Emerson MVME7100 manual Power Requirements, Board Variant Power

Page 32

Hardware Preparation and Installation

Power Requirements

 

 

2.3.2Power Requirements

The MVME7100 uses only +5.0 V from the VMEbus backplane. On board power supplies generate the required voltages for the various ICs. The MVME 7100 connects the +12 V and - 12 V supplies from the backplane to the PMC sites while the +3.3 V power supplied to the PMC sites comes from the +5.0 V backplane power. A maximum of 10 A of +3.3 V power is available to the PMC sites, however the 90 W +5.0 V limit must be observed as well as any cooling limitations.

The next table provides an estimate of the typical and maximum power required.

Table 2-3 Power Requirements

Board Variant

Power

 

 

MVME7100-0161

Typical: 40 W @ +5 V

 

Maximum: 55 W @ +5 V

 

 

MVME7100-0163

Typical: 40 W @ +5 V

 

Maximum: 55 W @ +5 V

 

 

MVME7100-0171

Typical: 45 W @ +5 V

 

Maximum: 60 W @ +5 V

 

 

MVME7100-0173

Typical: 45 W @ +5 V

 

Maximum: 60 W @ +5 V

 

 

The following table shows the power available when the MVME7100 is installed in either a 3- row or 5-row chassis and when PMCs are present.

Chassis Type

Available Power

Power With PMCs

 

 

 

3-Row

70 W maximum

Below 70 W1

5-Row

90 W maximum

Below 90 W1

1. Keep below power limit. Cooling limitations must be considered.

32

MVME7100 Single Board Computer Installation and Use (6806800E08A)

Page 31 Page 33
Image 32
Page 31 Page 33
Contents MVME7100 Single Board Computer Contact Address Contents Controls, LEDs, and Connectors ContentsBattery Exchange Index List of Tables Page List of Figures Secondary Side Thermally Significant ComponentsPage Overview of Contents About this ManualAbbreviations About this ManualGpcm Quart Bold ConventionsNotation Description Summary of Changes Comments and SuggestionsSafety Notes EMCSafety Notes Installation OperationCabling and Connectors BatterySicherheitshinweise EMVBetrieb SicherheitshinweiseKabel und Stecker Batterie UmweltschutzFeatures Features ListFunction Features IntroductionIntroductionFeatures PcieStandard Compliances Mechanical DataBoard Standard Compliances Mechanical DataBoard Accessories Ordering InformationSupported Board Models Board VariantsHardware Preparation and Installation OverviewStartup Overview TaskUnpacking and Inspecting the Board Shipment InspectionMVME7100 Specifications Requirements Hardware Preparation and InstallationCharacteristics Operating Nonoperating RequirementsPower Requirements Power RequirementsBoard Variant Power Chassis Type Available Power Power With PMCsThermal Requirements Hardware Preparation and Installation Thermal RequirementsThermally Significant Components Thermally Significant ComponentsPrimary Side Thermally Significant Components Equipment Requirements Hardware Preparation and Installation Equipment RequirementsConfiguring the Board Hardware Preparation and Installation Configuring the BoardSwitch Description Setting Function SMT Configuration Switch, S1Configuration Switch Settings S1 Safe Start Switch Geographical Address Switch, S2 VME System Controller and GA Switch SettingsPosition Function Default VME System Controller Select, S2Installing Accessories Hardware Preparation and InstallationInstalling AccessoriesPosition Function Default S2-8 Transition ModuleInstallation and Removal Procedure 2 PMCInstallation Procedure XMCspan Installing and Removing the BoardXMCspan Hardware Preparation and Installation Installation and Removal Procedure Completing the Installation Factory Installed LinuxPage Controls, LEDs, and Connectors Board LayoutFront Panel Reset/Abort SwitchControls, LEDs, and Connectors Front Panel LEDs Controls, LEDs, and Connectors LEDsFront Panel LEDs Label Function Location Color DescriptionReference Designator Function ConnectorsBaseboard Connectors Pin Signal XMC Expansion Connector J6 Pin AssignmentsConnectors Controls, LEDs, and Connectors Pin # 10/100/1000 Mb/s Ethernet Connectors J4A/J4B Pin AssignmentsControls, LEDs, and ConnectorsConnectors PCI Mezzanine Card PMC Connectors J11 J14, J21 J23 PMC Slot 1 Connector J11 Pin AssignmentsPMC Slot 1 Connector J12 Pin Assignments PMC Slot 1 Connector J13 Pin Assignments ConnectorsControls, LEDs, and ConnectorsPMC 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 12 COM1 Port Connector Pin Assignments 13 VMEbus P1 Connector Pin Assignments+5V 14 VME P2 Connector PinoutsPin P2-Z P2-A P2-B P2-C P2-D GND PMC1IO4 PMC1IO3 MVME7216E PMC I/O Module PIM Connectors J10, J14 15 MVME721 Host I/O Connector J10 Pin Assignments16 USB Connector J2 Pin Assignments Controls, LEDs, and ConnectorsHeadersHeaders Processor COP Header P418 Boundary Scan Header P5 Pin Assignments Boundary Scan Header P5 Controls, LEDs, and ConnectorsBoundary Scan Header P5 Page Functional Description Processor Block DiagramFunctional Description Block Diagram I2C Serial Interface and Devices Functional Description I2C Serial Interface and DevicesSystem Memory Local Bus Interface TimersEthernet Interfaces Control and Timers PLD Flash MemoryNvram Quad Uart QuartDuart Interface PCI-E PortVME Controller 10.2 USB Functional Description Duart InterfaceClock Distribution Power SuppliesXMC Expansion Reset Control Logic Real Time Clock BatterySystem Clock Real Time Clock InputTransition Module Transition Module LayoutTransition Module Features Seeprom Address Switch, S1Transition Module Features Rear Panel Connectors Seeprom Address Switch Assignments RTMSwitch Settings and Device Addresses Transition Module ConnectorsTransition Module Rear Panel Connectors Transition Module LEDsPMC Input/Output Module PMC Input/Output Module Transition ModuleInstalling the PIM Transition Module PMC Input/Output ModuleMOTLoad Commands MOTLoad FirmwareImplementation and Memory Requirements UtilitiesTests MOTLoad FirmwareCommand List MOTLoad CommandsCommand List MOTLoad Firmware Command DescriptionMOTLoad FirmwareCommand List Command ListMOTLoad Firmware Using the Command Line Interface MOTLoad FirmwareUsing the Command Line InterfaceUsing the Command Line Interface MOTLoad Firmware MVME7100MOTLoad Firmware Rules RulesHelp Firmware Settings MOTLoad Firmware Firmware SettingsDefault VME Settings MOTLoad Firmware Default VME Settings MVME7100 vmeCfg -sDefault VME Settings MOTLoad Firmware MVME7100 vmeCfg -s -o3Editing VME Settings Control Register/Control Status Register SettingsDisplaying VME Settings Deleting VME Settings Restoring Default VME SettingsDeleting VME Settings MOTLoad Firmware Remote StartBoot Images Name Type SizeChecksum Algorithm Image FlagsMOTLoad Image Flags Checksum Algorithm MOTLoad Firmware Name Type SizeUser Images Alternate Boot Data Structure Alternate Boot Images and Safe StartBoot Image Firmware Scan Alternate Boot Data Structure MOTLoad FirmwareStartup Sequence MOTLoad Firmware Startup SequenceBattery Exchange Battery ExchangeExchange Procedure Battery ExchangeEmerson Network Power Embedded Computing Documents Related DocumentationManufacturers’ Documents Table B-2 Manufacturer’s PublicationsRelated DocumentationManufacturers’ Documents Freescale CorporationRelated Specifications Table B-3 Related SpecificationsRelated SpecificationsRelated Documentation Organization and Standard Document TitleRelated DocumentationRelated Specifications Institute for Electrical and Electronics Engineers, IncIndex 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.
Top Page Image Contents