PCIBPMCx2
Contents
1. DYNAMIC _ ENGINEERING Embedded Solutions Page 12 The VME connectors are oriented as shown in the picture and the diagram Pin C1 is the lower left corner pin Pin C1 corresponds to the cable wire number 1 for a standard header inserted into the connector on the PCIBPMCX2 The mating part number is 120 964 455 Panduit DIN IDCA 64CSB TG30 Robinson Nugent Berg also has a part which is slightly taller Cables and breakouts are available from Dynamic Engineering Please see DINterm64 and DINribn64 products from the Dynamic Engineering website DYNAMIC _ ENGINEERING Embedded Solutions Page 13 PMC Module Backplane IO Interface Pin Assignment The figure below gives the pin assignments for the PMC Module IO Interface from Pn4 to the PCIBPMCx2 connectors Also see the User Manual for your PMC board for more information Please note that P2 or P3 P4 or P5 are installed not both DIN IDC P3 P5 SCSI II P2 P4 C1 Al 1 35 C2 A2 2 36 C3 A3 3 37 C4 A4 4 38 C5 A5 5 39 C6 A6 6 40 C7 A7 7 41 C8 A8 8 42 c9 A9 9 43 C10 A10 10 44 C11 A11 11 45 C12 A12 12 46 C13 A13 13 47 C14 A14 14 48 C15 A15 15 49 C16 A16 16 50 C17 A17 17 51 C18 A18 18 52 C19 A19 19 53 C20 A20 20 54 C21 A21 21 55 C22 A22 22 56 C23 A23 23 57 C24 A24 24 58 C25 A25 25 59 C26 A26 26 60 C27 A27 27 61 C28 A28 28 62 C29 A29 29 63 c30 A30 30 64 C31 A31 31 65 C32 A32 32 66 33 67 Open 5 or GND via J2 silk screen defined 34 68 Open 5 or GND via J2. 0 Position 2 corresponds to S_PCIXCAP When closed the signal is 0 When open the signal is 1 When set to 1 PCI X operation is enabled for the secondary side The factory setting is 0 Position 3 corresponds to OPAQUE_EN When closed the signal is 0 When open the signal is 1 When set to 1 Opaque Memory is enabled to establish the Base and limit registers used to create a private memory space The factory setting is 0 Position 4 corresponds to IDSEL_MASK When closed the signal is 0 When open the signal is 1 When set to 1 hide the devices attached to the PMC slots from the host after reset The factory setting is 0 Position 5 corresponds to DEV_64BIT When closed the signal is 0 When open the signal is 1 When set to 1 64 bit operation is enabled for the PMC slots The factory setting is 0 Position 6 is connected to the Monarch pin for slot 0 When open a 4 7K pull up to VIO is used to control the Monarch signal Pn2 64 When closed the Monarch signal is set to gnd The factory setting is 1 DYNAMIC _ ENGINEERING Embedded Solutions Page 7 Position 7 corresponds to S_M66EN When closed the signal is 0 When open the signal is 1 assuming that the PMC s do not pull the signal down SM66EN acts as an open drain signal with any of the nodes capable of reducing the clock rate and all nodes required to operate at th
3. in a residential area is likely to cause radio interference in which case the user at his own expense will be required to take whatever measures may be required to correct the interference Dynamic Engineering s products are not authorized for use as critical components in life support devices or systems without the express written approval of the president of Dynamic Engineering Connection of incompatible hardware is likely to cause serious damage ENGINEERING Embedded Solutions Page 2 Table of Contents PRODUCT DESCRIPTION 5 Shunt Settings 6 DipSwitch Settings 7 Reserved Pins Routing 11 Options 11 PMC Module Backplane IO Interface Pin Assignment 14 PMC Module Pn4 Ethernet and Serial Pin Assignment 15 APPLICATIONS GUIDE 16 Interfacing 16 Construction and Reliability 17 Thermal Considerations 17 WARRANTY AND REPAIR 18 Service Policy 18 Out of Warranty Repairs 18 For Service Contact 18 SPECIFICATIONS 19 ORDER INFORMATION 20 s DYNAMIC i ENGINEERING Embedded Solutions Page 3 List of Figures FIGURE 1 PCIBPMCX2 SLOTO INTERRUPTS SCHEMATIC 9 FIGURE 2 PCIBPMCX2 SLOT1 INTERRUPTS SCHEMATIC 10 FIGURE 3 PCIBPMCX2 PN4 INTERFACE STANDARD 14 FIGURE 4 PCIBPMCX2 PN4 ETHERNET SERIAL 15 ns DYNAMIC _ ENGINEERING Embedded Solutions Page 4 Product Description PCIBPMCx2 is part of the Dynamic Engineering PCI and PMC Compatible family of modular I O components The PCIBPMC adapts 2 PMCs
4. 3 FIGURE 3 PCIBPMCX2 PN4 INTERFACE STANDARD Read table P3 C1 P2 1 Pn4 1 P3 A1 P2 35 Pn4 2 etc DYNAMIC _ ENGINEERING Embedded Solutions Page 14 PMC Module Pn4 Ethernet and Serial Pin Assignment Ethernet J6 Serial J7 J8 Pn4 Slot 0 11 14 2 12 15 4 6 13 17 8 16 148 10 12 21 24 14 22 25 16 18 23 27 20 26 28 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 FIGURE 4 PCIBPMCX2 PN4 ETHERNET SERIAL The channel number is shown then the pin number For example On the ethernet connector J6 there are two RJ45 connectors Port 1 pin 1 is tied to Pn4 pin 1 Port 2 pin 8 is tied to pin 22 of Pn4 When the Ethernet and Serial options are installed the corresponding pins on Pn4 are no longer connected to the SCSI or VME connectors The unaffected pins are still connected DYNAMIC _ ENGINEERING Embedded Solutions Page 15 Applications Guide Interfacing Some general interfacing guidelines are presented below Do not hesitate to contact the factory if you need more assistance Installation The PMC is mounted to the PCIBPMCx2 prior to installation within the chassis For best results with the PCI bracket installed install the PMC at an angle so that the PMC front panel bezel penetrates the PCI bracket then rotate down to mate with the PMC PnX connectors The rear slot does not have the bezel interaction and can be mounted directly There are four mounting locations per PM
5. C Two into the PMC mounting bezel and two for the standoffs near the PMC bus connectors Start up Make sure that the system can see your hardware before trying to access it Many BIOS will display the PCI devices found at boot up on a splash screen with the VendorlD and Cardld for the PMC installed and an interrupt level If the information is not available from the BIOS then a third party PCI device cataloging tool will be helpful Watch the system grounds All electrically connected equipment should have a fail safe common ground that is large enough to handle all current loads without affecting noise immunity Power supplies and power consuming loads should all have their own ground wires back to a common point Power all system power supplies from one switch Connecting external voltage to the PCIBPMCx2 when it is not powered can damage it as well as the rest of the host system This problem may be avoided by turning all power supplies on and off at the same time This applies more to the PMCs installed onto the PCIBPMCx2 than the PCIBPMCxz2 itself and it is smart system design when it can be achieved DYNAMIC __ ENGINEERING Embedded Solutions Page 16 Construction and Reliability The PCIBPMCx2 is constructed out of 0 062 inch thick FR4 material Cooling cutouta have been designed into the product for improved air flow to the PMC sites The components on the PCIBPMCx2 are tied into the internal power planes to spead the dissi
6. DYNAMIC ENGINEERING 150 Dubois St STE 3 Santa Cruz Ca 95060 831 457 8891 Fax 831 457 4793 http www dyneng com sales dyneng com Est 1988 User Manual PCIBPMCx2 PCI 2 Slot PMC Compatible Carrier Revision A4 Corresponding Hardware Revision C D Fab number10 2005 0303 4 PCIBPMCx2 PCI and PMC Compatible Carrier Dynamic Engineering 150 Dubois St STE 3 Santa Cruz CA 95060 831457 8891 831457 4793 FAX 2005 2007 by Dynamic Engineering Other trademarks and registered trademarks are owned by their respective manufactures Manual Revision A4 Revised 10 15 07 DYNAMIC This document contains information of proprietary interest to Dynamic Engineering It has been supplied in confidence and the recipient by accepting this material agrees that the subject matter will not be copied or reproduced in whole or in part nor its contents revealed in any manner or to any person except to meet the purpose for which it was delivered Dynamic Engineering has made every effort to ensure that this manual is accurate and complete Still the company reserves the right to make improvements or changes in the product described in this document at any time and without notice Furthermore Dynamic Engineering assumes no liability arising out of the application or use of the device described herein The electronic equipment described herein generates uses and can radiate radio frequency energy Operation of this equipment
7. _0 FIGURE 1 PCIBPMCX2 SLOTO INTERRUPTS SCHEMATIC DYNAMIC _ ENGINEERING Embedded Solutions Page 9 Switch 4 PMC 1 Interrupt routing control The PMC INTA D signals are rotated and tied to switch positions 4 1 and 8 5 INTA is on pins 8 and 3 INTB is on 7 and 2 and so forth The upper bits are tied to Switch 3 and form the second connection on the Interrupt Intermediate bus The lower bits are tied to the PCI connector for direct connection to the PCI Interrupts The right hand side connections in the schematic are tied to the PMC Slot 1 interrupts Most PMC cards will have only one interrupt and present that on INTA With switch 3 closed the interrupt from PMC 1 is connected to INTB on the PCI primary bus With two PMC s installed and PMC 0 using interrupts this is the correct configuration Slot 0 on INTA and Slot 1 on INTB With switch 8 closed on SW3 and SW4 the intermediate bus ties INTA to INTA between the PMC sites If Slot 0 is not in use or not using INTA then PMC 1 can be routed through to the PCI interrupt INTA by closing switch 4 on SW3 The factory setting is switch 3 closed and the rest open Dip Switch 8 pos SMT INTR_AI INTR_BI INTR_CI INTR_DI INTR_A INTR_B INTR_C INTR_D FIGURE 2 PCIBPMCX2 SLOT1 INTERRUPTS SCHEMATIC Please note that SW3 and SW4 are installed with pin one on the RHS when viewing the card with the PCI fingers down SWS DIP switch number 1 is on the RHS and DIP switch number 8 is o
8. cted unit is at fault Then call the Customer Service Department for a RETURN MATERIAL AUTHORIZATION RMA number Carefully package the unit in the original shipping carton if this is available and ship prepaid and insured with the RMA number clearly written on the outside of the package Include a return address and the telephone number of a technical contact For out of warranty repairs a purchase order for repair charges must accompany the return Dynamic Engineering will not be responsible for damages due to improper packaging of returned items For service on Dynamic Engineering Products not purchased directly from Dynamic Engineering contact your reseller Products returned to Dynamic Engineering for repair by other than the original customer will be treated as out of warranty Out of Warranty Repairs Out of warranty repairs will be billed on a material and labor basis The current minimum repair charge is 100 Customer approval will be obtained before repairing any item if the repair charges will exceed one half of the quantity one list price for that unit Return transportation and insurance will be billed as part of the repair and is in addition to the minimum charge For Service Contact Customer Service Department Dynamic Engineering 150 DuBois St Suite 3 Santa Cruz CA 95060 831 457 8891 831 457 4793 fax InterNet Address support dyneng com DYNAMIC _ ENGINEERING Embedded Solutions Page 18 Specifications Logic Inte
9. ctors to support PMCs with Serial Ports e JTAG programming support The PCIBPMCx2 is ready to use with the default settings Just install the PMC onto the PCIBPMC and then into the system There are a few settings that can optimize performance DYNAMIC __ ENGINEERING Embedded Solutions Page 5 Shunt Settings Please note that the settings affect both PMC slots Select the appropriate VIO for your PMC s A PMC can be 3 3V or 5V or universal Please select the 3 3 or 5V VIO choice with the shunt J4 The Voltage choices are marked Install the shunt for 3 3V operation open for 5V operation The VIO plane is a reference for the IO level The specification does not prohibit larger current consumption from these pins The PCIBPMC design utilizes a MOSFET to control the 5V or 3 3V rails onto the VIO plane Max consumption on the VIO rail is 3A The maximum power draw of a PMC is 7 5W leaving a large safety factor The factory setting is 3 3V on the secondary VIO rail Select the 3 3V source for your PMC Some backplanes have 3 3 and some do not Sometimes the isolation provided by an inline power supply is useful Sometimes there is not enough 3 3V to supply all of the devices and it is handy to convert some of the 5V rail to 3 3V The PCIBPMCx2 has a switching DC DC power converter built in When shunt J1 is installed the switching regulator is enabled and the backplane power path is disabled The switching regulator controls a low
10. e higher rate Select the secondary side PMC PCI bus frequency The options are to use the PCI bus speed primary or to force 33 MHz on the secondary side The PMC to be installed must be 66 MHz compliant to use the 66 MHz secondary side option 1 66 MHz capable secondary side 0 33 MHz Please note that PCI XCAP will override if set to enabled The factory setting is 1 The SM66EN signal is also routed to the PMC connector pin M66EN If the PMC uses the M66EN as an input then the dipswitch can be used to control the frequency If the PMC uses the M66EN pin as a control then the Switch may have no effect For example if the switch is in the 1 position and the PMC is selecting M66EN 0 then the PMC will win and the signal will be at the 33 MHz setting Both the dipswitch and the PMC M66EN have to be enabled for 66 MHz operations Position 8 corresponds to P_M66EN When closed the signal is 0 When open the signal is 1 Select 1 to use the PCI bus speed and 0 to force 33 MHz operation If the rest of the cards installed on the same PCI segment and the segment itself are 66 MHz capable then the PCI primary speed will be 66 MHz If any device on the segment is set to 33 MHz only then the entire segment will operate at 33 MHz We recommend enabling the 66 MHz operations and using the bridge to switch to 33 MHz for the PMC The factory setting is 1 Switch 2 GPIO The 8 switch posi
11. er with DIN rail mounting DINribn64 http Awww dyneng com DINribn64 html 64 pin ribbon cable with strain relief Add XX for number of inches 36 is default All information provided is Copyright Dynamic Engineering OY NAMIC ENGINEERING Embedded Solutions Page 20
12. impedance MOSFET to pass the 5V onto the 3 3V rail When the switching regulator senses that the voltage is within tolerance the MOSFET is disabled When the voltage falls below the threshold the MOSFET is enabled An inductor and several large value tantalum capacitors are used to provide clean power to the PMCs The switching regulator is much more efficient than a linear regulator resulting in lower heat dissipation and a higher MTBF When shunt J1 is not installed the 3 3V rail from the backplane is routed to the PMC The factory setting is installed DYNAMIC _ ENGINEERING Embedded Solutions Page 6 DipSwitch Settings Please note that the switch numbering and 1 and 0 definitions are per the silk screen The dipswitches are numbered SW4 SW3 SW1 SW2 from top to bottom and are located between the PMC connectors SW3 4 are used to control the PMC interrupt routing SW2 is used for the GPIO port SW1 controls the Bridge operation SW 3 4 are oriented with pin 1 to the right and SW1 2 are positioned with pin 1 on the left see dot in silkscreen The on position is the closed position for the switch Switch 1 Special selections for the 31154 Bridge For more information please refer to the Intel documentation Position 1 corresponds to S_MAX100 When closed the signal is 0 When open the signal is 1 When set to 1 the secondary PMC side is limited to 100 Mhz in PCI X mode The factory setting is
13. iple versions of the PCIBPMCx2 design In addition to the basic bridged version there are options for Ethernet Fan Serial ports and minimization The PCIBPMCx2 features cooling cutouts designed to support the addition of a fan in one of two positions for each PMC On PrPMC s and other PMCs with high thermal loads the fan option is a good idea On cards with a lower thermal profile the fan is not needed The fan produces 8 CFM in a small area to create a high LFM rating suitable for most cooling requirements The fan used has a relatively low noise rating for quiet DYNAMIC _ ENGINEERING Embedded Solutions Page 11 operation Position 1 is closest to the PCI bezel and position 2 is closer to the PMC connectors For position 3 and position 4 locations continue counting left to right Some PMCs support Ethernet connections over the Pn4 connector with pins specified by the PICMG standard 2 15 PCIBPMCx2 supports Ethernet capable cards with an optional two position RJ45 connector on the top edge of the card Slot 0 has this option Some PMCs support serial channels on Pn4 with pins specified by by PICMG standard 2 15 PCIBPMCx2 supports serial capable cards with an optional pair of DB9F connectors on the top edge of the card Slot 0 has this option In addition the PCIBPMC has two options for Pn4 signal routing VME style 2x32 pin header shown or a SCSI style connector Please mix and match options as you need them A1 A32 C1 C32
14. n the LHS For a mental picture you can rotate the schematic counter clockwise 90 degree s With the switch in the up position the switch is open With the individual switches in the down position the switches are closed making the connection To implement the INTA from slot 1 to INTA on the PCI bus example Starting with the right hand side of SW3 the first three switches would be up and the 4 down then the next three up and the 8 down to correspond to SW3 switch 4 and 8 closed On SW4 the first 7 switches would be up and the last 8 down DYNAMIC _ ENGINEERING Embedded Solutions Page 10 The IDSEL is AD16 for slot 0 and AD17 is used for slot 1 secondary PCI Fab Rev 1 3 The IDSEL is selectable to be AD20 for slot 0 and AD21 is used for slot 1 or AD16 and Ad17 respectively Shunt J16 when installed provides AD16 AD17 and open selects AD20 AD21 Rev 4 The PCI reserved signals are routed to the PMC reserved pins in accordance with the PMC specification to allow for future signal definitions or special user signaling Reserved Pins Routing PCI PMC A9 Pn2 8 B10 Pn2 9 A11 Pn2 10 B14 Pn1 10 A40 Pni 41 A41 Pn1 42 B63 Pn3 1 A92 Pn3 59 B92 Pn3 63 B93 Pn3 61 A94 Pn3 64 In Addition Jn2 pins 58 and 64 are pull ed up to VCC_IO with 4 7KQ Pin 60 is open This configuration works with most Monarch capable PMCs Please contact Dynamic Engineering if you need alternate settings Options Dynamic Engineering offers mult
15. pated heat out over a larger area This is an effective cooling technique in the situation where a large portion of the board has little or no power dissipation A fan option is available for high thermal load PMCs or for a chassis with a lack of air circulation Surface mounted components are used The connectors are SMT for the PMC bus and through hole for the IO The PMC Module connectors are keyed and shrouded with Gold plated pins on both plugs and receptacles They are rated at 1 Amp per pin 100 insertion cycles minimum These connectors make consistent correct insertion easy and reliable The PMC Module is secured against the carrier with the PMC connectors It is recommended for enhanced security against vibration that the PMC mounting screws are installed The screws are supplied with the PMC from the OEM Dynamic Engineering has screws standoffs blank bezels and other PMC hardware available at a reasonable cost if your PMC was not shipped with some of the required attachment hardware or if it has been misplaced Thermal Considerations If the PMC installed has a large heat dissipation forced air cooling is recommended DYNAMIC _ ENGINEERING Embedded Solutions Page 17 Warranty and Repair Please refer to the warranty page on our website for the current warranty offered and options http Awww dyneng com warranty html Service Policy Before returning a product for repair verify as well as possible that the suspe
16. rfaces Access types CLK rates supported Software Interface Initialization Interface Dimensions Construction DYNAMIC _ ENGINEERING PCI PCI X Interface 33 32 lt gt 133 64 PCI bus accesses 133 100 66 33 MHz PCI clock rates transparent Bridge 31154 registers in configuration space switch selections for VIO 3 3V source primary and secondary clock rates special bridge based features and cable options PMC front bezel via PCI bracket and User IO connector via DIN ribbon and or SCSI Il connector full length PCI board with offset PCI card guide support High Temp FR4 Multi Layer Printed Circuit Through Hole and Surface Mount Components Embedded Solutions Page 19 Order Information standard temperature range 0 70 C PCIBPMCx2 full length PCI card with 2 PMC positions FAN 1 2 3 4 13 14 23 24 fan installed in position 1 or 2 or 3 or 4 or 1 and 3 or1 and 4 or 2 and 3 or 2 and 4 SER serial ports installed ENET ethernet connectors installed ROHS ROHS compliant parts and process http Awww dyneng com pcibpmcx2 html HDEterm68 http www dyneng com HDEterm68 html 68 pin SCSI II to 68 screw terminal converter with DIN rail mounting HDEcabl68 http www dyneng com HDEcabl68 html SCSI cables with latch blocks or thumbscrews and various lengths are available Custom lengths can be ordered DINterm64 http www dyneng com DINterm64 htm 64 pin ribbon cable to to 64 screw terminal convert
17. tions can be read in from the bridge via the configuration space registers The switch bits 8 1 correspond to the GPIO bits 7 0 The bits can be used for any purpose Card numbering etc The GPIO bits are also connected to a test point strip If the GPIO bits are to be used as outputs be sure that the corresponding switch is in the open position The factory setting is open DYNAMIC __ ENGINEERING Embedded Solutions Page 8 Interrupts from the PMC are connected from the PMC to the primary PCI bus INTA through INTD are mapped indirectly to the primary bus segment Switch 3 PMC 0 Interrupt routing control The PMC INTA D signals are tied to switch positions 4 1 and 8 5 The upper bits are tied to Switch 4 8 5 and form the slot 0 connection to the Interrupt Intermediate bus The lower bits are tied to the PCI connector interrupts The right hand side connections in the schematic are tied to the PMC Slot 0 interrupts Most PMC cards will have only one interrupt and present that on INTA With switch 4 closed the interrupt from PMC 0 is connected to INTA on the PCI primary bus If Slot O is not occupied or does not use interrupts the interrupt from Slot 1 will need to be routed to INTA on the PCI bus The factory setting is switch 4 closed and the rest open Dip Switch 8 pos SMT 9 8 INTR_AI INTR_BI INTR_CI INTR_DI INTR_A INTR_B o _ 4 swe3 swa3 INTR C oO swe2 swaz INTR_D 16 INTA_0 INTB_0 INTD
18. to one PCI slot Embedded applications frequently require real time processing coupled with special purpose IO With the PCIBPMCx2 s two slots a PrPMC can be matched with another PMC to make a high bandwidth processing node The PrPMC can communicate with the host for set up and then use the local bus to control and transfer data with the special purpose IO card For example the PMC BiSerial lIl HW1 provides 32 channels of Manchester encoded IO and when matched with a PrPMC can control or monitor a large system in real time The PCIBPMCx2 has programmable switch options for interrupts and other features to customize for your application Special features e Universal PCI voltage e PCI PCI X compatible e Device Hiding and Opaque Memory options e LED on PMC Busmode Present for each slot e LED s on plus 12V minus 12V plus 5V plus 3 3V and VIO e 8A regulator for PMC 3 3V supply e Selection switch for PCI3 3 or regulated 3 3 e Selectable secondary VIO e 32 or 64 bit operation on either bus e 133 100 66 or 33 MHz operation e Front panel connector access through PCI bracket e User IO Pn4 available through one of two cable connectors DIN IDC or SCSI II compatible Spare pins on SCSI connector can be shunt selected to power or ground e Cooling cutout for increased airflow to PMCs e Optional Fan s to increased airflow e Optional Ethernet connectors to support PMCs with Ethernet e Optional Serial Port conne
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