Emerson MVME7100 manual XMC Expansion, Power Supplies, Clock Distribution

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XMC Expansion

Functional Description

 

 

4.11XMC Expansion

The MVME7100 provides an additional XMC/PMC module capability through the use of a 78- pin stacking connector. This connector is connected to the second PCI Express port on the processor. Up to four additional XMC/PMC modules may be added by using two expansion boards. Refer to the XMCspan datasheet for additional details and/or programming information.

4.12Power Supplies

The MVME7100 on-board voltages will be generated using Linear Tech LTC3828 dual output two phase controllers and LTC3416 single output controllers. The following sections detail the MVME7100 power requirements.

4.12.1Power Sequencing

In order to meet the power sequencing requirements of the various components on the MVME7100, the power supply controllers implement voltage tracking which allows the power supply outputs to track each other coincidentally during power up and power down. The +3.3 V supply output will be used as the tracking reference. All supply outputs will reach their final values within 20 milliseconds during power up.

4.12.2Power Supply Monitor

Logic is provided on-board to monitor the PGOOD signal from the LTC3828 and LTC3416 regulators to determine if the power supply outputs are within tolerance. If any of the power supplies fail, this logic shuts off the power supplies to avoid any component damage. If the +5.0 V power supply is still good during a fail condition, a planar red LED (PWR FAIL D9) is illuminated to indicate the power supply fail condition.

4.12.3Power Supply Filtering and Fusing

Each of the switching power supply inputs on the MVME7100 will have an inductor to reduce switching noise from being fed back onto the +5.0 V input. The LTC3828 supplies will each have a 10 A fuse to protect the supplies from over-current in case of component failure.

4.13Clock Distribution

The clock function generates and distributes all of the clocks required for system operation. The PCI-E clocks are generated using an eight output differential clock driver. The PCI/PCI-X bus clocks are generated by the bridge chips from the PCI-E clock. Additional clocks required by individual devices are generated near the devices using individual oscillators. For clock assignments, refer to the MVME7100 Single Board Computer Programmer’s Reference manual.

MVME7100 Single Board Computer Installation and Use (6806800E08A)

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Contents MVME7100 Single Board Computer Contact Address Contents Contents Controls, LEDs, and ConnectorsBattery Exchange Index List of Tables Page Secondary Side Thermally Significant Components List of FiguresPage About this Manual Overview of ContentsAbout this Manual AbbreviationsGpcm Quart Notation Description ConventionsBold Comments and Suggestions Summary of ChangesEMC Safety NotesSafety Notes Operation InstallationBattery Cabling and ConnectorsEMV SicherheitshinweiseSicherheitshinweise BetriebKabel und Stecker Umweltschutz BatterieFeatures List FeaturesFunction Features IntroductionPcie IntroductionFeaturesMechanical Data Standard CompliancesBoard Standard Compliances Mechanical DataOrdering Information Board AccessoriesSupported Board Models Board VariantsOverview Hardware Preparation and InstallationStartup Overview TaskShipment Inspection Unpacking and Inspecting the BoardRequirements Hardware Preparation and Installation MVME7100 SpecificationsCharacteristics Operating Nonoperating RequirementsPower Requirements Power RequirementsBoard Variant Power Chassis Type Available Power Power With PMCsThermal Requirements Thermal Requirements Hardware Preparation and InstallationThermally Significant Components Thermally Significant ComponentsPrimary Side Thermally Significant Components Equipment Requirements Equipment Requirements Hardware Preparation and InstallationHardware Preparation and Installation Configuring the Board Configuring the BoardConfiguration Switch Settings S1 SMT Configuration Switch, S1Switch Description Setting Function Safe Start Switch VME System Controller and GA Switch Settings Geographical Address Switch, S2Position Function Default VME System Controller Select, S2Hardware Preparation and InstallationInstalling Accessories Installing AccessoriesPosition Function Default S2-8 Transition Module2 PMC Installation and Removal ProcedureInstallation Procedure XMCspan Hardware Preparation and Installation Installing and Removing the BoardXMCspan Installation and Removal Procedure Factory Installed Linux Completing the InstallationPage Board Layout Controls, LEDs, and ConnectorsControls, LEDs, and Connectors Front Panel Reset/Abort SwitchFront Panel LEDs LEDs Controls, LEDs, and ConnectorsFront Panel LEDs Label Function Location Color DescriptionBaseboard Connectors ConnectorsReference Designator Function Connectors Controls, LEDs, and Connectors XMC Expansion Connector J6 Pin AssignmentsPin Signal Controls, LEDs, and ConnectorsConnectors Ethernet Connectors J4A/J4B Pin AssignmentsPin # 10/100/1000 Mb/s PMC Slot 1 Connector J11 Pin Assignments PCI Mezzanine Card PMC Connectors J11 J14, J21 J23PMC Slot 1 Connector J12 Pin Assignments ConnectorsControls, LEDs, and Connectors PMC Slot 1 Connector J13 Pin AssignmentsPMC Slot 1 Connector J14 Pin Assignments PMC Slot 2 Connector J21 Pin Assignments 10 PMC Slot 2 Connector J22 Pin Assignments 11 PMC Slot 2 Connector J23 Pin Assignments 13 VMEbus P1 Connector Pin Assignments 12 COM1 Port Connector Pin AssignmentsPin P2-Z P2-A P2-B P2-C P2-D 14 VME P2 Connector Pinouts+5V GND PMC1IO4 PMC1IO3 15 MVME721 Host I/O Connector J10 Pin Assignments MVME7216E PMC I/O Module PIM Connectors J10, J14Controls, LEDs, and ConnectorsHeaders 16 USB Connector J2 Pin AssignmentsHeaders Processor COP Header P4Boundary Scan Header P5 Boundary Scan Header P5 Controls, LEDs, and Connectors18 Boundary Scan Header P5 Pin Assignments Page Functional Description Functional Description Block Diagram Block DiagramProcessor System Memory I2C Serial Interface and DevicesI2C Serial Interface and Devices Functional Description Ethernet Interfaces TimersLocal Bus Interface Flash Memory Control and Timers PLDNvram Quad Uart QuartPCI-E Port Duart InterfaceVME Controller 10.2 USB Functional Description Duart InterfaceXMC Expansion Power SuppliesClock Distribution Real Time Clock Battery Reset Control LogicSystem Clock Real Time Clock InputTransition Module Layout Transition ModuleTransition Module Features Seeprom Address Switch, S1Transition Module Features Seeprom Address Switch Assignments RTM Rear Panel ConnectorsSwitch Settings and Device Addresses Transition Module ConnectorsTransition Module LEDs Transition Module Rear Panel ConnectorsPMC Input/Output Module Transition Module PMC Input/Output ModuleTransition Module PMC Input/Output Module Installing the PIMMOTLoad Firmware MOTLoad CommandsImplementation and Memory Requirements UtilitiesMOTLoad Firmware TestsMOTLoad Commands Command ListCommand List MOTLoad Firmware Command DescriptionMOTLoad FirmwareCommand List Command ListMOTLoad Firmware MOTLoad FirmwareUsing the Command Line Interface Using the Command Line InterfaceMVME7100 Using the Command Line Interface MOTLoad FirmwareHelp RulesMOTLoad Firmware Rules Default VME Settings Firmware SettingsFirmware Settings MOTLoad Firmware MVME7100 vmeCfg -s MOTLoad Firmware Default VME SettingsMVME7100 vmeCfg -s -o3 Default VME Settings MOTLoad FirmwareDisplaying VME Settings Control Register/Control Status Register SettingsEditing VME Settings Restoring Default VME Settings Deleting VME SettingsDeleting VME Settings MOTLoad Firmware Remote StartName Type Size Boot ImagesImage Flags Checksum AlgorithmMOTLoad Image Flags Checksum Algorithm MOTLoad Firmware Name Type SizeUser Images Alternate Boot Images and Safe Start Alternate Boot Data StructureBoot Image Firmware Scan Alternate Boot Data Structure MOTLoad FirmwareMOTLoad Firmware Startup Sequence Startup SequenceBattery Exchange Battery ExchangeBattery Exchange Exchange ProcedureRelated Documentation Emerson Network Power Embedded Computing DocumentsManufacturers’ Documents Table B-2 Manufacturer’s PublicationsFreescale Corporation Related DocumentationManufacturers’ DocumentsTable B-3 Related Specifications Related SpecificationsRelated SpecificationsRelated Documentation Organization and Standard Document TitleInstitute for Electrical and Electronics Engineers, Inc Related DocumentationRelated SpecificationsIndex Transition module PIM installation XMCspan 29

MVME7100 specifications

The Emerson MVME7100 is a powerful and versatile embedded computing platform designed for demanding applications in various fields, including telecommunications, aerospace, and defense. It offers enhanced performance, a wide range of connectivity options, and robust security features, making it suitable for mission-critical operations.

One of the key features of the MVME7100 is its high-performance processing capabilities. The system is powered by a dual-core PowerPC processor that delivers exceptional computational power while maintaining energy efficiency. This makes the MVME7100 ideal for applications requiring intensive data processing and real-time analytics, allowing users to run complex algorithms and manage large datasets effectively.

The MVME7100 supports an extensive array of I/O options, which ensures compatibility with multiple peripheral devices and communication protocols. Users can take advantage of multiple serial ports, Ethernet interfaces, and USB connections. Additionally, the platform supports various fieldbus protocols, enabling seamless integration with existing systems and equipment.

In terms of ruggedness, the MVME7100 is designed to operate in challenging environments. It features a robust enclosure that can withstand extreme temperatures, shocks, and vibrations. This provides the reliability required for industrial applications, making it suitable for deployment in harsh conditions, such as manufacturing floors or remote locations.

Security is another critical aspect of the MVME7100. It incorporates advanced security measures, including secure boot and encryption capabilities, to protect sensitive data and ensure system integrity. These features are essential for applications in sectors like defense and aerospace, where cybersecurity is a top priority.

Moreover, the MVME7100 supports various operating systems, including VxWorks and Linux, providing flexibility for developers and engineers. This enables the use of popular software development tools and frameworks, facilitating faster application development and deployment.

In summary, the Emerson MVME7100 is a robust embedded computing solution that combines high performance, extensive connectivity, and exceptional reliability. Its versatile features make it suitable for a wide range of applications, ensuring that it meets the needs of industries where performance and security are paramount. Whether deployed in telecommunications, defense, or industrial automation, the MVME7100 stands out as a reliable choice for embedded computing challenges.
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