1 / 13

AMCOM M261/MK66

AMCOM M261/MK66. AMCOM M261/Mk66 missile: Fall Review 2. Matt Galante Adrian Lauf Ashley Devoto Shannon Stonemetz. Filiz Genca Jeffery Kohlhoff Jason Newquist. Contact Meeting. Met with project sponsor in Huntsville Learned more about the goals and expectations

manon
Download Presentation

AMCOM M261/MK66

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. AMCOM M261/MK66

  2. AMCOM M261/Mk66 missile:Fall Review 2 Matt Galante Adrian Lauf Ashley Devoto Shannon Stonemetz Filiz Genca Jeffery Kohlhoff Jason Newquist

  3. Contact Meeting • Met with project sponsor in Huntsville • Learned more about the goals and expectations • Discussed need for preliminary review prior to hardware implementation in spring • Need to research processor options, FPGA software / hardware, possible launching motors, etc.

  4. Wall-In-Space Requirement

  5. Design Parameters • General • Compatible with M261 launcher • Capable of being handled with arctic clothing and mittens • System Life: 10 yrs Min., 25 yrs Objective • All components unclassified • All units in Metric with English units in parenthesis

  6. Design Parameters (cont.) • Firing Envelope • Altitude: -200ft MSL to 20,000ft MSL • Platform Error: 19 milliradians • Crosswind: 15 knots • Velocity (Exit): 141 fps Max. • Velocity (Wall in Space): 1978 fps Max. • Detent Release Force: Minimum 13.5x missile weight • Acceleration: 79g Max. • Wall In Space

  7. Design Parameters (cont.) • Dimensions • Weight: 34.4 lbs Max. • Length: 79.7 inches Max., 71.7 inches Objective • Outer Diameter: 2.794 inches Max. • Environmental • Temperature (Storage): -65F to165F • Temperature (Operating): -50F to 150F • Humidity: constant 100% relative humidity @ 75F

  8. Weight Spec Sheet

  9. M261 Characteristics • Plastic nose cone, aluminum casing, integral fuze, explosion charge, 9 M73 submunitions • Warhead fuze range settings of 500 – 7000 m • Fuzed weight of M261 is 13.6 lbs • Submunitions landing 5 degrees off-center have a 90% probability of casualties w/in 20 m radius (occurs 66% of the time)

  10. 14 April – Final Progress Rept. • Previous project final status • Simulation • Implementation of ballistic algorithm • Rebuilt for 6 degrees of freedom • Prototype • Shell program and interrupt service routine (ISR) for pulse-wave modulation • Determination of I/O • Algorithmic state charts • Design review • Supply procurement, assembly, demonstration

  11. Previous Design Implementations • Current Hydra-70 missile uses a screw-mount warhead design • Suggested solution as per previous AMCOM team below: Warhead Side, Male Spline Avionics Module Side, Female Spline

  12. Altera Cyclone FPGA Chipset • The Cyclone device family offers the following features: • ■ 2,910 to 20,060 LEs, see Table 1–1 • ■ Up to 294,912 RAM bits (36,864 bytes) • ■ Supports configuration through low-cost serial configuration device • ■ Support for LVTTL, LVCMOS, SSTL-2, and SSTL-3 I/O standards • ■ Support for 66- and 33-MHz, 64- and 32-bit PCI standard • ■ High-speed (640 Mbps) LVDS I/O support • ■ Low-speed (311 Mbps) LVDS I/O support • ■ 311-Mbps RSDS I/O support

  13. Altera Cyclone FPGA Chipset (cont’d) • ■ Up to two PLLs per device provide clock multiplication and phase • shifting • ■ Up to eight global clock lines with six clock resources available per • logic array block (LAB) row • ■ Support for external memory, including DDR SDRAM (133 MHz), • FCRAM, and single data rate (SDR) SDRAM • ■ Support for multiple intellectual property (IP) cores, including • Altera® MegaCore® functions and Altera Megafunctions Partners • Program (AMPPSM) megafunctions.

More Related