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Discover the journey of new rail technology and signal systems, challenges in implementation, and advancements like Positive Train Control (PTC).
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New Rail TechnologySignal and Train Control Systems Bill Petit www.billpetit.com Railway Age Conference December 12, 2008
What I’ll Talk About • How we got where we are • Issues affecting application of new technology • Overview of new technology applications • Particularly PTC – Whatever that means
Track Warrant Control (Dark Territory) • Movement Authority conveyed by track warrant – Permission to occupy a “Block” of track • Verbal communication
Automatic Block Signal (ABS) • Two main tracks, each with an assigned direction of movement • Movement authority and operating speed conveyed by signal system • Tracks are signaled only for movement in assigned direction • Train separation and operating speed information provided by signal system
Train Control System (TCS) (or cTc) • Multiple main tracks, each signaled for traffic in both directions • Movement authority and operating speed conveyed by signal system • Train dispatcher controls switches and signals from distant location
TCS with Cab Signals and Speed Control • Multiple Main Tracks, each signaled for traffic in both directions • Movement authority and operating speed conveyed by signal system with information sent through the rails • Train dispatcher controls switches and signals from distant location • Train separation and speed limit provided by train crew and • onboard equipment
Issues Affecting new technology applications • Cost • Reliability • Environmental • Safety • Low probability, high consequence • 1000’s of units in the field • 30 + year lifetime
What Do I Mean by Safety • System Designed to correctly perform all operational requirements under normal conditions • System Designed to correctly perform all operational requirements under adverse conditions (environmental, system stress)
What Do I Mean by Safety • System does not provide more permissive outputs under failure conditions • System or subsystem • All single point self-revealing failures • Latent (secondary) failures for non-self-revealing failures
Particular Issues with processor-based systems • Failures are non-linear • Single transistor failure within IC leads to an unknowable result. (weak-link behavior) • Complexity • Over-reliance on redundancy
Enabling Technologies • Position Locating Systems • Vehicle determines its own position, instead of relying on operator reporting or track circuits • Transponders • Satellite Locating Systems (e.g GPS)
Enabling Technologies • Mobile Data Communications • Ability to transmit increased amounts of data • Ability to track mobile node through the system • Can be used to convey information to the engineer in ways other than verbal (written) orders, wayside signals or cab signals
Enabling Technologies • Increased Processing Power • Ability to support other enabling technologies
Electronic Train Management System (ETMS) • Implemented on BNSF on pilot projects • Safety plan approved by FRA for use as an overlay system • Existing system must be maintained and used for safety • Based on Forms-Based (train order) architecture)
Track Warrant Control (Dark Territory) • Train Orders conveyed verbally and repeated for confirmation (i.e. no change) • Plan to send digital version of text for onboard display but not approved yet. • Train orders encoded digitally at office and sent to locomotive (unseen by engineer) and enforced by onboard system based on GPS location. • Also capable of reading status of existing wayside signals and enforcing them.
Electronic Train Management System (ETMS) • Class I railroads are moving ahead with this architecture • CSX – CBTM • UP – V-TMS • NS - OTC
Advanced Civil Speed Enforcement System (ACSES) • In-Service on Amtrak NorthEast Corridor • Based on Cab Signal Architecture. • Utilizes existing cab signal • Adds onboard database of civil and infrastructure data • Transponders used for position location.
Advanced Civil Speed Enforcement System (ACSES) • Train separation and operating speed obtained from existing cab signal infrastructure • Civil speeds enforced from onboard database • Positive stop enforced with data from onboard database • i.e. length of block, grade, curve, etc.
Advanced Civil Speed Enforcement System (ACSES) • Temporary Speed Restrictions conveyed by radio from office and enforced based on onboard database.
MCP Radio Antenna Advanced Display Unit ACSES box (Vital on-board Computer) Transponder Reader and CTV box Axle generator ACSES - The Equipment Train borne …plus radio set(s) cables, serial links, brackets, connections to train brakes...
Incremental Train Control System (ITCS) • In revenue service on Michigan HSR corridor and in China • Uses cab signal based architecture • Michigan – uses existing wayside infrastructure • China – uses “virtual” blocks and signals
Interoperable Communication-Based Signaling (ICBS) • Industry effort to provide standards for interoperability based on a signaling-based architecture • Supported by Alstom, GETS, Safetran and US&S • Initial set of standards approved and published in current version of AREMA Manual of Recommended Practices for Communication and Signaling
ICBS Project • Demonstration project in process funded by FRA • Supported by Alstom, GETS, Safetran and US&S
What we set out to do • Define Interoperability for a PTC system based on signaling principles • Complete system providing stand-alone ability to set and protect routes, deliver onboard authorities in terms of aspects, enforce onboard authorities including civil speed and pre-emptive braking (positive stop) • Focus on train control • Work with interoperable comms system per RESC • Basic system defined with ability to add additional functionality as needed.
What we did • Agreed to and published architecture and interoperability recommended practices through a Professional Industry Association (AREMA) • Through FRA and Private (supplier) funding • Defined Test Layout to incorporate multiple suppliers • Developed Communications Router and Simulators for Test Environment • Substituted 2 sets of suppliers equipment for one of the simulators • 3rd supplier to be integrated next week
Overall Territory with Each Supplier covering One Section GETS Safetran US&S Alstom
GETS SLP Equipment Rack • SLP (GETS VHLC) • Interfaces to Genisys Control Office • Processes Signaling Logic • Interfaces to SLP Protocol Converter • Receives Block Statuses • Transmits Switch & Signal Statuses • Interfaces to WA for Switch Control Diagnostic Terminal • SLP Protocol Converter • Converts Between GE and ICBS Messaging • Uses ICBS Database for Status Mapping • Transmits Block Statuses to GE SLP • Receives Switch & Signal Statuses from GE SLP • Interfaces to Comm. Router (ICBS Network) • WA (GETS VHLC) • Interfaces to SLP • Receives Switch Control Statuses from SLP • Transmits Switch Position Statuses to SLP
GETS OBLP Equipment Rack • OBLP (GETS ITCS Onboard Computer) • Location Determination Using ITCS Equivalent Database • Enforces Targets • Interfaces to OBLP Protocol Converter • Transmits Block Statuses • Receives Switch & Signal Statuses • Interfaces to Vehicle Simulator & Loco Interface Panel GETS ITCS Locomotive Display Vehicle Simulator & Diagnostic Terminal • Locomotive Interface Panel • Acknowledgement Input • Reverser Handle Input • In/Out Mode Switch • OBLP Protocol Converter • Converts Between GE and ICBS Messaging • Uses ICBS Database for Status Mapping • Receives Block Statuses from OBLP • Transmits Switch & Signal Statuses to OBLP • Interfaces to Comm. Router (ICBS Network)
Alstom ICBS SLP and WA Equipment Rack Ethernet Hub VPI Power and VRD Relays VPI2 SLP WA Local Panel VPI2 WA Power Supply
Questions ? Bill.Petit@ieee.org www.billpetit.com