Tuesday, March 18, 2014

Delay Beginning of Flashing Yellow Arrow Due To Opposing Queue of Cars

This post is a continuation of a previous post showing a modified operation of Flashing Yellow Arrow as described in a previous post.  See:

http://ntcip-unleashed.blogspot.com/2013/01/flashing-yellow-arrow-operation.html

This post documents additional modifications to the Flashing Yellow Arrow operations, to delay the onset of the FYA if the signal would cycle from the side street back to the main street, but there is a queue of thru cars opposing the vehicles in the left turn pocket.  The assumption here is that the protected left turn portion of the FYA operation is a queue dependent lagging protected left turn.

The example in this blog post is running in a Trafficware / Naztec 2070 controller, running Apogee V.76.7d.  While I am not advocating the use of any specific controller brand or software version, the description here is based on what I am using in the field.

Traffic signal controller settings to modify the FYA operation.

Goals:

  • Continue use of inhibiting FYA across pedestrian WALK and FDW
  • Continue inherent controller delay of FYA by implementing FYA Delay Time under MM-1-5-2-(OL#)-3
  • Continue phase sequence to lag the protected left on the FYA, based on standing queue in the left turn lane at the end of the main street green phase
  • New operation in free and coordinated TOD plans.
  • New operation to inhibit the FYA when a queue of cars is in the opposing lane
  • New operation will not allow a ped call while inhibiting the FYA to start the WALK, rather it will hold the ped call until the next time the phase is served.
    • For example:
      • The signal ends phase 2, a queue exists on the SB thru lane (associated with phases 4 and 9).  
      • The signal would  come up in phases 9 and 8 (the queue of SB cars calls phase 9 as opposed to the min green for phase 8).  
      • The FYA head will display a steady red left turn arrow to the NBL traffic, while cycling phase 9, then when the SB traffic gaps out for phase 9, or maxes out for phase 9, the signal will transition from 9 to 4, and the NBL flashing yellow arrow head will transition from a steady red arrow to the FYA indication.
      • A late ped call across the west leg (ped 9) while the signal is timing phase 9 may display a WALK and FDW for Phase 9, which could end up with the signal needing to go into offset seeing mode

The phase diagram for this controller is as follows:

Phase diagram for signal controller running a modified flashing yellow arrow operation.
The modified FYA will provide a red left turn arrow across a specific pedestrian in WALK or FDW
(for example, Phase 7 will display a red arrow while the ped associated with phase 11 is provided a
WALK or FDW).  When ped 11 is through with timing the WALK, FDW, yellow and all-red, then the
controller will transition to phase 8, but since phases 11 and 8 are run through overlap 11 on load switch
position 8, the signal indication remains green for the thru movement.  After the signal transitions to
phase 8, the phase 7 FYA will be displayed.

In this case, the southbound left turns, associated with phases 7 and 12 on overlap 12 can be individually
programmed to provide either leading or lagging protected left turns, based on the NTCIP Action plan.
Setting up the controller in this way allows the signal to switch the lead and lagging protected left turns by TOD
without needing to go into free to allow for a change of sequence in coordination.


Intersection Layout and Description

Screen shot of intersection phasing and detection
In this case, the signal does not have stopbar detection on the main street.  There is main street presence detection located at approximately 60-ft to 80-ft from the stopbar.  The left turn detection also does not include stopbar detection.  There is presence detection located at approximately 20-ft to 40-ft from the stopbar in the left turn lane.  Since the signal rests in green on the main street, the FYA will normally come up.  The presence detection in the left turn lane is queue dependent to drive a lagging protected left turn lane.

The signal rests in min green for phases 4 and 8.  The signal is split phase eastbound (phase 1) / westbound (phase 2).  There is no ped for phase 2.  The eastbound approach to the signal serves a center including a big box retail, movie theater and, a restaurant and several smaller strip mall facilities.  The east leg serves a single parking lot for a small office complex.

If you look at the left turn arrow icons for phases 3 and 7, you will see that they are black, while the icons for phases 10 and 12 are red.  At the time that this screen shot was taken, phases 3 and 7 were omitted by the coord plan, but phases 10 and 12 were included.  They are displaying red, however the display also includes orange icons for the FYA indications.  These are driven off the channel outputs for the ped yellows that the FYA is operating from.  When the signal is not displaying a FYA, the orange arrows go black, providing an excellent indication of whether the signal is in protected left, FYA left, or just steady red or steady yellow for the lefts.

Also, note that the main street peds are phases 9 and 11, not the normal 4 and 8.    The pedestrian indications include unique phasing as a part of the special operation to not allow the FYA across the ped WALK or FDW, as described in the previous post on FYA operations.

Controller Coordination Programming Parameters:

One thing that must be considers is how tight the coordination parameters restrict the phasing and timing.  In this case, in order to get the signal to operate with all of the extra phases for the special FYA operation, the timing must be very tightly controlled.

One key thing that must be controlled is how the signal goes into offset seeking mode.  There are valid reasons why a controller may exceed the cycle length in coordination by over 0.1 second.

If the controller is only allowed to longway transition, you may find that your controller will bounce once in a while, where the signal exceeds the cycle length by 1 second, so the signal then goes into longway offset seeking mode to transition back to coordination sync.  This means that if the signal exceeds the cycle by 1 second, it must longway transition (cycle length - 1).  This could be a very long crawl for a signal running at a 140 second cycle that must longway transition 139 seconds over 3 exceptionally long cycles since the longway transition was set at 33%...  That would mean that the signal would need almost 560 seconds, or 9 minutes 20 seconds to get back into step if it exceeds the cycle by 1 second, and only has longway transition activated.  The caveat to this may be if the specific brand and model of controller firmware includes a special operation for allowing the split divisions to be less than the sum of (WALK+FDW+Yellow+All-red)

The coordination parameters inside the Apogee firmware allows each Action Plan to include 4 specific phases to not to be transitioned via shortway transition.  This allows for shortway transition to be very effective where you need specific phases to never shorten in the transition.  Having this type of control can really provide a nice way to get back into step if your cycle gets slightly long.

Before you decide that your controller never exceeds the cycle length under normal operation, take a good look at the specific cycle by cycle operation.  You may be very interested in how closely the coord cycle length is actually operating vs. the slight variations that you were unaware of.

Late Pedestrian Actuations

One key thing that must be accounted for is how does the signal accommodate late pedestrian actuations while in coordination.  In some cases, if there is time in the split divisions, a pedestrian pushing the button on the main street shortly after the main street green is provided will allow the ped indication to transition to WALK.  In this case, because of the special operation at the signal with the FYA, this needs to be prohibited.  If the pushbutton is actuated after the phase next decision is made, the signal really needs to lock the ped call, then come back to it.

Admittedly, this does hinder the pedestrian crossing, but at the same time, it is providing improved safety for the pedestrian, to insure that vehicles are not turning left across the crosswalk while the WALK or FDW is timing.

The Apogee software allows by Action Plan, to determine if the peds will be inhibited or not.  In this case, for the times of day where the FYA is operating in coordination, the specific Action Plans have this feature turned on.

Detection Settings to Inhibit the FYA When There Is An Opposing Queue

The goal here is not to inhibit the FYA when the opposing queue appears.  Rather it is to inhibit the FYA when the signal cycles from the side street back to the main street - if there is a queue of cars in the oncoming thru lanes.

In the Apogee software, each detection input is allowed to specifically be mapped to one phase.  Getting one detection input to do two separate things is accomplished by using the "source" feature.  Essentially, you program an unused detector input to be sourced from another detector.

I have used several controllers which allow you to map a single detection input to any of the 16 phases in the NTCIP controller.  I have to admit at first I didn't like Apogee's sourcing method, since I was used to assigning a controller's detector input to 2 or 3 phases, depending on what I wanted to do with the detector.  However, once I started working with Apogee's Sourcing features, I figured out that it was an exceptionally powerful tool.  You can source the detectors such that you can monitor a wide variety of things, such as:


  • The primary detector input logs occupancy during green + yellow
  • The sourced detector logs occupancy during any combination of green / yellow / red for any phase
  • The primary detector calls one phase as a standard call / extend detector
  • The sourced detector can be an extend only for another phase
  • The sourced detector can be a NTCIP queue detector for another phase
  • The primary and sourced detectors can have completely different delay and extension factors for running different types of signal operations from the same detector
and so on.

Sometimes flexibility comes in many different methods.  Once I started playing with this, it became very obvious how powerful this specific method of sourcing could be.

In this case:


  • Detectors 33 and 34 are sourced from detectors 9 and 10.  
    • Detector inputs 9 and 10 are the true inputs driving phase 4, but in this modification, 33 and 34 will drive call and extension detection for phase 9.
  • Detectors 35 and 36 are sourced from detectors 3 and 4.  
    • Detector inputs 3 and 4 are the true inputs driving phase 8, but in this modification, 35 and 36 will drive call and extension detection for phase 11.

In short, this type of operation allows the signal to delay the onset of the FYA for a left turn, where because of traffic congestion, there would be no opportunity to turn permissively across the oncoming cars anyway.  Since this is detection driven, the delay of the onset of the FYA would only appear when there is an opposing queue of cars.

It can be a little challenging in lighter traffic volumes.  Since a "dummy" phase is being called to drive the red arrow across the oncoming traffic, the "dummy" phase must time the min green, plus any extensions, plus the yellow and all-red before providing the left turn with a Flashing Yellow Arrow indication.  It may be appropriate to rethink the min green timings for the "dummy" phase to a short value to reduce undue delays to the left turning traffic.





Friday, March 7, 2014

Real Time Congestion Monitoring on Arterials

This article is on how to use your central system to provide real time congestion mapping, and incident notifications.  The example here is using Naztec's ATMS.now central system and Naztec controllers using Apogee Version 76.x firmware.  As I have said before, I am not a Naztec employee, or vendor.  I am a local agency traffic engineer who uses Naztec products.  I would assume that other brands of controllers and central systems can do similar operations.

In our case, each detection zone (each induction loop (or array of circle loops within a specific lane), video detection zone or radar detection zone is brought back into the controller using a unique channel.  The desire for detailed operational information drove the specific design of signal cabinets and detection systems.  We have a Caltrans 332 style cabinet which has a modified I and J file and wiring harnesses to take advantage of 46 unique detection inputs into the 2070 controller using the C1 and C11 harness.  The vast majority of our signal cabinets are NEMA TS2-1 where we have up to 48 or 64 channels of detection coming into the controller.  While this may seem excessive, the rich data we are provided through this expanded detection methodology provides us with a lot of tools to help our signals run better, and provide additional data for determining performance.

Each detection input is monitored in the controller for detection diagnostics along with logging volumes and occupancies on 5-minute intervals.  Almost all stopbar detection occupancies are tied to only log the occupancy when the signal is either green or yellow for the associated phase the detection channel drives in the controller.  In some cases, we choose to log green + yellow + red, or only yellow + red, but the vast majority of the stopbar detectors are logging occupancies only during green plus yellow.

In some cases, we do also mirror specific detectors to log green + yellow under one channel, but mirror the detection to log green + yellow + red, if we need additional information about how the lane is operating.

Why do we do this?

There are a lot of reasons.  One primary reason is that the central system is programmed to monitor each group of lanes for congestion.  The left turn lanes are separately monitored from the thru lanes.  When congestion occurs, the system logs the congestion levels, and specifically shows them on a map.  When specific thresholds are exceeded, the system also sends email notifications about a specific left turn or thru movement which has excessive congestion.

How do we do this?

As stated before, each controller's detection inputs are logging congestion data on 5-minute intervals.  That information is uploaded every 5 minutes to the central system via the Ethernet communications.  This is done mostly via fiber optic interconnect or Ethernet radios.  At some remote signals, the communications are accomplished via 3G cellular data modems.  We have had up to 4 signals reporting back continuously via cellular data modems without any problems.

ATMS.now – Congestion Monitoring Configuration

The basic congestion mapping for North, South, East and West is mapped on the scan screen, however functions within ATMS.now allow for additional information to be used for incident triggering.
Below is a picture of NE Hazel Dell at Ne 99th St, showing the detector layout and the basic N, S, E and W congestion mapping.

Screen shot of Naztec ATMS.now central system showing the detection, phasing, pedestrian
and other features.  The green lines with "Occupancy: #" show the percent occupancy during
the approach's phase green + yellow of the stopbar detection for the previous 5 minutes
Each detector used for this function needs to have occupancy, or volume checked in the controller (MM-5-2, Occup and Volum columns).  The reporting period of the detector data needs to be set to 5 minutes in the controller (MM-5-8-1).

Each of the directions need to be associated with the specific detection inputs for the congestion levels.  In addition to the north, south, east, and west congestion levels being defined, the other 4 are defined.

Screen shot of Naztec ATMS.now central system definition of congestion mapping for a
signalized intersection The user has the option of choosing congestion thresholds of
occupancy, volumes or speeds based on specific detection inputs.  The specific
threshold values for "Medium" and "High" correspond to the color of the lines
on the map for the congestion (low is green, medium is yellow and high is red).  The
specific medium and high thresholds also correspond to unique incident triggers
 that the central system can implement.
Under Definitions, Incident Triggers, create the incident triggers for the 8 locations.

Screen shot of Naztec AMS.now showing the incident triggers based on inputs
Note that there are 8 separate congestion alerts for each signal (1 for each left turn, and 1 for each thru movement).  This is true only where separate left turn lanes exist.  In the event that the left is permissive, this tracks the frequency that congestion on the permissive left turn lane exceeds the high threshold as set in the Congestion Level Definition.

One problem with this system is that when a loop fails, and constantly calls, this mapping will generate constant email messages.  If you look at the list above, under 3425, you will see that none of the day of the week boxes are checked (orange oval).  In this case, a contractor cut out the stopbar loops when they were not supposed to, and the controller is running in recall, with the loop amplifiers failing.  To keep the email messages from overwhelming the user, this approach’s two congestion incident triggers were turned off for weekdays.  This provides a good visual indication of where problems need to be fixed in the field.

Under Incident Trigger, create the congestion incident triggers similar to the following.  The text for the box “Description” is important, since this is the specific message provided in the email, and in reports run in ATMS.now.

Screen shot of Naztec ATMS.now incident trigger.  The specific time and dates when the incident
trigger is in place can be customized.  The incident triggers can also be set up based on
alarms or congestion to change the pattern, turn on a CMS sign with a message, turn on a video
camera which has been integrated into the central system software using the IV&C video relay
software, or send out an email notification
In general, the congestion incident triggers only run from 5 AM to 8:59 PM, Monday through Friday.

In the future, additional information will be included, such as camera triggers, to allow for future implementation of automatic PTZ camera viewing of congested areas.

The orientations on the incident trigger congestion and congestion level definition are as follows:

NB - North NBL – North West
SB – South SBL – South East
EB – East         EBL – North East
WB - West WBL – South West

The user distribution is set to Clark TMC Staff

Screen shot of Naztec ATMS.now central system showing how to set up the email alerts to a
specific group of users based on the incident trigger.
When the incident trigger criteria is met, ATMS.now will send an email to the people listed on the Clark TMC staff for the specific approach with the congestion alert.

The email sent will look similar to the following.  Note that the message in the text of the email is what was entered in the “Description” box of the incident trigger definition, plus the date and time.

If you do not populate the “Description” box with enough information, the emails will not have any specific meaning. 

Sample email from central system showing congestion incident
Specific reports can also be run within ATMS.now

Sample report from Naztec ATMS.now showing the reporting abilities

Like other reports in ATMS.now, the text of the report can be exported to Excel, PDF, Word documents and RTF formats, in addition to printing them out on a printer.

Additionally, specific reports can be run showing the relative congestion on specific approaches to the signalized intersections.

Sample of congestion reporting for sample intersection.  The different colored lines
correspond to the  specific occupancies of the stopbar detectors during
green plus + yellow of the signal for that approach's phase.

Conclusion

This is a lot of work to do.  There are dozens, if not hundreds of settings in each controller.  There are thousands of settings in the central system which must be made, and verified.  A detailed understanding of how each controller is connected to the unique detection system in the intersection is mandatory.  After the system is set up, all of the thresholds will need to be verified and adjusted to show what is truly special as opposed to regular congestion.

The net result is that this type of operation in a central system provides invaluable data for understanding where the problems exist regularly as opposed to occasionally.  Also, this type of approach to signal operations provides advance notice that something is happening in the field.  In many cases, the system has told me that something has occured (collision, failed detection etc) via this type of programming, and I am already working on the fix, or in many cases have already addressed the issue before the phone calls come in.

Thursday, February 7, 2013

Truck Priority Traffic Signal Operation – a potential opportunity


This post is based on the reader understanding basic and advanced traffic signal controller overlap operations.  These are outlined at:

http://ntcip-unleashed.blogspot.com/2012/02/basic-overlap-information.html

and

http://ntcip-unleashed.blogspot.com/2012/02/advanced-overlap-applications.html

Trucks decelerate and accelerate slower than other vehicles.  The operation described here provides a method to allow the signal to operate such that when a truck approaches a signal at a point where the signal may normally gap out, or max out, the truck will have a better chance of getting through the signal on a green, reducing the frequency of truck stops.
 
In this example, the truck is approaching the traffic signal on a continuous 10% uphill grade.  The continuous 10% uphill grade breaks to relatively flat right at the signalized intersection.  Any large vehicle stopping would have increased difficulty in getting moving on a green indication due to the grade of the street.
 
This is not a sales document.  There are a variety of methods that can be used to determine the classification of the vehicle.  This method uses a Wavetronix HD Count station, located approximately 400 feet from the stopbar down the hill from the traffic signal.  The HD Count Station uses RS-485 communications from the count station to the traffic signal cabinet.  The processing is done within the traffic signal cabinet.
 
More information about the HD Count Station can be found here:
 
 
In the cabinet, there is a Wavetronix backplane, which provides the power bus and the RS-485 com for the Click! Devices on the back plane.  This backplane also provides power and communications for the Wavetronix Matrix stopbar detection system.
 
One key componenet is the Wavetronix Click! 512 vehicle alert module.  This module was developed for overspeed conditions, not necessarily for truck priority.  The Click! 512 module allows the user to program 4 unique channels of output, where the combination of the HD Count Station and the 512 module will identify a large vehicle, and make different actions based on the speed of that large vehicle.
 
More information about the Click! 512 Vehicle Alert module can be found at:
 
 
When a large vehicle is progressing towards the signal, and passes the HD Count Station, the Click! 512 module determines the speed of the large vehicle, and then places a contact closure output to a Wavetronix 114 detector card.  The relation of the speed range, and which input to the controller is shown on the table below.  These are starting points, based on the HD Count Station being 400 feet from the stopbar.
 
Controller Det Input
Speed Range
Lower Speed
Ph 12 Extension Timing
17
More than 40 mph
60 fps
7 seconds
18
30-40 mph
45 fps
9 seconds
19
20-29 mph
30 fps
13 seconds
20
15-19 mph
22 fps
18 seconds

The extension timing is the controller’s extension timing, such that the controller detection input will call and extend for the time listed, based on one or more truck priority calls.
 
The traffic signal controller operates in USER mode (a modification from the standard 8-phase dual quad operation).  The USER mode is configured such that phase 4 and 12 are sequential, running to overlap 12, through load switch 4.  Phases 4 and 8, and phases 8 and 12 will terminate simultaneously.  This means that when the signal is getting close to gapping out, or maxing out, and a truck approaches the count station, the signal will transition from phase 4 to phase 12, and hold the green for the approach with the truck, while also holding the green for the opposing thru movement. 
 
The phase sequence diagram looks as follows:



If additional trucks arrive while the signal is running in phase 8 and 12, the signal will continue to hold the green until either phase 12 gaps out, or the phase 12 max timer is met.
 
If there is no traffic in the opposing left turn, or on the side street, then the controller may cycle between 4 and 12, based on the actual traffic on the main street.  Even though the signal is cycling between phase 4 and 12, the drivers will not see a change in the state of the indications, since 4 and 12 are run on an overlap through the load switch for phase 4.
 
It is important to keep the min green time for phase 12 relatively short.  The detection inputs for phase 12 are set to call and extend.  If the signal is operating in phase 4 and 8, and ready to gap out, and a truck approaches the intersection via the count station, the count station system places a call to the controller on the specific detection channel associated with the approach speed.  The following will occur within the controller while displays attached to load switch 4 stays green.
 
  • Phase 4 times the yellow interval (typically 3 to 4 seconds, depending on what the engineer sets it to)
  • Phase 4 times the red interval (0 to 2 seconds, depending on what the engineer sets it to)
  • Phase 12 times the min green interval
  • The remainder of the phase 2 extension timing occurs
 
If the min green time is excessive, the signal will hold for a longer time than necessary.  For example, if the truck is going 40 mph uphill, the call and extend time on phase 12 is 7 seconds.  This should get the truck to the stopbar at 40 mph.  If the signal is ready to end phases 4 and 8 and move on to 2 and 6, the controller will stay green for load switches 4 and 8, while the call / extension for phase 12 causes the signal to hold that green through the timing of phase 4 yellow and red plus the phase 12 min green time.  If phase 4 yellow is 3.2 seconds, and phase 4 all-red time is 1.8 seconds and the phase 12 min green time is 5 seconds (10 seconds total), the signal will hold green 3 seconds longer than necessary for the truck.  However, if the truck is traveling at 20 mph with the same settings, the extension timing will hold the green for 8 seconds longer than the sum of phase 4 yellow and all-red plus phase 12 min green.
 
There needs to be a balance of the timing that will need to be set by field calibration.
 
If the signal is to be in coordination, Phase 12 will need to be given adequate time in the split divisions to function within the coord plan. 

 

Wednesday, January 30, 2013

Flashing Yellow Arrow Operation

This is a complete revision of a previous post on the same topic.  Based on new information, many of the controller settings were modified as shown below:

The operation detailed in this post is not a recommended operation, it is provided to allow engineers who work on traffic signal controllers ideas as to how Flashing Yellow Arrow signals could be operated.

The operation in this post details controller operations where the signal will not provide a FYA indication across a pedestrian movement that has a WALK or FDW indication that is active.

Flashing Yellow Arrow Operation

The Naztec controller has some specific things that must be done in order, to enable FYA.  The manual has some of the information, but not all.
 
One key piece of information is that the manual (as of December 2012 V.76, and Technote 1105 on the Naztec Website specifically use Overlap 1 (OLA) as the example overlap detailing the controller settings.  According to the Naztec rep’s email on January 21, 2013, the overlaps with FYA operation need to be on even overlaps (OL2, OL4, OL6… OL16), not on odd overlaps (OL1, OL3, OL5… OL 15).
 
When the FYA overlaps are on odd overlaps, the FYA appears to work properly until a preempt call is served.  The preempt call causes the signal that is operating on FYA to present signal indications that the monitor will not accept.

This appears to occur very occasionally in signals that are running in STD mode, operating with FYA indications.  However, when the signal is operating as described below, for No FYA across Ped Movements, the preempt call regularly presents signal indications that the monitor will not accept.

When the overlaps are mapped to even overlap numbers, the normal termination of a FYA operation due to a side street call, the signal should transition something like:


The main street greens (phases 2 and 6) and the main street FYA indications (phases 1 and 5) should all go yellow simultaneously upon the call to the side street.

When the overlaps are mapped to odd overlap numbers, the normal termination of the main street to a vehicle or pedestrian call on the side street operates the same as the above diagram, at least in Apogee V.76.7D, Build 3195, however when an emergency vehicle preemption call is served, the following phase operation will occasionally occur when the controller is in STD mode, but predictably occur when the controller is in USER mode:


The monitor will not accept a steady yellow on load switches 1 and 5, while greens are on for load switches 2 and 6, causing the signal to go into red flash.
By programming the overlaps running the FYA as even numbered overlaps, the controller has internal logic on the even numbered overlaps that prevent this from occurring.

No FYA across Ped Movements

The operation described here includes specific modifications of the controller operation to have the signal stop presenting a FYA indication to the left turn, when the pedestrian immediately to the left of the driver in the left turn pocket could have a WALK or FDW during normal operation.

A standard operation would be to allow the pedestrian movement to go to WALK and FDW while the corresponding left was in FYA.  In other words, if the NBL signal was in FYA operation, the SB ped would be given the WALK and FDW.

At issue here is what level of safety needs to be provided to the pedestrian while the driver is looking at for gaps in the oncoming stream of vehicles.  It could be argued that the left turning driver should yield to pedestrians to their left, however, if the pedestrian is traveling thru the crosswalk, to the left of the driver, going the same direction as a driver, the left turning driver may never look behind them while attempting to turn left for a person walking, running, biking or using other mode of transport while crossing the crosswalk.

Another operation would be to allow the FYA to terminate, and go to a steady red arrow, when a pedestrian received a WALK / FDW for the crossing.  This would likely create a yellow trap for the driver at a 4-legged intersection.

This operation would receive the pedestrian call, and wait for the signal to gap out, or max out on the main street traffic, then quickly serve the side street, them come back to the main street with the Ped WALK, and the conflicting left turn having a red arrow.

This is done by modifying the signal operation from the standard 8 phase dual quad operation.

Modifying the Phase Sequence


The following example is for setting up FYA for an intersection with the following basic operation:

The flashing yellow arrow will be for the eastbound left movement (Overlap 12 corresponding to Phase 1), and for the westbound left movement (Overlap 14 corresponding to phase 5).

The actual phase diagram is as follows:



The modified ring and barrier structure is set up to allow the FYA to flash yellow with the thru movements (1 with 6), but not with the peds (1 with 10).

The correspondence of the overlaps, and outputs is as follows:
 
The FYA output to the field wires is set up to connect to the (typically) unused yellow indication on the pedestrian load switches.  In this case, LS 9 drives Ped 2, and LS 11 drives Ped 6
  

Setting the Ring and Barrier Operation on Apogee V.76

 
There are several areas that need to be set up to make the FYA work.

The signal must be set to User mode.  To do this, go to MM-1-7, and turn the Run-Enable Status from ON to OFF, press enter, and the signal will stop running.  Next, go to MM-1-2-1 (Unit Parameters) and change the Phase Mode from “STD8” to “USER”. 

Now the ring and barrier structure must be modified to include the extra phases.   This is done via the signal sequence (MM-1-2-4):
  
The example here shows only modifying Sequence 1, but the user may want to modify other sequences.  

In general, when I am programming a special sequence that I don’t want to have the ability to undermine with potentially calling a sequence that may violate antibackup, or other features, I copy the only sequence I want to use into all 16 sequence entries, which means that there should be no way to have a sequence that creates a problem for the signal operation.

Next, the phase concurrency table needs to be modified to reflect the modified phases.  At this time, the signal is also modified such that it starts up in 9 and 10 WALK.  Normally, I start up signals in main street WALK.

This is done under MM-1-1-4:


Now that the ring and barrier structure is set for the controller, the signal run timer can be turned back on, under MM-1-7

Enabling the Specific Vehicle and Pedestrian Movements

  
The specific phases need to be enabled under MM-1-1-2.  The normal phases are enabled for the ped movements, plus phases 9 and 11 need to be enabled, so that the peds will time.

Time needs to be added to phase 9 and 11 peds under MM-1-1-1.  Also, any time for WALK and FDW for phase 2 and 6 peds need to be zeroed out.  In the example below, the ped timing, yellows and reds are what are operating in the signal cabinet for the intersection.

Specific timing is added to phase 9 and 11 for the min green, yellow and red.  This time is added, since the signal will be operating in soft recall during certain hours of the day.  Without having the appropriate clearance times for the phase 9 and 11, and the signal in soft recall, a late night pedestrian service may terminate from the main street to the side street at the end of the FDW without the signal going through the appropriate clearance times for the main street traffic.

 
Now the ped timing for phase 2 and 6 peds needs to be zeroed out.  The Peds that are normally associated with phase 2 and 6 are now phase 9 and 10 peds respectively.

Setting The Load Switches for the Overlaps


Now the load switches must be assigned for the overlaps.  The Channel I/O needs to be modified as follows under MM-1-8-1:

If you scroll to the right of the last column on the first screen , you will see the second screen that covers load switches 9 through 16.

The assumption on this second screen is that the channels were already modified so that the pedestrian load switch and overlap load switch assignments were modified to reflect that the peds were on load switch positions 9-12 and the standard overlaps were on load switch positions 13-16.

In this case, the load switches for 13-16 were actually modified to an unused input (changed to OL 16).  This was done to make sure that there was no problem with the overlaps being assigned to load switches 1, 2, 5 and 6.  Each specific installation will need to assign overlaps to the unused load switches that will not conflict with the other inputs.  Alternately, the unused load switches could be programmed to channel 0, which will result in a dark output.  The monitor will need to be programmed to accept a dark red output if the unused load switches are programmed to channel 0.

Setting up the Overlaps


There are several overlaps to be programmed for this operation.
  • Overlap 12 and 14 are for the flashing yellow arrow.
  • Overlap 9 is for the westbound thru / right movement
  • Overlap 10 is for the eastbound thru / right movement
Starting with Overlap 9, the following parameters need to be programmed under MM-1-5-2-(9-Enter)-1:


For Overlap 10, the following parameters need to be programmed under MM-1-5-2-(10-Enter)-1:

Setting up the Overlaps for FYA Operation

For overlap 12, several parameters need to be added, including the type of overlap.  This is programmed under MM-1-5-2-(12-Enter)-1


The minus ped overlap parameters should not need to be programmed, However, if it is desired to program the negative ped overlaps, then this done under MM-1-5-2-(12-Enter)-2

For overlap 14, similar programming needs to be entered into the controller.  This is programmed under MM-1-5-2-(14-Enter)-1

The minus ped overlap parameters should not need to be programmed, However, if it is desired to program the negative ped overlaps, then this done under MM-1-5-2-(14-Enter)-2

Setting The Ped Yellows on Load Switches for FYA


Under MM-1-8-1, some values need to be modified for the output drivers.  In this case, the normal vehicle head for phase 1 (Channel 1) will be changed to run from Overlap 12 and the normal vehicle head for phase 5 (channel 5) will be changed to run from Overlap 14.

Now the controller’s operation needs to be modified to allow the overlap setting work with the controller outputs.  This is done by modifying the Channel plus parameters, under MM-1-8-4.  Once you are at the screen, scroll to the right, to bring up the screen that shows channels 9 through 16.  Modify the settings as follows:

This screen allows the controller to override yellow indications on load switches 9 and 11 to flash yellow as a driven output.  Normally, the yellows on the pedestrian load switches are steady on during the FDW clearance phase.  The steady on is a NEMA TS2 output standard.  This screen is the final item in the controller that must be enabled to get the controller to flash the ped yellow outputs, to drive the flashing yellow circuit on the left turns.

Setting the Pedestrian Calls and Detection Diagnostics

  
Now the pedestrian need to be modified to allow for to allow the pedestrians for phases 9 and 11 be mapped to the phase 2 and 6 inputs.  This is done under MM-5-4

Note that the MaxPres column has values other than zero.  Setting a value to other than zero for the MaxPres allows the controller to look for malfunctioning pedestrian buttons – where they are locked on.  This is covered in more detail at: 

Setting Antibackup Operation

  
Now the antibackup feature needs to be set up, so that a ped call on phase 9 does not back up with a FYA on phase 5, nor a ped call on phase 11 does not back up to a FYA on phase 1.

The antibackup coding done via MM-1-1-5

Essentially, all of the work in the controller allows for the FYA to not operate across the pedestrian yellow

Setting Logic Processor To Serve the Side Street Before Serving Peds


One last thing needs to be done to the controller to allow the signal to cycle back to the pedestrian.  This is especially important to enable since the side street may have no traffic.  This is done by creating two logic statements to cause the signal to call a (typically) unused detector, and the detector then looks for an opportunity to call the side street.

The logic statements are coded under MM-1-8-7


 A quick conversion, from Section 12.6 and 12.7 of the Naztec controller manual
  • I 64         (detector 64)
  • I 130       (Ped call 2)  - The ped call is actually ped phase 9, but the physical input is 2 
  • I 134       (Ped call 6) –  The ped call is actually ped phase 10, but the physical input is 6
  • I 240       (logic flag)
  • I 241       (logic flag)
  • O 90       (Phase 2 on)
  • O 94       (Phase 6 on)
Keep in mind, if you are coding this in ATMS.now, the columns in the data input screen in ATMS.now do not coincide with the columns in the controller.
 
Something to keep in mind about the logic processor.  The controller processes the logic from top to bottom.  The logic flags are set up to allow the controller to allow either ped

Setting Logic Processor To Serve the Side Street Before Serving Peds

  
The last controller function to set is to create a dummy input for detection channel to call phase 4 (the side street phase).  In this case, I selected detector input 64.  This detector input is unlikely to be used in normal operation.  If the controller operations use input 64 for a specific detection input purpose, then another detector should be selected.

Set detector 64 to call phase 4 under MM-5-1

Set detector 64 to be a calling detector, and to be a locking detector for red and yellow operation under MM 5 2.

Something to keep in mind about the logic processor.  The controller processes the logic from top to bottom.  The logic flags are set up to allow the controller to allow either ped call to serve the locking call to the side street.  Another way to reduce the logic statements by 1 line would be to have two unused detector channels used to place the call to the side street.

The logic statements could also be coded under MM-1-8-7

In this case, both detector inputs 63 and 64 would be coded to place locking calls to phase 4.

Emergency Vehicle Preemption Operation


The EVP channels on the approaches with the FYA operation should be set under MM-3-(EVP channel <enter>)- 8 to turn on the All Red B4 Prmpt.  The factory configuration has this off.
 
If the all red before preempt is not turned on, then an EVP call on the approach will create a yellow trap for vehicles in the left turn pocket when the signal transitions to preemption.
 
As stated before, if the overlaps are on odd numbers and the controller is running in USER mode, it is quite likely that any EVP call will cause the controller to transition where the monitor sees steady greens on the main street thru phases, and steady yellows on the main street left turn phases – which is a conflict.  As of Apogee V.76.7D, it did not matter what particular EVP call, or if the all red before preempt was enabled, any EVP call would cause the signal to display the conflicting greens and yellows while the FYA overlaps are programmed to the odd phases.
 
The EVP channels need to be programmed for the appropriate phase and overlap operation.  
 
The overlap exit phases can be tricky.  Normally, the EVP channels are programmed to end the call on any approach with the main street green thru’s (in this case phase 2 and 6).
 
This creates a problem, when the signal controller is programmed for anti-backup on phases 2 and 6.  When the EVP call ends, and the signal transitions from any EVP to 2 and 6, it does just that, without reliably bringing up the FYA indications that correspond with the phase 2 and 6 operation.
 
In general, the EVP operation and end of phase is programmed for this signal as follows:
 
 
By exiting the side street EVP call to the same phase, the controller will come around to the next movement, which is likely 2 and 6 including the FYA for corresponding lefts.
 
By existing the main street EVP call to the main street lefts, the controller will quickly transition to the main street green with the FYA active.

Min or Soft Recall

Once the controller has the programming as shown above, one final step needs to be made.  Phase 2 and 6 need to be in either min or soft recall.  Otherwise, under low traffic volumes, the signal will rest in phases 9 and 10, and the FYA will not turn on to the drivers.
 
Now, the monitor operation must be modified to allow the FYA to operate.
 

Settings in the Reno 1600 MMU for FYA

 
The monitor needs to be set up for the FYA operation.  In this case, phases 3 and 7 are future phases.  There are multiple methods for setting up the monitor based on how the load bay is being used.  This method is consistent with the programming of the Reno MMU Application Note AN-005 Example 3. This technote is available at Reno A&E’s website at:
 
 
The particular screens for the Reno monitor for this operation in the test cabinet is as follows:
 
A couple of things to note. 
 
Load switch 1 and 5 are the steady RYG arrows of the FYA head.  Load Switches 1 and 5 need to have field check / dual enables turned on in the monitor.  With this done, the monitor should internally compare the load switch outputs of the 3 arrows on the load switch, with the corresponding flashing yellow arrow on the same 4-section head.
 
A flash transfer relay can go bad, where the outputs of the FTR are always flashing.  In one specific case during testing, the bad FTR caused load switch 1 and 5 to flash red, while the signal was operating with the flashing yellow arrow flashing on the same 4-section head.  While the monitor was set up to not have load switch 1 and 5 enabled for field check / dual enables, the monitor found no problems with the dual flashing of the FYA and the errant red flashing due to the bad load switch.  Once the field check / dual enables were checked for load switch 1 and 5, the monitor found the problem and kicked the signal into red flash.