, EtherSynch, FlashTec, Hyper Speed Control, HyperLight Load, IntelliMOS, Libero, motorBench, mTouch, Powermite 3, Precision Edge, ProASIC, ProASIC Plus, ProASIC Plus logo, Quiet-Wire, SmartFusion, SyncWorld, Temux, TimeCesium, TimeHub, TimePictra, TimeProvider, Vite, WinPath, and ZL are registered trademarks of Microchip Technology Incorporated in the U.S.A.Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut, BlueSky, BodyCom, CodeGuard, CryptoAuthentication, CryptoAutomotive, CryptoCompanion, CryptoController, dsPICDEM, , Dynamic Average Matching, DAM, ECAN, EtherGREEN, In-Circuit Serial Programming, ICSP, INICnet, Inter-Chip Connectivity, JitterBlocker, KleerNet, KleerNet logo, memBrain, Mindi, MiWi, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, , PICkit, PICtail, PowerSmart, PureSilicon, QMatrix, REAL ICE, Ripple Blocker, SAM-ICE, Serial QuadI/O, SMART-I.S., SQI, SuperSwitcher, SuperSwitcher II, Total Endurance, TSHARC, USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, and ZENA are trademarks of Microchip Technology Incorporated in the U.S.A. and other countries.SQTP is a service mark of Microchip Technology Incorporated in the U.S.A.The Adaptec logo, Frequency on Demand, Silicon Storage Technology, and Symmcom are registered trademarks of Microchip Technology Inc. in other countries.GestIC is a registered trademark of Microchip Technology Germany II GmbH & Co. KG, a subsidiary of Microchip Technology Inc., in other countries.All other trademarks mentioned herein are property of their respective companies.© 2020, Microchip Technology Incorporated, Printed in the U.S.A., All Rights Reserved.ISBN:Quality Management SystemFor information regarding Microchip’s Quality Management Systems, please visit /quality.Worldwide Sales and Service。

MA816 数据手册版本 0.06目录1.概述 (5)2.功能 (6)3.方框图 (7)4.特殊功能寄存器SFR (8)4.1.SFR 映射表 (8)4.2.SFR 位分配 (9)4.3.SFR 内存分页 (10)5.引脚 (11)5.1.封装 (11)5.2.引脚定义 (12)6.系统时钟 (13)6.1.时钟结构图 (13)6.2.时钟寄存器 (13)7.8051 CPU 功能描述 (15)7.1.CPU 寄存器 (15)7.2.CPU 时序 (16)7.3.CPU 寻址方式 (16)8.存储器结构 (17)8.1.片上程序存储器 (17)8.2.片上数据存储器 RAM (18)8.3.片上扩展RAM (XRAM) (18)8.4.关于C51编译器的声明识别符 (19)9.双数据指针寄存器 (DPTR) (20)10.I/O 结构 (21)10.1.I O 配置 (21)10.1.1.准双向口 (21)10.1.2.推挽输出 (21)10.1.3.仅输入(高阻输入) (22)10.1.4.开漏集输出 (22)10.2.I/O 端口寄存器 (23)10.2.1.端口0 (24)10.2.2.端口1 (24)10.2.3.端口2 (24)10.2.4.端口3 (25)10.2.5.端口4 (25)10.2.6.端口5 (26)10.2.7.端口6 (26)10.2.8.端口7 (27)11.中断 (28)11.1.中断结构 (28)11.2.中断寄存器 (29)12.定时器/计数器 (35)12.1.定时器0 和定时器1 (35)12.1.1.模式0 (35)12.1.2.模式1 (36)12.1.3.模式2 (36)12.1.4.模式3 (37)12.1.5.定时器时钟输出 (37)12.1.6.定时器0/1寄存器 (38)12.2.定时器2 (40)12.2.1.捕获模式 (CP) (40)12.2.2.自动加载模式(AR) (40)12.2.3.波特率发生器模式 (BRG) (42)12.2.4.定时器2的可编程时钟输出模式 (43)12.2.5.定时器2寄存器 (43)12.3.P WM 定时器 (45)12.3.1.PWM 定时器结构 (45)12.3.2.PWM 定时器寄存器 (46)13.串行口 (UART) (48)13.1.模式0详述 (48)13.2.模式1详述 (51)13.3.模式2、3详述 (52)13.4.帧错误检测 (52)13.5.多处理器通讯 (53)13.6.自动地址识别 (53)13.7.波特率设置 (55)13.7.1.模式0波特率 (55)13.7.2.模式2波特率 (55)13.7.3.模式1 & 3波特率 (55)13.8.串口寄存器 (55)14.模拟比较器 (58)14.1.模拟比较器结构 (58)14.2.模拟比较器寄存器 (58)15.看门狗 (WDT) (61)15.1.看门狗结构 (61)15.2.看门狗寄存器 (61)15.3.W DT 硬件选项 (62)16.Power Management (63)16.1.节能模式 (63)16.1.1.空闲模式（Idle） (63)16.1.2.掉电模式(Power-down) (63)16.1.3.中断唤醒 (63)16.1.4.复位唤醒 (63)16.1.5.普通I/O (GPIO) 唤醒 (63)16.2.B rown-Out侦察器 (64)16.3.电源控制寄存器 (64)17.在系统编程 (ISP) (66)18.在应用程序编程 (IAP) (69)19.辅助特殊功能寄存器SFR (70)20.指令集 (72)21.最大绝对额定参数 (76)22.电气特性 (77)22.1.直流特性 (77)23.封装尺寸 (78)24.修订历史 (79)1. 概述MA816 是基于80C51的高效1-T结构的单芯片微处理器，每条指令需要1~7个时钟信号(比标准8051快6~7倍)，与8051指令集兼容。

Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsThe MA4P277/MA4P7437/MADP-007437 series and MA4P278/MA4P7438/MADP-007438 series device have thicker intrinsic regions to provide lower distor-tion in attenuator circuits.The MA4P290/MADP-007167 series devices have the thickest I-Region, offering the lowest distortion and highest IP3 for current controlled attenuator cir-cuits. These devices are ideal for AGC functions for infrastructure and CATV applications.These parts are available as single diodes, series tees (ST), series tee reverse (STR), common cathode pairs (CK), common anode pairs (CA), and unconnected pairs in the respective featured packages.M/A-COM’s PIN diodes are available in the SOT-23 (case style 287), the SOT-143 (case style 1068), the SOT-323/SC-70 (3L) (case style 1146), theSOD-323 (case style 1141), and the SC-79 (case style 1279) packages. These packages are supplied on tape and reel for automatic pick and place assembly. The tape and reel suffix designation is a “T” at the end of the part number.Package OutlinesSOT-23SC-79SOT-143SOD-323SOT-323Features• Industry Standard Surface Mount Packages • Lead-Free (RoHS Compliant) Equivalents Available with 260 °C Reflow Compatibility • Low Loss, High Isolation Switching Diodes • Low Distortion Attenuator Diodes• Single and Dual Diode Configurations • Tape and Reel PackagingDescription and ApplicationsM/A-COM offers silicon PIN diodes in five standard, low cost, surface mount plastic packages for use as switches and attenuators. These diodes are offered with standard Sn/Pb plating, as well as with 100% matte Sn plating on our RoHS compliant devices. M/A-COM’s PIN diodes feature a variety of I-region lengths resulting in lower resistance, and lower capacitance devices for various microwave control circuit applications.The MA4P275/MA4P7436/MADP-007436 series offer the lowest series resistance for best perform-ance as low loss series switches and high isolation shunt switches.The MA4P789/ MA4P7433/MADP-007433 series have the lowest capacitance and offers the highest isolation in series and series-shunt switches through 3GHz.The MA4P282/ MA4P7447/MADP-007155 series and the MA4P274/MA4P7455/ MADP-007455 series are general purpose PIN diodes useful as either switches or attenuators .Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent Parts1. The reverse current will not exceed 10 μA at the reverse voltage rating.2. Total capacitance is measured at 1 MHz at the indicated voltage.3. Series resistance is measured at the specified current and a frequency of 100 MHz.Absolute Maximum Ratings @ 25 °C 1 (Unless Otherwise Noted)1. Operation of these devices above any one of these parameters may cause permanent damage. ParameterAbsolute Maximum ValueOperating Temperature -65°C to +150 °C Storage Temperature -65°C to +125 °CJunction Temperature+ 175 °C RF C.W. Incident Power @ 25 °C:MA4P282 / MA4P7447/MADP-007155 Series( θ die = 15 °C / W ), RF & DC Incident De-rating Coefficient = - 21.3 mW / °C MA4P275 / MA4P7436/MADP-007436 Series( θ die = 25 °C / W ), RF & DC Incident De-rating Coefficient = - 16.8 mW / °C MA4P278 / MA4P7438/MADP-007438Series ( θ die = 30 °C / W ), RF & DC Incident De-rating Coefficient = - 13.3 mW / °C MA4P274 / MA4P7455/MADP-007455 Series ( θ die = 35 °C / W ), RF & DC Incident De-rating Coefficient = - 13.3 mW / °C MA4P277 / MA4P7437/MADP-007437 Series ( θ die = 45 °C / W ), RF & DC Incident De-rating Coefficient = - 13.3 mW / °C MA4P290 / MADP-007167 Series ( θ die = 55 °C / W ), RF & DC Incident De-rating Coefficient = - 13.3 mW / °CMA4P789 / MA4P7433/MADP-007433 Series( θ die = 80 °C / W ), RF & DC Incident De-rating Coefficient = - 10.7 mW / °C+ 32 dBm + 31 dBm + 30 dBm + 30 dBm + 30 dBm + 30 dBm + 29 dBm Total ( RF + DC ) Power Dissipation @ 25 °C( SOT-23, SOT-143 ) : RF & DC Dissipated De-rating Coefficient = - 33.3 mW / °C( SOT-323, SOD-323, SC-79 ) : RF & DC Dissipated De-rating Coefficient = - 26.7 mW / °C250 mW 200 mW Reverse VoltageVoltage RatingForward Current150 mA DCTotal Capacitance 2Max.Nominal Characteristics Standard Part Number RoHS Compliant Part Number Reverse Voltage 1 (V) R S @ 10 mA 3 Max. (Ohms) Carrier Lifetime 4 (μs) I-Region Thickness (mils) MA4P275 MA4P7436MADP-007436 Series 75 1.00 @ 20V 0.5 0.2 0.4 MA4P789MA4P7433MADP-007433 Series750.35 @ 20V1.50.20.4MA4P282 MA4P7447MADP-007155 Series100 1.20 @ 20V 0.6 1.0 0.8MA4P274 MA4P7455MADP-007455 Series100 0.35 @ 50V 3.0 1.0 2.0MA4P277 MA4P7437MADP-007437 Series200 0.35 @ 50V 6.0 2.0 4.0MA4P278 MA4P7438MADP-007438 Series200 0.35 @ 50V 10.0 3.0 5.0MA4P290 MADP-007167 200 0.30 @ 50V 16.0 3.0 7.0Electrical Specifications @ 25°CSurface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsSingleSingleSC-79SOD-323SOT-23Standard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberMADP-007436-12790T MA4P275-1141T MA4P7436-1141T MA4P275-287T MA4P7436-287T MADP-007433-12790TMA4P789-1141T MA4P7433-1141T MA4P789-287T MA4P7433-287TMA4P282-1141T MA4P7447-1141T MA4P282-287T MA4P7447-287T MADP-007455-12790TMA4P274-1141T MA4P7455-1141T MA4P274-287T MA4P7455-287T MA4P277-1141T MA4P7437-1141T MA4P277-287T MA4P7437-287T MA4P278-1141T MA4P7438-1141T MA4P278-287T MA4P7438-287TMA4P290-1141TMADP-007167-11410TMA4P290-287TMADP-007167-287ATL S = 0.6 nH L S = 1.3 nH L S = 1.4 nH C P = 0.10 pFC P = 0.11 pFC P = 0.12 pFPackaging and ConfigurationsCommon CathodeCommon AnodeSOT-23SC70 (3L)SOT-23SC70 (3L)Standard Part NumberRoHS Compliant Part NumberStandard Part Number RoHS Compliant Part Number Standard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberMA4P275CK-287T MA4P7436CK-287T MA4P275CK-1146T MA4P7436CK-1146T MA4P275CA-287T MA4P7436CA-287T MA4P275CA-1146T MA4P7436CA-1146T MA4P289CK-287T MA4P7433CK-287T MA4P789CK-1146T MA4P7433CK-1146TMA4P789CA-287T MA4P7433CA-287T MA4P789CA-1146TMA4P7433CA-1146TMA4P282CK-287T MA4P7447CK-287TMA4P282CA-287T MA4P7447CA-287TMA4P274CK-287T MA4P7455CK-287T MA4P274CK-1146T MA4P7455CK-1146TMA4P274CA-287T MA4P7455CA-287T MA4P274CA-1146TMA4P7455CA-1146TMA4P277CK-287T MADP-007437-0287FT MA4P277CA-287T MA4P7437CA-287T MA4P278CK-287T MADP-007438-0287FT MA4P278CA-287TMA4P7438CA-287T MA4P290CK-287TMADP-007167-0287FTMADP-007167-0287GTL S = 1.4 nH L S = 1.3 nH L S = 1.4 nHL S = 1.3 nHC P = 0.12 pFC P = 0.12 pFC P = 0.12 pFC P = 0.12 pFSurface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsPackaging and ConfigurationsSeries TeeSeries Tee ReverseSOT-23SC70 (3L)SOT-23SC70 (3L)Standard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberMA4P275ST-287T MA4P7436ST-287T MA4P275ST-1146T MA4P7436ST-1146T MA4P275STR-287T MADP-007436-0287DT MA4P275STR-1146T MADP-007436-1146DT MA4P789ST-287TMA4P7433ST-287TMA4P789ST-1146TMA4P7433ST-1146TMA4P789STR-287TMADP-007433-0287DTMA4P789STR-1146TMADP-007433-1146DTMA4P282ST-287T MA4P7447ST-287T MA4P282ST-1146T MADP-007155-1146BT MA4P282STR-287T MADP-007155-0287DT MA4P282STR-1146T MADP-007155-1146DTMA4P274ST-287T MA4P7455ST-287T MA4P274ST-1146T MA4P7455ST-1146T MA4P274STR-287T MADP-007455-0287DT MA4P274STR-1146T MADP-007455-1146DTMA4P277ST-287T MADP-007437-0287BT MA4P277ST-1146T MADP-007437-1146BT MA4P277STR-287T MADP-007437-0287DT MA4P277STR-1146T MADP-007437-1146DTMA4P278ST-287T MADP-007438-0287BT MA4P278ST-1146T MADP-007438-1146BT MA4P278STR-287T MADP-007438-0287DT MA4P278STR-1146T MADP-007438-1146DTMADP-007167-0287BT MADP-007167-1146BT MA4P290STR-287T MADP-007167-0287DT MADP-007167-1146DTL S = 1.4 nH L S = 1.3 nH L S = 1.4 nHL S = 1.3 nHC P = 0.12 pFC P = 0.12 pFC P = 0.12 pFC P = 0.12 pFLow InductanceUnconnected PairSOT-23SOT-143Standard Part NumberRoHS Compliant Part NumberStandard Part NumberRoHS Compliant Part NumberMA4P290-LI-287TMADP-007167-0287HTMA4P275-1068T MA4P7436-1068T MA4P789-1068T MA4P7433-1068TMA4P274-1068TMA4P7455-1068TL S = 0.4 nH L S = 1.3 nH C P = 0.12 pFC P = 0.12 pFSurface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsTypical Forward Resistance vs DC Bias Current Curves @ 100 MHzResistance vs Forward Current(MA4P277 / MA4P7437 /MADP-007437 Series)Resistance vs Forward Current(MA4P278 / MA4P7438 /MADP-007438 Series)Resistance vs Forward Current(MA4P275 / MA4P7436 /MADP-007436 Series)Resistance vs Forward Current(MA4P274 / MA4P7455 MADP-007155 Series)0.1110100100010000FORWARD BIAS CURRENT S E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mA0.1110100100010000FORWARD BIAS CURRENTS E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mA0.1110100100010000FORWARD BIAS CURRENT S E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mA110100100010000100000FO RWARD BIAS CURRE NTS E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mASurface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsTypical Forward Resistance vs DC Bias Current Curves @ 100 MHzResistance vs Forward Current(MA4P282 / MA4P7447 / MADP-007155 Series)Resistance vs Forward Current(MA4P789 / MA4P7433/ MADP-007433 Series)0.1110100100010000FORWARD BIAS CURRENTS E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mA0.1110100100010000FORWARD BIAS CURRENTS E R I E S R E S I S T A N C E , R S (O H M S )1μA 10μA 100μA 1mA 10mA 100mA0.01 0.1 110 100Forward Bias Current (m A)110100100010,000Resistance vs Forward Current (MA4P290 / MADP-007167 Series)Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsCase Styles F DHJAGLCEB KNM A EDJHGF10°A X.CBSOT-23 (Case Style 287)INCHES MILLIMETERSDIM.MIN. MAX.MIN. MAX.A ⎯0.048 ⎯1.22 B ⎯0.008 ⎯0.20 C ⎯0.040 ⎯1.00 D 0.013 0.020 0.35 0.50 E 0.003 0.006 0.08 0.15 F 0.110 0.1192.803.00 G 0.047 0.0561.20 1.40H 0.037 typical 0.95 typical J 0.075 typical1.90 typicalK ⎯0.103 ⎯ 2.60 L⎯0.024 ⎯0.60 DIM.GRADIENTM 10° max.1 N2° . . .30°Note: 1. Applicable on all sidesSOT-323 (Case Style 1146)INCHES MILLIMETERS DIM.MIN. MAX.MIN. MAX.A 0.063 0.087 1.6 2.2B 0.045 0.053 1.15 1.35C 0.079 0.087 2.0 2.2D 0.047 0.055 1.2 1.4E 0.008 0.016 0.2 0.4F 0.031 0.039 0.8 1.0G ⎯ 0.004⎯0.1H 0.003 0.08 typicalJ0.0040.10.0060.0100.15 0.25SOT-323Case Style 1146SOT-23Case Style 287Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsG JEKAHMCFB LPN DCase Styles (Cont’d) FDHGCEABSOT-143Case Style 1068SOD-323 (Case Style 1141)INCHES MILLIMETERS DIM.MIN. MAX.MIN. MAX.A ⎯ 0.043 ⎯ 1.1B ⎯ 0.004 ⎯ 0.1C ⎯ 0.008 ⎯ 0.2D 0.010 0.016 0.25 0.4E 0.003 0.006 0.08 0.15F 0.063 0.075 1.6 1.9G 0.045 0.0571.15 1.45H0.0910.106 2.32.7SOT-143 (Case Style 1068)INCHES MILLIMETERSDIM.MIN. MAX. MIN. MAX.A ⎯ 0.044 ⎯1.10 B ⎯ 0.004 ⎯0.10 C ⎯ ⎯ D 0.013 0.020 0.35 0.50 E 0.030 0.035 0.75 0.90 F 0.003 0.006 0.08 0.15 G 0.110 0.119 2.80 3.00 H 0.047 0.056 1.20 1.40J 0.075 typical 1.90 typical K 0.075 typical 1.90 typical L ⎯ 0.103 ⎯ 2.6M ⎯ ⎯DIM.GRADIENTM 10° max. 1N2° . . . 30°0.0400.0241.000.6Note: 1. Applicable on all sidesSOD-323Case Style 1141Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsMounting InformationThe illustration indicates the recommended mounting pad configuration for the SOT-23, SOT-323 , SOD-323, SOT-143, and SC-79 packages. Solder paste containing flux should be screened onto the pads to a thickness of 0.005- 0.007 inches. The plastic package is placed in position, firmly adhering to the solder paste.Permanent attachment is performed by a reflow soldering procedure during which the tab temperature does not exceed +275 °C and the body temperature does not exceed +250 °C, for standard models and +260 °C for the RoHS compliant devices.Please refer to Application Note M538 for surface mounting instructions.0.751.9.0370.95.0350.90.0902.2.0300.80inchesmmDimenstions:min.min.SOT-23SOT-3230.0300.800.0300.800.0300.800.0751.90.0300.80inchesDimenstions:SOD-3230.0300.80.0902.20.0300.80inchesm mDim enstions:0.0300.80SOT-1430.0350.890.1152.920.0451.170.0451.140.0300.76inchesmmDimenstions:0.0451.140.1062.690.0310.79SC-790.020 0.500.053 1.35inchesm mDim enstions:0.020 0.50Surface Mount Plastic PIN DiodesV16SMPP SeriesEquivalent PartsCase Styles (Cont’d) SC-79Case Style 1279SC-79 (Case Style 1279)INCHES MILLIMETERS DIM.MIN. MAX.MIN. MAX.A 0.020 0.028 0.51 0.71B 0.003 0.008 0.08 0.20C 0.006 0.010 0.15 0.25D 0.010 0.014 0.25 0.36E 0.059 0.067 1.50 1.70F 0.043 0.051 1.09 1.30G 0.011 0.012 0.28 0.30H 0.037 0.043 0.94 1.09 I0.0270.0350.690.89DEF CathodeBCSeating Plane10°A10°GH。

2014产品版本号：A2文档版本号：V1.0更多产品信息请浏览：广州创龙电子科技有限公司Revision History阅前须知版权声明广州创龙电子科技有限公司保留随时对其产品进行修改和完善的权利，同时也保留在不作任何通告的情况下，终止其任何一款产品的供应和服务的权利。

请用户在购买前向我司获取相关产品的最新信息，本文档一切解释权归广州创龙所有。

©2014-2018 Guangzhou Tronlong Electronic Technology Co.,Ltd. All rights reserved.公司简介广州创龙电子科技有限公司（简称“广州创龙”，英文简称“Tronlong”），是杰出的嵌入式方案商，专业提供嵌入式开发平台工具及嵌入式软硬件定制设计及技术支持等服务，专注于DSP+ARM+FPGA三核系统方案开发，和国内诸多著名企业、研究所和高校有密切的技术合作，如富士康、威胜集团、中国科学院、清华大学等国内龙头企业和院校。

TI 嵌入式处理业务拓展经理Zheng Xiaolong 指出：“Tronlong 是国内研究OMAP-L138最深入的企业之一，Tronlong 推出OMAP-L138+Spartan-6三核数据采集处理显示解决方案，我们深感振奋，它将加速客户新产品的上市进程，带来更高的投资回报率，使得新老客户大大受益。

”经过近几年的发展，创龙产品已占据相关市场主导地位，特别是在电力、通信、工控、音视频处理等数据采集处理行业广泛应用。

创龙致力于让客户的产品快速上市、缩短开发周期、降低研发成本。

选择创龙，您将得到强大的技术支持和完美的服务体验。

产品保修广州创龙所有产品保修期为一年，保修期内由于产品质量原因引起的，经鉴定系非人为因素造成的产品损坏问题，由广州创龙免费维修或者更换。

更多帮助目录1 核心板简介 (5)2 产品特点 (6)3 典型运用领域 (7)4 软硬件参数 (7)5 技术支持和开发资料 (8)6 电气特性 (12)7 机械尺寸图 (13)8 产品认证 (14)9 产品订购型号 (17)10 相关产品列表 (18)11 增值服务 (18)12 更多帮助 (19)1 核心板简介基于TI 浮点DSP TMS320C6748 CPU ，标配工业级，主频456MHz ，； 55mm*33mm ，全国最小DSP 核心板，采用精密工业级B2B 连接器； TI 主推的超低功耗C6000系列DSP 处理器，适用于便携式设备； 标配工业级NAND FLASH ，128/256/512MByte 可选； 标配工业级DDR2，128/256MByte 可选；标配裸机，支持DSP/BIOS 、SYS/BIOS 、TI-RTOS （SYS/BIOS ），提供40多个例程； 通过高低温、振动测试认证，满足工业环境应用；图2 SOM-TL6748背面由广州创龙自主研发的SOM-TL6748是全国最小的C6000系列浮点DSP C6748工业级核心板，55mm*33mm ，仅硬币大小，功耗小、成本低、性价比高。

北京华清伟业技术有限公司SMP用户使用手册OTT Spider系列–用户管理平台张睿l2015/5/20修改历史1目录2前言 (5)2.1什么是SMP? (5)3用户管理 (7)3.1用户管理 (7)3.1.1创建用户 (7)3.1.2删除用户 (8)3.1.3编辑用户 (8)3.1.4冻结用户 (8)3.1.5设备绑定 (9)3.1.6用户缴费 (9)3.1.7产品购买 (10)3.2设备管理 (10)3.2.1查看绑定历史 (11)4产品管理 (11)4.1资费管理 (11)4.1.1创建资费 (11)4.1.2编辑资费 (12)4.1.3删除资费 (13)4.2产品管理 (13)4.2.1创建产品 (13)4.2.2克隆产品 (14)4.2.3编辑产品 (15)4.2.4删除产品 (15)5设置 (15)5.1后台账户管理 (16)5.1.1创建用户 (16)5.1.2编辑用户 (17)5.1.3删除用户 (17)5.1.4重置账号密码 (18)6系统统计 (18)6.1用户统计 (18)6.2产品统计 (19)6.3缴费统计 (19)6.4收益统计 (20)2前言本手册介绍sovp的基本概念和业务流程。

有几个重要的概念需要了解：资源（resource），内容（content），用户（subscriber），内容提供商（provider）等。

2.1什么是SMP?SMP后台用户管理系统是华清伟业 spider平台的几个核心部件之一，为运营商提供产品、用户管理。

这个平台的功能包括，用户、产品、资费的创建、编辑、删除，以及设备的绑定，用户缴费、退费等功能。

产品（Product）产品是商品化货币化的的视频内容。

产品由基本信息（Basic），内容信息（Content），区域（Region）和资费（Rate)四个部分定义。

产品分两类：简单产品（simple），复杂产品（complex）。

简单产品只能包含一个内容，复杂产品可以包含多个内容。

Package‘APtools’October12,2022Type PackageTitle Average Positive Predictive Values(AP)for Binary Outcomes andCensored Event TimesVersion6.8.8Depends graphics,stats,utils,survival,cmprskAuthor Hengrui Cai<********************>,Yan Yuan<*****************>,Qian Michelle Zhou<****************>,Bingying Li<*********************>Maintainer Hengrui Cai<********************>Description We provide tools to estimate two prediction accuracy metrics,the average positive predictive values(AP)as well as the well-known AUC(the area under the receiver operator characteristic curve)for risk scores.The outcome of interest is either binary or censored event time.Note that for censored event time,our functions'estimates,the AP and theAUC,are time-dependent for pre-specified time interval(s).A function thatcompares the APs of two risk scores/markers is also included.Optionaloutputs include positive predictive values and true positive fractions atthe specified marker cut-off values,and a plot of the time-dependent APversus time(available for event time data).License LGPL-3Encoding UTF-8LazyData trueNeedsCompilation noRepository CRANDate/Publication2018-09-2104:40:09UTCR topics documented:APBinary (2)APSurv (3)CompareAP (5)mayo (6)Index812APBinary APBinary Estimating the AP and the AUC for Binary Outcome Data.DescriptionThis function calculates the estimates of the AP and AUC for binary outcomes as well as their confidence intervals using the perturbation or the nonparametric bootstrap resampling method. UsageAPBinary(status,marker,cut.values=NULL,method="none",alpha=0.95,B=1000,weight=NULL)Argumentsstatus Binary indicator,1indicates case/the class of prediction interest and0other-wise.marker Numeric risk score.Data can be continuous or ordinal.cut.values risk score values to use as a cut-off for calculation of positive predictive values (PPV)and true positive fractions(TPF).The default value is NULL.method Method to obtain confidence intervals.The default is method="none",in which case only point estimates will be given without confidence intervals.If method="perturbation",then perturbation based CI will be calculated.If method="boot-strap",then nonparametric bootstrap based CI will be calculated.alpha Confidence level.The default level is0.95.B Number of resampling to obtain confidence interval.The default value is1000.weight Optional.The default weight is1,same object length as the"status"and"marker"ers can use their own weights,and the length of weight is required tobe the same as the length of status.Valuean object of class"APBinary"which is a list with components:ap_summary Summary of the AP,including the proportion of cases,a point estimate of AP, and their corresponding confidence intervals.auc_summary Summary of the AUC,including a point estimate of AUC with a confidence interval.PPV Available object,positive predictive values at the unique risk score in the data.TPF Available object,true positive fractions at the unique risk score in the data. ReferencesYuan,Y.,Su,W.,and Zhu,M.(2015).Threshold-free measures for assessing the performance of medical screening tests.Frontiers in Public Health,3.57.Bingying Li(2015)Threshold-free Measure for Assessing the Performance of Risk Prediction with Censored Data,MSc.thesis,Simon Fraser University,CanadaExamplesstatus=c(rep(1,10),rep(0,1),rep(1,18),rep(0,11),rep(1,25),rep(0,44),rep(1,85),rep(0,176))marker=c(rep(7,11),rep(6,29),rep(5,69),rep(4,261))cut.values=sort(unique(marker)[-1])out1<-APBinary(status,marker,cut.values)out1out2<-APBinary(status,marker,method="perturbation",alpha=0.90,B=1500)out2APSurv Estimating the Time-dependent AP and AUC for Censored Time toEvent Outcome Data.DescriptionThis function calculates the estimates of the AP and AUC for censored time to event data as well as their confidence intervals using the perturbation or the nonparametric bootstrap resampling method.The estimation method is based on Yuan,Y.,Zhou,Q.M.,Li,B.,Cai,H.,Chow,E.J.,Armstrong,G.T.(2018).A threshold-free summary index of prediction accuracy for censored time to eventdata.Statistics in medicine,37(10),1671-1681.UsageAPSurv(stime,status,marker,t0.list,cut.values=NULL,method="none",alpha=0.95,B=1000,weight=NULL,Plot=TRUE)Argumentsstime Censored event time.status Binary indicator of censoring.1indicates observing event of interest,0other-wise.Other values will be treated as competing risk event.marker Numeric risk score.Data can be continuous or ordinal.t0.list Prediction time intervals of interest.It could be one numerical value or a vector of numerical values,which must be in the range of stime.cut.values Risk score values to use as a cut-off for calculation of time-dependent positive predictive values(PPV)and true positive fractions(TPF).The default value isNULL.method Method to obtain confidence intervals.The default is method="none",in which case only point estimates will be given without confidence intervals.If method="perturbation",then perturbation based CI will be calculated.If method="boot-strap",then nonparametric bootstrap based CI will be calculated.alpha Confidence level.The default level is0.95.B Number of resampling to obtain a confidence interval.The default value is1000.weight Optional.The default value is NULL,in which case the observations are weighted by the inverse of the probability that their respective time-dependent event status(whether the event occurs within a specified time period)is observed.In esti-mating the probability,the survival function of the censoring time is estimatedby a Kaplan-Meier estimator under the assumption that the censoring time isindependent of both the event time and risks ers can use their ownweights,in which case the t0.list should be a scalar and the length of weight isrequired to be the same as the length of status.Plot Whether to plot the time-dependent AP versus the prediction time intervals.The default value is TRUE,in which case the AP is evaluated at the time points whichpartition the range of the event times of the data into100intervals.ValueAn object of class"APsurv"which is a list with components:ap_summary Summary of estimated AP(s)at the specified prediction time intervals of interest.For each prediction time interval,the output includes the estimated event rate,apoint estimate of the AP,the estimated scaled AP(ratio of the AP versus eventrate),and their corresponding confidence intervals.auc_summary Summary of AUC at the specified prediction time intervals of interest.For each prediction time intervals,the output includes the estimated event rate and a pointestimate of AUC with a confidence interval.PPV Available object,time-dependent positive predictive values at the unique risk score in the data.TPF Available object,time-dependent true positive fractions at the unique risk score in the data.ReferencesYuan,Y.,Zhou,Q.M.,Li,B.,Cai,H.,Chow,E.J.,Armstrong,G.T.(2018).A threshold-free summary index of prediction accuracy for censored time to event data.Statistics in medicine, 37(10),1671-1681.Bingying Li(2015)Threshold-free Measure for Assessing the Performance of Risk Prediction with Censored Data,MSc.thesis,Simon Fraser University,CanadaExampleslibrary(APtools)data(mayo)t0.list=seq(from=min(mayo[,1]),to=max(mayo[,1]),length.out=5)[-c(1,5)]cut.values=seq(min(mayo[,3]),max(mayo[,3]),length.out=10)[-10]out<-APSurv(stime=mayo[,1],status=mayo[,2],marker=mayo[,3],t0.list=t0.list,cut.values=cut.values,method= bootstrap ,alpha=0.90,B=500,weight=rep(1,nrow(mayo)),Plot=FALSE)outCompareAP5CompareAP Comparison of two risk scores based on the differences and ratio oftheir APs.DescriptionThis function estimates the difference between and the ratio of two APs in order to compare two markers for censored time to event data or binary data.The corresponding confidence intervals are provided.UsageCompareAP(status,marker1,marker2,stime=NULL,t0.list=NULL,method="none",alpha=0.95,B=1000,weight=NULL,Plot=TRUE)Argumentsstatus Binary indicator.For binary data,1indicates case and0otherwise.For survival data,1indicates event and0otherwise.marker1Risk score1(to be compared to risk score2).Its length is required to be the same as the length of status.marker2Risk score2(to be compared to risk score1).Its length is required to be the same as the length of status.stime Censored event time.If dealing with binary outcome,skip this argument which is set to be NULL.t0.list Prediction time intervals of interest for event time outcome.It could be one numerical value or a vector of numerical values,which must be in the range ofstime.It is set to be NULL if stime is NULL.method Method to obtain confidence intervals.The default is method="none",in which case only point estimates will be given without confidence intervals.If method="perturbation",then perturbation based CI will be calculated.If method="boot-strap",then nonparametric bootstrap based CI will be calculated.alpha Confidence level.The default level is0.95.B Number of resampling for obtaining a confidence interval.The default value is1000.weight Optional argument for event time data,i.e.stime is not NULL.Its default value is NULL,in which the observations are weighted by the inverse of the probabil-ity that their respective time-dependent event status(whether the event occurswithin a specified time period)is observed.In estimating the probability,thesurvival function of the censoring time is estimated by a Kaplan-Meier estima-tor under the assumption that the censoring time is independent of both the eventtime and risks ers can use their own weights,in which case the t0.listshould be a scalar and the length of weight is required to be the same as thelength of status.6mayo Plot Optional argument for event time data,i.e.stime is not NULL.For binary data, it is set to FALSE.For event time data,its default value is TRUE and threeplots are generated:1)the time-dependent AUC of two markers;2)the time-dependent AP of two markers;and3)the time-dependent ratio of APs,all versusthe prediction time intervals.The quantities in1)-3)are evaluated at the timepoints which partition the range of the event times of the data to100intervals.Valuedap_summary Summary of the APs of two markers and the differences(AP1-AP2)and their ratio(AP1/AP2).For event time data,these quantities are estimated at thespecified prediction time intervals.The output includes the estimated eventrate/proportion of cases,point estimates of the APs of the two markers,pointestimates of the difference between and ratio of the two APs as well as theirrespective confidence intervals.ReferencesYuan,Y.,Zhou,Q.M.,Li,B.,Cai,H.,Chow,E.J.,Armstrong,G.T.(2018).A threshold-free summary index of prediction accuracy for censored time to event data.Statistics in medicine, 37(10),1671-1681.Yuan,Y.,Su,W.,and Zhu,M.(2015).Threshold-free measures for assessing the performance of medical screening tests.Frontiers in Public Health,3.57.Bingying Li(2015)Threshold-free Measure for Assessing the Performance of Risk Prediction with Censored Data,MSc.thesis,Simon Fraser University,CanadaExampleslibrary(APtools)status=c(rep(1,10),rep(0,1),rep(1,18),rep(0,11),rep(1,25),rep(0,44),rep(1,85),rep(0,176))marker1=c(rep(7,11),rep(6,29),rep(5,69),rep(4,261))marker2=c(rep(7,17),rep(6,29),rep(5,70),rep(4,254))out_binary<-CompareAP(status,marker1,marker2)out_binarydata(mayo)t0.list=seq(from=min(mayo[,1]),to=max(mayo[,1]),length.out=5)[-c(1,5)]out_survival<-CompareAP(status=mayo[,2],marker1=mayo[,3],marker2=mayo[,4],stime=mayo[,1],t0.list=t0.list,method= bootstrap ,alpha=0.90,B=500,weight=rep(1,nrow(mayo)),Plot=FALSE)out_survivalmayo Mayo Marker dataDescriptionTwo marker values with event time and censoring status for the subjects in Mayo PBC datamayo7FormatA data frame with312observations and4variables:time(event time/censoring time),censor(cen-soring indicator),mayoscore4,mayoscore5.The two scores are derived from4and5covariates respectively.SourceT Therneau,P Grambsch(2000)Modeling Survival Data:Extending the Cox Model Springer-Verlag,New York,ISBN:0-387-98784-3.ReferencesFleming T,Harrington D.(1991)Counting Processes and Survival Analysis Wiley,New York.Heagerty,P.J.,Zheng,Y.(2005)Survival Model Predictive Accuracy and ROC Curves Biometrics, 61,92–105Index∗survivalmayo,6APBinary,2APSurv,3CompareAP,5mayo,68。

AddendumThe following sections are added to the 9390 Marinetransceiver User guide, Codan part number 15-04068 Issue 1,May 1996.Options factory fitted in your transceiverCode DescriptionC CICS—access to Computer Interface Command Set throughtransceiver’s I2C adaptor (accessory) or RS-232 port.D Data—support for 9001/9002 fax/data modems.I IPC-500—support for IPC-500.LD Local Diagnostics—local diagnostics such as dB voltsdisplay and SWR.RC Remote Control—support for control of transceiver by8570/8571 remote control system.RDD RDD Telcall—telcall format for use with RDD bases (needsSEL or T).SEL Selcall: Full—send and receive selcall, group call, page call,selective beacon call, status call and telcall.TP Tx Power Select—selectable transmit power level.TxD TxD—sets channel programming capability.U Upper Sideband—upper sideband on transmit frequencies.qAddendumALE callALE calls allow you to use both numeric and alphanumericstation IDs. A numeric ID is a 6-digit number or less. Analphanumeric ID is either a number greater than six digits oran ID containing one or more of the characters ‘A–Z’, ‘@’and ‘?’. Maximum length is 15 characters.Before you can send an ALE call, you need to:•set up your alphanumeric ID if you intend to call analphanumeric ID (refer to the 9390 Marine transceiverReference manual, Addendum)A typical display screen is given below.The top line of the display shows the ID of the last stationcalled.qAddendum Status callA status call enables you to obtain information about a remotetransceiver or control equipment connected to it withoutassistance from the operator at the remote station.There are three types of status call:•type 1: remote diagnostics call—obtains diagnosticmeasurements of the remote transceiver•type 2: remote config call—obtains some configurationdetails of the remote transceiver•type 3: user status call—controls equipment at the remotestation by sending commands that the remote transceiverautomatically passes on to connected equipment.The remote transceiver responds to your status call bysending back the requested information. This information isrecorded in your call memory for you to review.Expect a longer delay for a remote diagnostics call since theremote transceiver must take several measurements before itcan send the reply.A transceiver receiving a status call does not record the callor alert the operator.If the station you are calling has set up a privacy key, you willneed to set up the same privacy key in your transceiver to beable to receive status information from this station.Before you can send a status call, you need to:•make sure that the use of status calls is switched on (referto the 9390 Marine transceiver Reference manual,Addendum)•make sure that the station you are calling is also set up forreceiving status calls•check if you need to match the other station’s use of aprivacy key (refer to the 9390 Marine transceiverReference manual, Chapter 5, Call privacy on/off)Addendum•set up your ID (refer to the 9390 Marine transceiverReference manual, Chapter 8, Selcall ID setup)•set up a channel for selcalling (refer to 9390 Marinetransceiver Reference manual, Chapter 3, Channel andscan table setup).To send a status call:Action Notes1.To find a good channelto use, send selectivebeacon calls on thefrequencies scanned bythe other station.See Selective beacon call on page 5-10.2.In Channel mode, selectthe best channel andwait until the channel isclear of all voice anddata traffic.3.Press Example of the display:The top right position of thedisplay shows the ID of the laststation called.AddendumActionNotes4.Repeatedly pressuntil you see Status Call displayed on the top line.Example of the display:5.Enter the ID you want to call (if different tothe one displayed)numeral buttonIf the transceiver beeps when you try to enter the ID, the channel has been set up with a fixed ID. Refer to the 9390Marine transceiver Reference manual, Chapter 8, Selcall ID setup .6.PressThe display shows the last typeof status call sent, for example,a remote diagnostics call:AddendumActionNotes7.Select one of the three types of status callusingThe status call types are:1 remote diagnostics 2 remote config 3 user status.Have you selected type 1 or 2?Yes ½Step 10.No ½Step 8.8.To edit the message fora user status call, pressExample of the display:9.Select each characterusingand move between characters usingEnter up to 63 characters.To scroll any hidden part of themessage into view, rotateTo clear existing text, pressAddendumActionNotes10.To send the status call,pressCallorExample of the display:While your transceiver waits for call acknowledgment, the display looks like this:If the call was successful, the display immediately reverts to the channel mode display.If after 60 seconds the call was unsuccessful, the display looks like this for three seconds:AddendumAction Notes11.To view the results ofyour status call, checkthe call memory for thetypes of display shownbelow.Call memory holds the information that the remote transceiver sent back to you. In call memory the information scrolls across the screen after a few seconds (see Chapter 6, Reviewing and returning calls held in memory).AddendumAction Notes11. (cont.)qAddendumReceiving CallsAdd the following received call type to the table in C hapter 6,Receiving selective calls.q Reviewing calls held in memoryAdd the following received call type to the table in Chapter 6,Reviewing and returning calls held in memory.qAddendum9390 Marine transceiver User guide 12-50084 Issue 1, Page-11Operating the transceiver from a computerDue to an upgrade in software, the following commands and responses are available.Commands entered at the computerCommand MeaningALECALL=<ID>,SSends an ALE call. If you specify option S , the call is sent silently with the loudspeaker switched off.ALPHAID=<alphanumeric ID>Sets your alphanumeric ID. It can consist of up to 15 of any of the characters: ‘A–Z ’, ‘0–9’, ‘@’ and ‘?’.SIDEBAND=AMChanges the sideband setting for the current channel. If the channel does not allow the sideband setting to be changed, nothing happens.STATUSACK=<ID>,“<message>”,SSends a reply to acknowledge that a user status call has been received.This command is typically generated automatically by equipment connected to thetransceiver. If you specify option S ,the call is sent silently with the loudspeaker switched off.AddendumPage-12, 12-50084 Issue 19390 Marine transceiver User guideCommandMeaningSTATUSCALL=<ID>,“<message>”,SSends one of the three types ofstatus call: a remote diagnostics call for message “1”, a remote config call for message “2”, or a user status call for any other message up to 63characters. If you specify option S ,the call is sent silently with the loudspeaker switched off.STATUSTIME=<timeout>Sets the status call reply timeout in the range 1–255 seconds. The transceiver waits this time forconnected equipment to respond to a user status command before sending a negative acknowledgment.STATUSTIME?Shows you the current setting of the status call reply timeout in seconds.VER?Shows you the version of the command set supported by the transceiver.Computer display in response to a commandMessage MeaningALE-LINK: FAILYour ALE call failed because no ALE link could be established.ALE-LINK:<channel number>,<ID of other station>,<your ID>,<time of call>You successfully sent or received an ALE call.CALL SENTYour call has been sent.Addendum9390 Marine transceiver User guide 12-50084 Issue 1, Page-13Message MeaningCALL STARTED Your call has started.NO ALPHA SELF IDYou tried to send an ALE call to an alphanumeric ID but your own alphanumeric ID is unset.NO EXTERNAL UNIT CONNECTEDYou sent a user status call to a station that is not connected to a computer.NO RESPONSEYour call has not been acknowledged.SIDEBAND:AMA control panel was used to change the sideband setting for the current channel.STATUS-CALL-ACK:<channel number>,<ID of other station>,<your ID>,<time of call>,“<message>”You received an acknowledgment to your status call.STATUSCALL:<channel number>,<ID of other station>,<your ID>,<time of call>,“<message>”You received a user status call.STATUSTIME:<timeout>Response to a STATUSTIME?command showing you the status call reply timeout in seconds.CICS:V<version number>Response to VER? command showing you the command set version number (for example,V2.00).。

普思特p-608说明书摘要：1.普思特p-608 产品概述2.普思特p-608 主要功能与特点3.安装与使用普思特p-6084.普思特p-608 的维护与保养5.产品技术支持与联系方式正文：一、普思特p-608 产品概述普思特p-608 是一款性能卓越的知识类写作助手，旨在帮助用户高效地完成各类写作任务。

该产品采用了先进的自然语言处理技术，能够快速理解用户需求并生成高质量的文本。

二、普思特p-608 主要功能与特点1.快速生成文本：普思特p-608 能够根据用户输入的关键词或主题，迅速生成相应的文章、报告等文本。

2.丰富的写作模板：普思特p-608 内置了多种写作模板，涵盖了学术论文、商业报告、新闻报道等不同领域，方便用户快速完成写作任务。

3.强大的语言处理能力：普思特p-608 具备优秀的语言理解与生成能力，能够根据用户需求生成符合语法、逻辑和语义的文本。

4.自动化排版：普思特p-608 可以根据用户需求自动排版，生成的文章、报告等文本格式整齐、美观。

三、安装与使用普思特p-6081.下载并安装普思特p-608 软件：用户可以从官方网站下载软件，按照提示完成安装。

2.启动普思特p-608：安装完成后，用户可以双击软件图标启动普思特p-608。

3.输入写作任务：在普思特p-608 界面中，用户可以输入关键词或主题，选择合适的写作模板，即可开始生成文本。

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四、普思特p-608 的维护与保养1.定期更新软件：为了确保普思特p-608 能够更好地运行，用户应定期查看软件更新，并按照提示完成更新。

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五、产品技术支持与联系方式1.技术支持：普思特p-608 提供在线技术支持服务，用户遇到问题可以随时联系技术支持团队。

SIMATICET 200SPTM Count 1x24V(6ES7138‑6AA01‑0BA0) 工艺模块设备手册Siemens AG Division Digital Factory Postfach 48 48 90026 NÜRNBERG A5E33002343-ADⓅ05/2019 本公司保留更改的权利Copyright © Siemens AG 2019.保留所有权利法律资讯警告提示系统为了您的人身安全以及避免财产损失，必须注意本手册中的提示。

人身安全的提示用一个警告三角表示，仅与财产损失有关的提示不带警告三角。

警告提示根据危险等级由高到低如下表示。

危险表示如果不采取相应的小心措施，将会导致死亡或者严重的人身伤害。

警告表示如果不采取相应的小心措施，可能导致死亡或者严重的人身伤害。

小心表示如果不采取相应的小心措施，可能导致轻微的人身伤害。

注意表示如果不采取相应的小心措施，可能导致财产损失。

当出现多个危险等级的情况下，每次总是使用最高等级的警告提示。

如果在某个警告提示中带有警告可能导致人身伤害的警告三角，则可能在该警告提示中另外还附带有可能导致财产损失的警告。

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With VibePro 8IPAD VIBRATION ANALYSIS WITH VIBEPRO 8 // 2NEW IN VIBEPRO 8• TWF collection and on-screen analysis •FFT in Acceleration and integrated FFT in Velocity and Displacement (available on iPad and VibePro Online)• TWF and Spectrum in same view • High-frequency impact demodulation (available on iPad and VibePro Online)• Selection of sample rate (Fmax)and number of samples (lines of resolution)• Additional windowing options: hemming, hamming and blackman• Circular TWF plots for gearbox analysis • Waterfall plot for selected measurements •Vibration trending in acceleration/Velocity for RMS, Peak & Crest Factor Values• Editing Functions in Route • Allows: deleting, duplication, and renaming route data • Machine Point Library• Change Sensors Quickly with Calibration Presets•TWF Capture and AnalysisFEATURES• Real Time Spectrum Analysis• Single measurement reports with easy email sharing• Recorded readings for post processing • Routes have never been easier with VibePro.• Import and export routes via GTI Cloud, Files app, email and other options • Automatic and manual markers on the spectrum• Set RPM and bearing makers with multiples • Full FFT Signature graph from 0 to 20khz or 0 to 1.2 million CPM • Spectrum Frequency Resolution from 0.17Hz to 10.77Hz•Selectable Fmax of 22,050Hz, 11,025Hz, 5,512Hz and 2,756Hz•Selectable number of samples of 4,096, 8,192, 16,384 and 32,768VIBEPROIs a powerful machine vibration analyzer app for iPad/iOS. Coupled with GTI sensor equipment, it can be an invaluable tool for measuringvibration and health of a wide variety of machine parts including motors, bearings, spindles, shaft imbalance, gears, belt wear and more. The app can be used for single readings or full vibration analysis routes, documenting trends along the way. Route data can be processed directly in VibePro, GTI’s web app or other platforms available for Windows and MacOS.The contents of this publication are the copyright of the publisher and may not be reproduced (even extracts) unless prior writtenpermission is granted. Every care has been taken to ensure the accuracy of the information contained in this publication but no liability canbe accepted for any loss or damage whether direct, indirect or consequential arising out of the use of the information contained herein.888.473.9675 // 33 Zachary Road // Manchester, NH GTI HEATMAP:A custom vibration degradationalgorithm developed by GTI brings a new visualization tool to the health of a plant’s assets.The larger the box the faster that asset is degrading. GTI HeatMap for the first time provides an accurate look at a plant’s health. Green assets that are rapidly failing will show up well before an emergency repair is needed. GTI HeatMap can also be a helpful tool to ensure thresholds are being properly setup.FULL HIERARCHY VIEW WITHWATERFALL, TREND CHARTS, ANDSPECTRUM ANALYSIS WITH REPORTING:View the same route hierarchy that is used with VibePro for iPad. Full reporting is available for any reading captured with VibePro. Trend charts or waterfall view to see data trends. TWF analysis is also available.VIBEPULSE:A custom vibration signature recognition algorithmdeveloped by GTI brings a new fault detection technology not offered elsewhere. The fault detection algorithm will provide a good starting point for your technicians to fix the asset and return it back to normal vibration levels.VIBEPRO ONLINE: POST PROCESSINGSINGLE-MEASUREMENTSROUTE MEASUREMENTSVIBEPRO 8 IPAD VIBRATION ANALYSISFull Spectrum Email and Printer Friendly ReportsCreate, Edit and Manage RoutesCustom Options for MeasurementCapture Route Vibration DataView Plant Status Review Past Readings View Trending DataView and Create Maintenance。

DDC, DBV PACKAGE(Top View)SWGNDFBV INENGND SWV IN NCEN FB321456DRV PACKAGE(Top View)70727476788082848688900.1110100EFFICIENCYvsOUTPUT CURRENTI O − Output Current − mAEfficiency−%L1FV OUTV IN to 28 VV IN1.8 V to 6 VC4.7 µTPS61040TPS61041 SLVS413F–OCTOBER2002–REVISED DECEMBER2010 LOW-POWER DC/DC BOOST CONVERTER IN SOT-23AND SON PACKAGESCheck for Samples:TPS61040,TPS61041FEATURES DESCRIPTION• 1.8-V to6-V Input Voltage Range The TPS61040/41is a high-frequency boostconverter dedicated for small to medium LCD bias •Adjustable Output Voltage Range up to28Vsupply and white LED backlight supplies.The device •400-mA(TPS61040)and250-mA(TPS61041)is ideal to generate output voltages up to28V from a Internal Switch Currentdual cell NiMH/NiCd or a single cell Li-Ion battery.•Up to1-MHz Switching Frequency The part can also be used to generate standard3.3-V/5-V to12-V power conversions.•28-m A Typical No-Load Quiescent Current•1-m A Typical Shutdown Current The TPS61040/41operates with a switchingfrequency up to1MHz.This allows the use of small •Internal Soft Startexternal components using ceramic as well as •Available in SOT23-5,TSOT23-5,tantalum output capacitors.Together with the thin and2×2×0.8-mm SON Packages SON package,the TPS61040/41gives a very smalloverall solution size.The TPS61040has an internal APPLICATIONS400mA switch current limit,while the TPS61041has•LCD Bias Supply a250-mA switch current limit,offering lower outputvoltage ripple and allows the use of a smaller form •White-LED Supply for LCD Backlightsfactor inductor for lower power applications.The low •Digital Still Cameraquiescent current(typically28m A)together with an •PDAs,Organizers,and Handheld PCs optimized control scheme,allows device operation at •Cellular Phones very high efficiencies over the entire load currentrange.•Internet Audio Player•Standard3.3-V/5-V to12-V ConversionTYPICAL APPLICATIONPlease be aware that an important notice concerning availability,standard warranty,and use in critical applications of TexasInstruments semiconductor products and disclaimers thereto appears at the end of this data sheet.PRODUCTION DATA information is current as of publication date.Copyright©2002–2010,Texas Instruments Incorporated Products conform to specifications per the terms of the TexasVINFBENTPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010This integrated circuit can be damaged by ESD.Texas Instruments recommends that all integrated circuits be handled with appropriate precautions.Failure to observe proper handling and installation procedures can cause damage.ESD damage can range from subtle performance degradation to complete device failure.Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.Table 1.ORDERING INFORMATION(1)SWITCH CURRENTPACKAGE T APART NUMBER (2)PACKAGE LIMIT,mAMARKING TPS61040DBV 400SOT23-5PHOI TPS61040DDC400TSOT23-5QXK –40°C to TPS61041DBV 250SOT23-5PHPI 85°CTPS61040DRV 400SON-62×2CCL TPS61041DRV250SON-62×2CAW(1)For the most current package and ordering information,see the Package Option Addendum at the end of this document,or see the TI website at .(2)The devices are available in tape and reel and in tubes.Add R suffix to the part number (e.g.,TPS61040DRVR)to order quantities of 3000parts in tape and reel or add suffix T (e.g.,TPS61040DRVT)to order a tube with 250pieces..FUNCTIONAL BLOCK DIAGRAM2Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments IncorporatedI peak(typ)+I LIM)V INL100nsI peak(typ)+400mA)V INL100ns for the TPS61040I peak(typ)+250mA)V INL100ns for the TPS61041TPS61040TPS61041 SLVS413F–OCTOBER2002–REVISED DECEMBER2010Table2.Terminal FunctionsTERMINALI/O DESCRIPTIONDDC,NAME DRV NO.DBV NO.This is the enable pin of the device.Pulling this pin to ground forces the device into shutdownEN43I mode reducing the supply current to less than1m A.This pin should not be left floating and needsto be terminated.This is the feedback pin of the device.Connect this pin to the external voltage divider to program FB34Ithe desired output voltage.GND21–GroundNC–5–No connectionConnect the inductor and the Schottky diode to this pin.This is the switch pin and is connected to SW16Ithe drain of the internal power MOSFET.V IN52I Supply voltage pinDETAILED DESCRIPTIONOPERATIONThe TPS61040/41operates with an input voltage range of1.8V to6V and can generate output voltages up to 28V.The device operates in a pulse-frequency-modulation(PFM)scheme with constant peak current control. This control scheme maintains high efficiency over the entire load current range,and with a switching frequency up to1MHz,the device enables the use of very small external components.The converter monitors the output voltage,and as soon as the feedback voltage falls below the reference voltage of typically1.233V,the internal switch turns on and the current ramps up.The switch turns off as soon as the inductor current reaches the internally set peak current of typically400mA(TPS61040)or250mA(TPS61041). See the Peak Current Control section for more information.The second criteria that turns off the switch is the maximum on-time of6m s(typical).This is just to limit the maximum on-time of the converter to cover for extreme conditions.As the switch is turned off the external Schottky diode is forward biased delivering the current to the output.The switch remains off for a minimum of400ns(typical),or until the feedback voltage drops below the reference voltage ing this PFM peak current control scheme the converter operates in discontinuous conduction mode(DCM)where the switching frequency depends on the output current,which results in very high efficiency over the entire load current range.This regulation scheme is inherently stable,allowing a wider selection range for the inductor and output capacitor.PEAK CURRENT CONTROLThe internal switch turns on until the inductor current reaches the typical dc current limit(I LIM)of400mA (TPS61040)or250mA(TPS61041).Due to the internal propagation delay of typical100ns,the actual current exceeds the dc current limit threshold by a small amount.The typical peak current limit can be calculated:(1) The higher the input voltage and the lower the inductor value,the greater the peak.By selecting the TPS61040or TPS61041,it is possible to tailor the design to the specific application current limit requirements.A lower current limit supports applications requiring lower output power and allows the use of an inductor with a lower current rating and a smaller form factor.A lower current limit usually has a lower output voltage ripple as well.Copyright©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback3I LIM4I LIM 2TPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010SOFT STARTAll inductive step-up converters exhibit high inrush current during start-up if no special precaution is made.This can cause voltage drops at the input rail during start up and may result in an unwanted or early system shut down.The TPS61040/41limits this inrush current by increasing the current limit in two steps starting fromfor 256cycles to for the next 256cycles,and then full current limit (see Figure 14).ENABLEPulling the enable (EN)to ground shuts down the device reducing the shutdown current to 1m A (typical).Because there is a conductive path from the input to the output through the inductor and Schottky diode,the output voltage is equal to the input voltage during shutdown.The enable pin needs to be terminated and should not be left ing a small external transistor disconnects the input from the output during shutdown as shown in Figure 18.UNDERVOLTAGE LOCKOUTAn undervoltage lockout prevents misoperation of the device at input voltages below typical 1.5V.When the input voltage is below the undervoltage threshold,the main switch is turned off.THERMAL SHUTDOWNAn internal thermal shutdown is implemented and turns off the internal MOSFETs when the typical junction temperature of 168°C is exceeded.The thermal shutdown has a hysteresis of typically 25°C.This data is based on statistical means and is not tested during the regular mass production of the IC.ABSOLUTE MAXIMUM RATINGSover operating free-air temperature (unless otherwise noted)(1)UNIT Supply voltages on pin V IN (2)–0.3V to 7V Voltages on pins EN,FB (2)–0.3V to V IN +0.3VSwitch voltage on pin SW(2)30VContinuous power dissipation See Dissipation Rating TableT J Operating junction temperature –40°C to 150°C T stg Storage temperature–65°C to 150°C(1)Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device.These are stress ratings only,and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied.Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.(2)All voltage values are with respect to network ground terminal.DISSIPATION RATING TABLEDERATING T A ≤25°C FACTOR T A =70°C T A =85°C PACKAGE R q JA POWER RATINGABOVE POWER RATINGPOWER RATINGT A =25°C DBV 250°C/W 357mW 3.5mW/°C 192mW 140mW DDC,DRV76°C/W1300mW13mW/°C688mW500mW4Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments IncorporatedTPS61040TPS61041 SLVS413F–OCTOBER2002–REVISED DECEMBER2010 RECOMMENDED OPERATING CONDITIONSMIN TYP MAX UNIT V IN Input voltage range 1.86VV OUT Output voltage range28VL Inductor(1) 2.210m Hf Switching frequency(1)1MHzC IN Input capacitor(1) 4.7m FC OUT Output capacitor(1)1m FT A Operating ambient temperature–4085°CT J Operating junction temperature–40125°C (1)See application section for further information.ELECTRICAL CHARACTERISTICSV IN=2.4V,EN=V IN,T A=–40°C to85°C,typical values are at T A=25°C(unless otherwise noted)PARAMETER TEST CONDITIONS MIN TYP MAX UNIT SUPPLY CURRENTV IN Input voltage range 1.86VI Q Operating quiescent current I OUT=0mA,not switching,V FB=1.3V2850m AI SD Shutdown current EN=GND0.11m AV UVLO Under-voltage lockout threshold 1.5 1.7V ENABLEV IH EN high level input voltage 1.3VV IL EN low level input voltage0.4VI I EN input leakage current EN=GND or V IN0.11m A POWER SWITCH AND CURRENT LIMITVsw Maximum switch voltage30Vt off Minimum off time250400550nst on Maximum on time467.5m sR DS(on)MOSFET on-resistance V IN=2.4V;I SW=200mA;TPS610406001000mΩR DS(on)MOSFET on-resistance V IN=2.4V;I SW=200mA;TPS610417501250mΩMOSFET leakage current V SW=28V110m AI LIM MOSFET current limit TPS61040350400450mAI LIM MOSFET current limit TPS61041215250285mA OUTPUTV OUT Adjustable output voltage range V IN28VV ref Internal voltage reference 1.233VI FB Feedback input bias current V FB=1.3V1m AV FB Feedback trip point voltage 1.8V≤V IN≤6V 1.208 1.233 1.258V1.8V≤V IN≤6V;V OUT=18V;I load=10mA;Line regulation(1)0.05%/VC FF=not connectedLoad regulation(1)V IN=2.4V;V OUT=18V;0mA≤I OUT≤30mA0.15%/mA (1)The line and load regulation depend on the external component selection.See the application section for further information.Copyright©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback5E f f i c i e n c y − %70727476788082848688900.1110100I O − Output Current − mA70727476788082848688900.1110100I L − Load Current − mAE f f i c i e n c y − %TPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010TYPICAL CHARACTERISTICSTable 3.Table of GraphsFIGUREvs Load current 1,2,3h Efficiency vs Input voltage4I Q Quiescent current vs Input voltage and temperature 5V FB Feedback voltage vs Temperature 6I SW Switch current limit vs Temperature7vs Supply voltage,TPS610418I CL Switch current limit vs Supply voltage,TPS610409vs Temperature 10R DS(on)R DS(on)vs Supply voltage11Line transient response 12Load transient response 13Start-up behavior14EFFICIENCYEFFICIENCYvsvsOUTPUT CURRENTLOAD CURRENTFigure 1.Figure 2.6Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments IncorporatedI L − Load Current − mAE f f i c i e n c y − %V I − Input Voltage − VE f f i c i e n c y −%T A − Temperature − °CV F B − F e e d b a c k V o l t a g e − VV I − Input Voltage − VQ u i e s c e n t C u r r e n t − µATPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010EFFICIENCYEFFICIENCYvsvsLOAD CURRENTINPUT VOLTAGEFigure 3.Figure 4.TPS61040QUIESCENT CURRENTFEEDBACK VOLTAGEvsvsFigure 5.Figure 6.Copyright ©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback 7T A − Temperature − °CI (S W ) − S w i t c h C u r r e n t L i m i t − mAV CC − Supply Voltage − VI (C L ) − C u r r e n t L i m i t − m AT A − Temperature − °Cr D S (o n ) − S t a t i c D r a i n -S o u r c e O n -S t a t e R e s i s t a nc e − m ΩV CC − Supply Voltage − VI (C L ) − C u r r e n t L i m i t − m ATPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010TPS61040/41TPS61041SWITCH CURRENT LIMITCURRENT LIMITvsvsFREE-AIR TEMPERATURESUPPLY VOLTAGEFigure 7.Figure 8.TPS61040TPS61040/41CURRENT LIMITSTATIC DRAIN-SOURCE ON-STATE RESISTANCEvsvsSUPPLY VOLTAGEFREE-AIR TEMPERATUREFigure 9.Figure 10.8Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments IncorporatedV I2.4 V to3.4 VV O100 mV/div 200 µS/divV O = 18 VV CC − Supply Voltage − Vr D S (o n ) − S t a t i c D r a i n -S o u r c e O n -S t a t e R e s i s t a n c e − m ΩV O 5 V/div EN 1 V/divI I50 mA/divV O = 18 VV O1 mA to 10 mA200 µS/divV O100 mA/divV O = 18 VTPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010TPS61040/41STATIC DRAIN-SOURCE ON-STATE RESISTANCEvsSUPPLY VOLTAGEFigure 11.Figure 12.Line Transient ResponseFigure 13.Load Transient Response Figure 14.Start-Up BehaviorCopyright ©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback 9fS max+V IN(min)(V OUT*V IN)I P L V OUTfSǒI loadǓ+2I load(V OUT*V IN)Vd)I2PLI load max+hI2PL fS max 2(V OUT*V IN)TPS61040TPS61041SLVS413F–OCTOBER2002–REVISED APPLICATION INFORMATIONINDUCTOR SELECTION,MAXIMUM LOAD CURRENTBecause the PFM peak current control scheme is inherently stable,the inductor value does not affect the stability of the regulator.The selection of the inductor together with the nominal load current,input and output voltage of the application determines the switching frequency of the converter.Depending on the application,inductor values between2.2m H and47m H are recommended.The maximum inductor value is determined by the maximum on time of the switch,typically6m s.The peak current limit of400mA/250mA(typically)should be reached within this6-m s period for proper operation.The inductor value determines the maximum switching frequency of the converter.Therefore,select the inductor value that ensures the maximum switching frequency at the converter maximum load current is not exceeded. The maximum switching frequency is calculated by the following formula:Where:I P=Peak current as described in the Peak Current Control sectionL=Selected inductor valueV IN(min)=The highest switching frequency occurs at the minimum input voltage(2) If the selected inductor value does not exceed the maximum switching frequency of the converter,the next step is to calculate the switching frequency at the nominal load current using the following formula:Where:I P=Peak current as described in the Peak Current Control sectionL=Selected inductor valueI load=Nominal load currentVd=Rectifier diode forward voltage(typically0.3V)(3) A smaller inductor value gives a higher converter switching frequency,but lowers the efficiency.The inductor value has less effect on the maximum available load current and is only of secondary order.The best way to calculate the maximum available load current under certain operating conditions is to estimate the expected converter efficiency at the maximum load current.This number can be taken out of the efficiency graphs shown in Figure1through Figure4.The maximum load current can then be estimated as follows:Where:I P=Peak current as described in the Peak Current Control sectionL=Selected inductor valuefS max=Maximum switching frequency as calculated previouslyh=Expected converter efficiency.Typically70%to85%(4) 10Submit Documentation Feedback Copyright©2002–2010,Texas Instruments IncorporatedV OUT+1.233Vǒ1)R1R2ǓC FF+12p fS20R1TPS61040TPS61041 SLVS413F–OCTOBER2002–REVISED DECEMBER2010 The maximum load current of the converter is the current at the operation point where the converter starts to enter the continuous conduction ually the converter should always operate in discontinuous conduction mode.Last,the selected inductor should have a saturation current that meets the maximum peak current of the converter(as calculated in the Peak Current Control section).Use the maximum value for I LIM for this calculation. Another important inductor parameter is the dc resistance.The lower the dc resistance,the higher the efficiency of the converter.See Table4and the typical applications for the inductor selection.Table4.Recommended Inductor for Typical LCD Bias Supply(see Figure15)DEVICE INDUCTOR VALUE COMPONENT SUPPLIER COMMENTS10m H Sumida CR32-100High efficiency10m H Sumida CDRH3D16-100High efficiencyTPS6104010m H Murata LQH4C100K04High efficiency4.7m H Sumida CDRH3D16-4R7Small solution size4.7m H Murata LQH3C4R7M24Small solution sizeHigh efficiencyTPS6104110m H Murata LQH3C100K24Small solution sizeSETTING THE OUTPUT VOLTAGEThe output voltage is calculated as:(5) For battery-powered applications,a high-impedance voltage divider should be used with a typical value for R2of ≤200kΩand a maximum value for R1of2.2MΩ.Smaller values might be used to reduce the noise sensitivity of the feedback pin.A feedforward capacitor across the upper feedback resistor R1is required to provide sufficient overdrive for the error comparator.Without a feedforward capacitor,or one whose value is too small,the TPS61040/41shows double pulses or a pulse burst instead of single pulses at the switch node(SW),causing higher output voltage ripple.If this higher output voltage ripple is acceptable,the feedforward capacitor can be left out.The lower the switching frequency of the converter,the larger the feedforward capacitor value required.A good starting point is to use a10-pF feedforward capacitor.As a first estimation,the required value for the feedforward capacitor at the operation point can also be calculated using the following formula:Where:R1=Upper resistor of voltage dividerfS=Switching frequency of the converter at the nominal load current(See the Inductor Selection,Maximum Load Current section for calculating the switching frequency)C FF=Choose a value that comes closest to the result of the calculation(6) Copyright©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback11D V out+I outC outǒ1fS(Iout)–I P LVout)Vd–VinǓ)I P ESRTPS61040TPS61041SLVS413F–OCTOBER2002–REVISED The larger the feedforward capacitor the worse the line regulation of the device.Therefore,when concern for line regulation is paramount,the selected feedforward capacitor should be as small as possible.See the following section for more information about line and load regulation.LINE AND LOAD REGULATIONThe line regulation of the TPS61040/41depends on the voltage ripple on the feedback ually a50mV peak-to-peak voltage ripple on the feedback pin FB gives good results.Some applications require a very tight line regulation and can only allow a small change in output voltage over a certain input voltage range.If no feedforward capacitor C FF is used across the upper resistor of the voltage feedback divider,the device has the best line regulation.Without the feedforward capacitor the output voltage ripple is higher because the TPS61040/41shows output voltage bursts instead of single pulses on the switch pin (SW),increasing the output voltage ripple.Increasing the output capacitor value reduces the output voltage ripple.If a larger output capacitor value is not an option,a feedforward capacitor C FF can be used as described in the previous section.The use of a feedforward capacitor increases the amount of voltage ripple present on the feedback pin(FB).The greater the voltage ripple on the feedback pin(≥50mV),the worse the line regulation. There are two ways to improve the line regulation further:e a smaller inductor value to increase the switching frequency which will lower the output voltage ripple,as well as the voltage ripple on the feedback pin.2.Add a small capacitor from the feedback pin(FB)to ground to reduce the voltage ripple on the feedback pindown to50mV again.As a starting point,the same capacitor value as selected for the feedforward capacitorC FF can be used.OUTPUT CAPACITOR SELECTIONFor best output voltage filtering,a low ESR output capacitor is recommended.Ceramic capacitors have a low ESR value but tantalum capacitors can be used as well,depending on the application.Assuming the converter does not show double pulses or pulse bursts on the switch node(SW),the output voltage ripple can be calculated as:where:I P=Peak current as described in the Peak Current Control sectionL=Selected inductor valueI out=Nominal load currentfS(I out)=Switching frequency at the nominal load current as calculated previouslyVd=Rectifier diode forward voltage(typically0.3V)C out=Selected output capacitorESR=Output capacitor ESR value(7) See Table5and the typical applications section for choosing the output capacitor.Table5.Recommended Input and Output CapacitorsDEVICE CAPACITOR VOLTAGE RATING COMPONENT SUPPLIER COMMENTS4.7m F/X5R/0805 6.3V Tayo Yuden JMK212BY475MG C IN/C OUT10m F/X5R/0805 6.3V Tayo Yuden JMK212BJ106MG C IN/C OUT TPS61040/411m F/X7R/120625V Tayo Yuden TMK316BJ105KL C OUT1m F/X5R/120635V Tayo Yuden GMK316BJ105KL C OUT4.7m F/X5R/121025V Tayo Yuden TMK325BJ475MG C OUT12Submit Documentation Feedback Copyright©2002–2010,Texas Instruments IncorporatedV O V INC TPS61040 TPS61041 SLVS413F–OCTOBER2002–REVISED DECEMBER2010 INPUT CAPACITOR SELECTIONFor good input voltage filtering,low ESR ceramic capacitors are recommended.A4.7m F ceramic input capacitor is sufficient for most of the applications.For better input voltage filtering this value can be increased.See Table5 and typical applications for input capacitor recommendations.DIODE SELECTIONTo achieve high efficiency a Schottky diode should be used.The current rating of the diode should meet the peak current rating of the converter as it is calculated in the Peak Current Control e the maximum value for I LIM for this calculation.See Table6and the typical applications for the selection of the Schottky diode.Table6.Recommended Schottky Diode for Typical LCD Bias Supply(see Figure15) DEVICE REVERSE VOLTAGE COMPONENT SUPPLIER COMMENTS30V ON Semiconductor MBR053020V ON Semiconductor MBR0520TPS61040/4120V ON Semiconductor MBRM120L High efficiency30V Toshiba CRS02LAYOUT CONSIDERATIONSTypical for all switching power supplies,the layout is an important step in the design;especially at high peak currents and switching frequencies.If the layout is not carefully done,the regulator might show noise problems and duty cycle jitter.The input capacitor should be placed as close as possible to the input pin for good input voltage filtering.The inductor and diode should be placed as close as possible to the switch pin to minimize the noise coupling into other circuits.Because the feedback pin and network is a high-impedance circuit,the feedback network should be routed away from the inductor.The feedback pin and feedback network should be shielded with a ground plane or trace to minimize noise coupling into this circuit.Wide traces should be used for connections in bold as shown in Figure15.A star ground connection or ground plane minimizes ground shifts and noise.yout DiagramCopyright©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback13L1D1V OUT 18 VV IN1.8 V to 6 VC14.7 µFL1:Sumida CR32-100D1:Motorola MBR0530C1:Tayo Yuden JMK212BY475MG C2:Tayo Yuden TMK316BJ105KLL1D1V IN1.8 V to 6 V4.7 DAC or Analog Voltage 0 V = 25 V 1.233 V = 18 V Sumida CR32-100Motorola MBR0530Tayo Yuden JMK212BY475MG C2:Tayo Yuden GMK316BJ105KLV OUT18 V / 10 mAV IN1.8 V to 6 V4.7 µR3200 k WµF Sumida CR32-100Motorola MBR0530Tayo Yuden JMK212BY475MG Tayo Yuden TMK316BJ105KLTPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010Figure 16.LCD Bias SupplyFigure 17.LCD Bias Supply With Adjustable Output VoltageFigure 18.LCD Bias Supply With Load Disconnect14Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments IncorporatedV IN = 2.7 V to 5 VC14.7 µFV2 = –10 V/15 mAMurata LQH4C6R8M04Motorola MBR0530Tayo Yuden JMK212BY475MG Tayo Yuden EMK316BJ105KFL1D1µFV O = 12 V/35 mAV IN 3.3 V10 µL1:Murata LQH4C6R8M04D1:Motorola MBR0530C1:Tayo Yuden JMK212BJ106MG C2:Tayo Yuden EMK316BJ475MLµF5 V/45 mA1.8 V to 4 V4.7 L1:Murata LQH4C3R3M04D1:Motorola MBR0530C1, C2:Tayo Yuden JMK212BY475MGTPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010Figure 19.Positive and Negative Output LCD Bias SupplyFigure 20.Standard 3.3-V to 12-V SupplyFigure 21.Dual Battery Cell to 5-V/50-mA ConversionEfficiency Approx.Equals 84%at V IN =2.4V to Vo =5V/45mACopyright ©2002–2010,Texas Instruments Incorporated Submit Documentation Feedback 15L1V CCPWM100 Hz to 500 HzL1:Murata LQH4C100K04D1:Motorola MBR0530C1:Tayo Yuden JMK212BY475MG C2:Tayo Yuden TMK316BJ105KLL1D14.7 µV CC = 2.7 V to 6 V160 k Ω0 V ≅ Iled = 20 mAL1:Murata LQH4C3R3M04D1:Motorola MBR0530C1:Tayo Yuden JMK212BY475MG C2:Standard Ceramic CapacitorTPS61040TPS61041SLVS413F –OCTOBER 2002–REVISED DECEMBER 2010Figure 22.White LED Supply With Adjustable Brightness ControlUsing a PWM Signal on the Enable Pin,Efficiency Approx.Equals 86%at V IN =3V,I LED =15mAA.A smaller output capacitor value for C2causes a larger LED ripple.Figure 23.White LED Supply With Adjustable Brightness ControlUsing an Analog Signal on the Feedback Pin16Submit Documentation Feedback Copyright ©2002–2010,Texas Instruments Incorporated。

DSP56F826/DRev. # 0, 3/2001 Semiconductor Products SectorDSP56F826 Preliminary Technical DataDSP56F826 16-bit Digital Signal Processor•Up to 40 MIPS at 80MHz core frequency •DSP and MCU functionality in a unified, C-efficient architecture•Hardware DO and REP loops•MCU-friendly instruction set supports both DSP and controller functions: MAC, bitmanipulation unit, 14 addressing modes •31.5K × 16-bit words Program Flash •512 × 16-bit words Program RAM•2K × 16-bit words Data Flash•4K × 16-bit words Data RAM•2K × 16-bit words BootFLASH •Up to 64K × 16-bit words each of external memory expansion for Program and Datamemory•One Serial Port Interface (SPI)•One additional SPI or two optional Serial Communication Interfaces (SCI)•One Synchronous Serial Interface (SSI)•One General Purpose Quad Timer •JTAG/OnCE™ for debugging•100-pin LQFP Package•16 dedicated and 30 shared GPIO•One Time-of-Day moduleFigure1. DSP56F826 Block DiagramPart 1 Overview1.1 DSP56F826 Features1.1.1Digital Signal Processing Core•Efficient 16-bit DSP56800 Family DSP engine with dual Harvard architecture•As many as 40 Million Instructions Per Second (MIPS) at 80MHz core frequency•Single-cycle 16 × 16-bit parallel Multiplier-Accumulator (MAC)•Two 36-bit accumulators, including extension bits•16-bit bidirectional barrel shifter•Parallel instruction set with unique DSP addressing modes•Hardware DO and REP loops•Three internal address buses and one external address bus•Four internal data buses and one external data bus•Instruction set supports both DSP and controller functions•Controller style addressing modes and instructions for compact code•Efficient C Compiler and local variable support•Software subroutine and interrupt stack with depth limited only by memory•JTAG/OnCE Debug Programming Interface1.1.2Memory•Harvard architecture permits as many as three simultaneous accesses to program and data memory •On-chip memory including a low cost, high volume flash solution—31.5K × 16-bit words of Program Flash—512× 16-bit words of Program RAM—2K × 16-bit words of Data Flash—4K × 16-bit words of Data RAM—2K × 16-bit words of BootFLASH•Off-chip memory expansion capabilities programmable for 0, 4, 8, or 12 wait states —As much as 64 K × 16-bit data memory—As much as 64 K × 16-bit program memory1.1.3Peripheral Circuits for DSP56F826•One General Purpose Quad Timer totalling 7pins•One Serial Peripheral Interface with 4 pins (or four additional GPIO lines)•One Serial Peripheral Interface, or multiplexed with two Serial Communications Interfaces totalling4 pins•Synchronous Serial Interface (SSI) with configurable six-pin port (or six additional GPIO lines)DSP56F826 Description•Sixteen (16) dedicated general purpose I/O (GPIO) pins•Thirty (30) shared general purpose I/O (GPIO) pins•Computer-Operating Properly (COP) Watchdog timer•Two external interrupt pins•External reset pin for hardware reset•JTAG/On-Chip Emulation (OnCE™) for unobtrusive, processor speed-independent debugging •Software-programmable, Phase Lock Loop-based frequency synthesizer for the DSP core clock •Fabricated in high-density EMOS with 5V tolerant, TTL-compatible digital inputs•One Time of Day moduleEnergy Information•Dual power supply, 3.3V and 2.5V•Wait and Multiple Stop modes available1.2 DSP56F826 DescriptionThe DSP56F826 is a member of the DSP56800 core-based family of Digital Signal Processors (DSPs). It combines, on a single chip, the processing power of a DSP and the functionality of a microcontroller with a flexible set of peripherals to create an extremely cost-effective solution for general purpose applications. Because of its low cost, configuration flexibility, and compact program code, the DSP56F826 is well-suited for many applications. The DSP56F826 includes many peripherals that are especially useful for applications such as: noise suppression, ID tag readers, sonic/subsonic detectors, security access devices, remote metering, sonic alarms, POS terminals, feature phones.The DSP56800 core is based on a Harvard-style architecture consisting of three execution units operating in parallel, allowing as many as six operations per instruction cycle. The microprocessor-style programming model and optimized instruction set allow straightforward generation of efficient, compact code for both DSP and MCU applications. The instruction set is also highly efficient for C/C++ Compilers to enable rapid development of optimized control applications.The DSP56F826 supports program execution from either internal or external memories. Two data operands can be accessed from the on-chip Data RAM per instruction cycle. The DSP56F826 also provides two external dedicated interrupt lines, and up to 46 General Purpose Input/Output (GPIO) lines, depending on peripheral configuration.The DSP56F826 DSP controller includes 31.5K words (16-bit) of Program Flash and 2K words of Data Flash (each programmable through the JTAG port) with 512 words of Program RAM, and 4K words of Data RAM. It also supports program execution from external memory.The DSP56F826 incorporates a total of 2K words of BootFLASH for easy customer-inclusion of field-programmable software routines that can be used to program the main Program and Data Flash memory areas. Both Program and Data Flash memories can be independently bulk-erased or erased in page sizes of 256 words. The BootFLASH memory can also be either bulk- or page-erased.This DSP controller also provides a full set of standard programmable peripherals including one Synchronous Serial Interface (SSI), one Serial Peripheral Interface (SPI), the option to select a second SPI or two Serial Communications Interfaces (SCIs), and one Quad Timer. The SSI, SPI, and quad timer can be used as General Purpose Input/Outputs (GPIOs) if a timer function is not required.1.3 Best in Class Development EnvironmentThe SDK (Software Development Kit) provides fully debugged peripheral drivers, libraries and interfaces that allow programmers to create their unique C application code independent of component architecture.The CodeWarrior Integrated Development Environment is a sophisticated tool for code navigation,compiling, and debugging. A complete set of evaluation modules (EVMs) and development system cards will support concurrent engineering. Together, the SDK, CodeWarrior, and EVMs create a complete,scalable tools solution for easy, fast, and efficient development.1.4 Product DocumentationThe four documents listed in Table 1 are required for a complete description and proper design with the DSP56F826. Documentation is available from local Motorola distributors, Motorola semiconductor sales offices, Motorola Literature Distribution Centers, or online at /semiconductors/.Table 1. DSP56F826 Chip Documentation1.5 Data Sheet ConventionsThis data sheet uses the following conventions:TopicDescriptionOrder NumberDSP56800Family Manual Detailed description of the DSP56800 family architecture, and 16-bit DSP core processor and the instruction set DSP56800FM/D DSP56824/F826/F827User’s Manual Detailed description of memory, peripherals, and interfaces of the DSP56824, DSP56F826, DSP56F827TBD DSP56F826Technical Data Sheet Electrical and timing specifications, pin descriptions, and package descriptions (this document)DSP56F826/D DSP56F826Product BriefSummary description and block diagram of the DSP56F826 core, memory, peripherals and interfacesDSP56F826PB/DOVERBAR This is used to indicate a signal that is active when pulled low. For example, the RESET pin is active when low.“asserted” A high true (active high) signal is high or a low true (active low) signal is low.“deasserted” A high true (active high) signal is low or a low true (active low) signal is high.Examples:Signal/SymbolLogic State Signal State Voltage 11.Values for VIL, VOL, VIH, and VOH are defined by individual product specifications.PIN True Asserted V IL /V OL PIN False Deasserted V IH /V OH PIN True Asserted V IH /V OH PINFalseDeassertedV IL /V OLIntroduction Part 2 Signal/Connection Descriptions2.1 IntroductionThe input and output signals of the DSP56F826 are organized into functional groups, as shown in Table2 and as illustrated in Figure2. In Table3 describes the signal or signals present on a pin.Table2. Functional Group Pin AllocationsFunctional Group Number of PinsPower (V DD , V DDIO or V DDA)(3,4,1)Ground (V SS , V SSIO or V SSA )(3,4,1)PLL and Clock3Address Bus116Data Bus16Bus Control4Interrupt and Program Control5Dedicated General Purpose Input/Output16Synchronous Serial Interface (SSI) Port6Serial Peripheral Interface (SPI) Port11.Alternately, GPIO pins 4Serial Communications Interface (SCI) Ports4 Quad Timer Module Ports4 JTAG/On-Chip Emulation (OnCE)6Figure 2. DSP56F826 Signals Identified by Functional Group 11.Alternate pin functionality is shown in parenthesis.DSP56F8262.5V Power Port Ground PortPLL and ClockExternal Address Bus or GPIO External Data BusExternal Bus ControlDedicatedGPIOSPI1 Port orGPIOSCI0 Port or SPI0 PortSCI1 Port or SPI0 PortV DD V SS V DDIO V SSIO V DDA V SSAEXTAL(CLOCKIN )XTAL CLKOA0-A15(GPIO/E0–E7,GPIOA0–A7)D0–D15PS DS RD WRTA0 (GPIOF0)TA1 (GPIOF1)TA2 (GPIOF2)TA3 (GPIOF3)TCK TMS TDI TDO TRST DEQuad Timer AJTAG/OnCE ™PortInterrupt/Program ControlGPIOB0–7GPIOD0–7SRD (GPIOC0)SRFS (GPIOC1)SRCK (GPIOC2)STD (GPIOC3)STFS (GPIOC4)STCK (GPIOC5)SCLK (GPIOF4)MOSI (GPIOF5)MISO (GPIOF6)SS (GPIOF7)TXD0 (SCLK0)RXD0 (MOSI0)TXD1 (MISO0)RXD1 (SS0)IRQA IRQB RESET EXTBOOT33816168SSI Port orGPIO44Ground PortAnalog Power Port (3.3V)3.3V Power Port Ground PortIntroductionTable 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.Type DescriptionA024Output Address Bus —A0–A7 specify the address for external program or data memory accesses.Port E GPIO —These eight General Purpose I/O (GPIO) pins can be individually programmed as input or output pins. After reset, the default state is Address Bus.A123Output A222Output A321Output A418Output A517Output A616Output A7GPIOE0–GPIOE715Output Input/OutputA814Output Address Bus —A8–A15 specify the address for external program or data memory accesses.Port A GPIO —These eight General Purpose I/O (GPIO) pins can be individually programmed as input or output pins.After reset, the default state is Address Bus.A913Output A1012Output A1111Output A1210Output A139Output A148Output A15GPIOA0–GPIOA77Output Input/OutputCLKO65OutputClock Output —This pin outputs a buffered clock signal. By programming the CLKO Select Register (SLKOSR), the user can select betweenoutputting a version of the signal applied to XTAL and a version of the DSP master clock at the output of the PLL. The clock frequency on this pin can be disabled by programming the CLKO Select Register (CLKOSR).D034Input/OutputData Bus — D0–D15 specify the data for external program or data memory accesses. D0–D15 are tri-stated when the external bus is inactive.D135D236D337D438D539D640D741D842D943D1044D1146D1247D1348D1449D1550DE 98Output Debug Event —DE provides a low pulse on recognized debug events.DS28OutputData Memory Select —DS is asserted low for external data memory access.Table 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.Type DescriptionIntroductionEXTALCLOCKIN 61InputInputExternal Crystal Oscillator Input —This input can be connected to an 4MHz external crystal. If a 4MHz or less external clock source is used, EXTAL can be used as the input and XTAL must not be connected. For more information, please refer to Section 3.5.2.External Clock Input —This input can be connected to an external 8MHz clock. For more information, please refer to Section 3.5.The input clock can be selected to provide the clock directly to the DSP core. This input clock can also be selected as input clock for the on-chip PLL. EXTBOOT 25InputExternal Boot —This input is tied to V DD to force device to boot from off-chip memory. Otherwise, it is tied to ground.GPIOB066Input or OutputPort B GPIO —These eight dedicated General Purpose I/O (GPIO) pins can be individually programmed as input or output pins.After reset, the default state is GPIO input.GPIOB167GPIOB268GPIOB369GPIOB470GPIOB571GPIOB672GPIOB773GPIOD074Input or OutputPort D GPIO —These eight dedicated GPIO pins can be individually programmed as an input or output pins. After reset, the default state is GPIO input.GPIOD175GPIOD276GPIOD377GPIOD478GPIOD579GPIOD682GPIOD783Table 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.TypeDescriptionIRQA32InputExternal Interrupt Request A —The IRQA input is a synchronized external interrupt request that indicates that an external device is requesting service. It can be programmed to be level-sensitive or negative-edge- triggered. If level-sensitive triggering is selected, an external pull up resistor is required for wired-OR operation.If the processor is in the Stop state and IRQA is asserted, the processor will exit the Stop state.IRQB33InputExternal Interrupt Request B —The IRQB input is an external interrupt request that indicates that an external device is requesting service. It can be programmed to be level-sensitive or negative-edge-triggered. If level-sensitive triggering is selected, an external pull up resistor is required for wired-OR operation.MISO GPIOF686Input/OutputInput/OutputSPI Master In/Slave Out (MISO)—This serial data pin is an input to a master device and an output from a slave device. The MISO line of a slave device is placed in the high-impedance state if the slave device is not selected.Port F GPIO —This General Purpose I/O (GPIO) pin can be individually programmed as input or output. After reset, the default state is MISO.MOSIGPIOF585Input/OutputInput/Output SPI Master Out/Slave In (MOSI)—This serial data pin is an output from a master device and an input to a slave device. The master device places data on the MOSI line a half-cycle before the clock edge that the slave device uses to latch the data.Port F GPIO —This General Purpose I/O (GPIO) pin can be individually programmed as input or output.PS 29Output Program Memory Select —PS is asserted low for external program memory access.RD26OutputRead Enable —RD is asserted during external memory read cycles. When RD is asserted low, pins D0–D15 become inputs and an external device is enabled onto the DSP data bus. When RD is deasserted high, the external data is latched inside the DSP. When RD is asserted, it qualifies the A0–A15, PS, and DS pins. RD can be connected directly to the OE pin of a Static RAM or ROM.Table 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.TypeDescriptionIntroduction RESET45Input Reset—This input is a direct hardware reset on the processor. When RESETis asserted low, the DSP is initialized and placed in the Reset state. A Schmitttrigger input is used for noise immunity. When the RESET pin is deasserted,the initial chip operating mode is latched from the external boot pin. Theinternal reset signal will be deasserted synchronous with the internal clocks,after a fixed number of internal clocks.To ensure complete hardware reset, RESET and TRST should be assertedtogether. The only exception occurs in a debugging environment when ahardware DSP reset is required and it is necessary not to reset the OnCE/JTAG module. In this case, assert RESET, but do not assert TRST.RXD0 MOSI096InputInput/OutputReceive Data (RXD0)— receive data inputSPI Master Out/Slave In—This serial data pin is an output from a masterdevice, and an input to a slave device. The master device places data on theMOSI line one half-cycle before the clock edge the slave device uses to latchthe data.After reset, the default state is SCI input.RXD1 SS092InputInputReceive Data (RXD1)— receive data inputSPI Slave Select—In maste mode, this pin is used to arbitrate multiplemasters. In slave mode, this pin is used to select the slave.After reset, the default state is SCI input.SCLK GPIOF484Input/OutputInput/OutputSPI Serial Clock—In master mode, this pin serves as an output, clockingslaved listeners. In slave mode, this pin serves as the data clock input.Port F GPIO—This General Purpose I/O (GPIO) pin can be individuallyprogrammed as input or output.After reset, the default state is SCLK.SRCK GPIOC253Input/OutputInput/OutputSSI Serial Receive Clock (STCK)—This bidirectional pin provides theserial bit rate clock for the Receive section of the SSI. The clock signal canbe continuous or gated and can be used by both the transmitter and receiverin synchronous mode.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capabilityof being individually programmed as input or output.After reset, the default state is GPIO input.Table3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled. Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.SignalNamePin No.Type DescriptionSRD GPIOC051Input/OutputInput/OutputSSI Receive Data (SRD)—This input pin receives serial data and transfersthe data to the SSI Receive Shift Receiver.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capabilityof being individually programmed as input or output.After reset, the default state is GPIO input.SRFS GPIOC152Input/ OutputInput/OutputSSI Serial Receive Frame Sync (SRFS)—This bidirectional pin is used bythe receive section of the SSI as frame sync I/O or flag I/O. The STFS can beused only by the receiver. It is used to synchronize data transfer and can bean input or an output.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capabilityof being individually programmed as input or output.After reset, the default state is GPIO input.SS GPIOF787InputInput/OutputSPI Slave Select—In master mode, this pin is used to arbitrate multiplemasters. In slave mode, this pin is used to select the slave.Port F GPIO—This General Purpose I/O (GPIO) pin can be individuallyprogrammed as input or output.After reset, the default state is SS.STCK GPIOC556Input/ OutputInput/OutputSSI Serial Transmit Clock (STCK)—This bidirectional pin provides theserial bit rate clock for the transmit section of the SSI. The clock signal canbe continuous or gated. It can be used by both the transmitter and receiver insynchronous mode.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capabilityof being individually programmed as input or output.After reset, the default state is GPIO input.STD GPIOC354OutputInput/OutputSSI Transmit Data (STD)—This output pin transmits serial data from theSSI Transmitter Shift Register.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capabilityof being individually programmed as input or output.After reset, the default state is GPIO input.Table3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled. Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.SignalNamePin No.Type DescriptionIntroductionSTFSGPIOC455InputInput/OutputSSI Serial Transmit Frame Sync (STFS)—This bidirectional pin is used by the Transmit section of the SSI as frame sync I/O or flag I/O. The STFS can be used by both the transmitter and receiver in synchronous mode. It is used to synchronize data transfer and can be an input or output pin.Port C GPIO—This is a General Purpose I/O (GPIO) pin with the capability of being individually programmed as input or output. After reset, the default state is GPIO input.TA0-3GPIOF0-GPIOF391Input/OutputInput/OutputTA0–3—Timer F Channels 0, 1, 2, and 3Port F GPIO —These four General Purpose I/O (GPIO) pins can be individually programmed as input or output. After reset, the default state is Quad Timer.908988TCS99TCS —This pin is reserved for factory use. It must be tied to V SS for normal use. In block diagrams, this pin is considered an additional V SS.TCK 100InputTest Clock Input —This input pin provides a gated clock to synchronize the test logic and shift serial data to the JTAG/OnCE port. The pin is connected internally to a pull-down resistor.TDI 2InputTest Data Input —This input pin provides a serial input data stream to the JTAG/OnCE port. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor.TDO 3OutputTest Data Output —This tri-statable output pin provides a serial output data stream from the JTAG/OnCE port. It is driven in the Shift-IR and Shift-DR controller states, and changes on the falling edge of TCK.TMS 1InputTest Mode Select Input —This input pin is used to sequence the JTAG TAP controller’s state machine. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor.TRST 4InputTest Reset —As an input, a low signal on this pin provides a reset signal to the JTAG TAP controller. To ensure complete hardware reset, TRST should be asserted whenever RESET is asserted. The only exception occurs in a debugging environment when a hardware DSP reset is required and it is necessary not to reset the JTAG/OnCE module. In this case, assert RESET, but do not assert TRST.Table 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.TypeDescriptionTXD0SCLK097Output Input/OutputTransmit Data (TXD0)—transmit data outputSPI Serial Clock—In master mode, this pin serves as an output, clocking slaved listeners. In slave mode, this pin serves as the data clock input. After reset, the default state is SCI output.TXD1MISO093Output Input/OutputTransmit Data (TXD1)—transmit data outputSPI Master In/Slave Out—This serial data pin is an input to a masterdevice and an output from a slave device. The MISO line of a slave device is placed in the high-impedance state if hte slave device is not selected.After reset, the default state is SCI output.V DD 20V DD Power —These pins provide power to the internal structures of the chip, and are generally connected to a 2.5V supply.V DD 64V DD V DD 94V DD V DDA 59V DDA Analog Power —This pin supplies an analog power source (generally 2.5V).V DDIO 5V DDIO Power —These pins provide power to the I/O structures of the chip, and are generally connected to a 3.3V supply.V DDIO 30V DDIO V DDIO 57V DDIO V DDIO 80V DDIO V SS 19V SS GND —These pins provide grounding for the internal structures of the chip. All should be attached to V SS.V SS 63V SS V SS 95V SS V SSA 60V SSA Analog Ground —This pin supplies an analog ground.V SSIO 6V SSIO GND In/Out —These pins provide grounding for the I/O ring on the chip.All should be attached to V SS.V SSIO 31V SSIO V SSIO 58V SSIO V SSIO81V SSIOTable 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.Type DescriptionIntroductionWR27OutputWrite Enable —WR is asserted during external memory write cycles. When WR is asserted low, pins D0–D15 become outputs and the DSP puts data on the bus. When WR is deasserted high, the external data is latched inside the external device. When WR is asserted, it qualifies the A0–A15, PS, and DS pins. WR can be connected directly to the WE pin of a Static RAM.XTAL 62OutputCrystal Oscillator Output —This output connects the internal crystal oscillator output to an external crystal. If an external clock source over 4MHz is used, XTAL must be used as the input and EXTAL connected to V SS . For more information, please refer to Section 3.5.2.Table 3. DSP56F826 Signal and Package Information for the 100 Pin LQFPAll inputs have a weak internal pull-up circuit associated with them. These pull-up circuits are always enabled .Exceptions:1.When a pn is owned by GPIO, then the pull-up may be disabled under software control.2.TCK has a weak pull-down circuit always active.Signal Name Pin No.Type DescriptionPart 3 Specifications3.1 General CharacteristicsThe DSP56F826 is fabricated in high-density CMOS with 5-volt tolerant TTL-compatible digital inputs. The term 5-volt tolerant refers to the capability of an I/O pin, built on a 3.3V compatible process technology, to withstand a voltage up to 5.5V without damaging the device. Many systems have a mixture of devices designed for 3.3V and 5V power supplies. In such systems, a bus may carry both 3.3V and 5V- compatible I/O voltage levels. A standard 3.3V I/O is designed to receive a maximum voltage of 3.3V ± 10% during normal operation without causing damage. This 5V tolerant capability, therefore, offers the power savings of 3.3V I/O levels while being able to receive 5V levels without being damaged.Absolute maximum ratings given in Table4 are stress ratings only, and functional operation at the maximum is not guaranteed. Stress beyond these ratings may affect device reliability or cause permanent damage to the device.The DSP56F826 DC/AC electrical specifications are preliminary and are from design simulations. These specifications may not be fully tested or guaranteed at this early stage of the product life cycle. Finalized specifications will be published after complete characterization and device qualifications have been completed.CAUTIONThis device contains protective circuitry to guard againstdamage due to high static voltage or electrical fields.However, normal precautions are advised to avoidapplication of any voltages higher than maximum ratedvoltages to this high-impedance circuit. Reliability ofoperation is enhanced if unused inputs are tied to anappropriate logic voltage level (e.g., either or V DD or V SS).Table4. Absolute Maximum Ratings (V SS = 0 V)Characteristic Symbol Min Max Unit Supply voltage, core V DD V SS – 0.3 3.0V Supply voltage, IO and analog V DDIO V SS – 0.3 4.0V All other input voltages V IN V SS – 0.3V DDIO + 0.3V Current drain per pin excluding V DD, V SS I—10mA Junction temperature T J—150°C Storage temperature range T STG–55150°C。