Friday, July 22, 2022

Start Saying Goodbye to Your Favorite Paper Chart

This should not be a surprise. NOAA told us they were Sunsetting Traditional Paper Charts back in 2019 and that they would all be gone by the end of 2024. After these charts are gone, we will rely on electronic navigational charts (ENC) and the new NOAA Custom Charts (NCC) that we design on our own using an online NOAA app and print on our own in a size and quality we choose.

This note is an alert that this is happening at an accelerated rate... plus we  have a way now to know the status of our favorite charts.  In item (1) of our starpath.com/getcharts resource, go to the paper chart index on the left and you will see something like shown  below for the San Juan Islands area.

Notice a few things new. Several of the charts are now gray and their traditional names have been changed to be preceded by the letters "LE." This means "last edition." I have clicked one of them (it turns orange) to show its details on the right. Take notice of the text in red. This chart is no longer updated and will be removed on Oct 5, 2022—2 month and 13 days from today. The same with all of the gray ones.

These are not random, obscure charts. These are the main working charts for the San Juan Islands, and it is not just this area. The extent of cancelation is even higher on the Gulf and East Coasts.


All gray charts west of Alabama are schedule for cancellation same time as the West Coast (Oct 5, 2022). Those on the East Gulf Coast and on the SE Atlantic are scheduled for Jan 4, 2023—that is 5 months 14 days from today.


The Central Atlantic has a lot charts leaving on Nov 16, 2022, which is just 3 months and 25 days.

When these traditional charts are gone, there are two NOAA Print on Demand outlets that have announced on their websites that they are set up to print the new ENC versions of these same charts. In other words, they are considering making their own NCC that are the exact aspects, scales and sizes so you could just ask for the chart number. 

But it is not clear if that is the best solution. The NCC app gives the chart designer a lot of freedom on what is included and what exact area is covered and at what scale. I think it will be best for mariners to learn how to use the NCC app to make their own decisions on what paper charts they want to replace the old ones.  

Luckily, there is an easy place to go to learn to use the NCC app, namely the Starpath online Course on Electronic Chart Navigation, which includes our unique textbook on the subject. We focus on the actual ENC usage, but do have an extended lesson on how to make the NCC along with practice exercises and individual support.



Needless to say, the goal of the US National Charting Plan is not to navigate on these NCC, but rather to navigate on the ENC, which is what we teach. But NOAA knows that many mariners, if not most, do indeed want to have access to a paper chart at all times, just in case—and that is the main purpose of the NCC.

Beside NOAA doing away with the traditional paper charts in lieu of ENC and NCC made from them, the USCG is helping this transition along. They have just competed a call for comments on their proposed new ruling that commercial vessels must have on board a functional way (ECS or ECDIS) to use the official ENC. Third party charts that dominate the recreational echart world, do not count.

In short, we have arrived at the moment where we have gone from a time when the ENC were a legal alternative to paper charts to a time when ENC are the required means of navigation. We stand by to learn how this specific ruling evolves, and what all vessels will be covered, but it will indeed be enacted.

The side message to this note is this: knowing how to find these LE dates, if you want a copy of the last valid traditional paper chart, now is the time to order it.  Right now you can still even get a PDF of it.






Tuesday, July 5, 2022

Magnetic Variation on Electronic Navigational Charts (ENC)

Magnet variation (magvar) is crucial to marine navigation. It is the difference between true north and the direction of north read from a compass card, which is shown on the compass rose on a chart as the difference between true north and magnetic north. We might like to navigate by all magnetic bearings since we drive the boat by the compass, but we cannot avoid dealing with true bearings at times. Tidal current directions are always given in true, as are wind directions from any official forecast or observation. Charted navigation ranges are given in true, as are the visible boundaries of sector lights. Any cel nav solution must be worked out in true bearings, and so on. 

In short, we might avoid them whenever possible, but we have to deal with true bearings. But that is navigator talk. Normally you would communicate related results or desired courses to the helmsman in magnetic and you would expect all logbook entries to be in magnetic.

Working with magvar is just one more aspect of navigation that is improved with the use of ENC. Magvar is an ENC charted object, and we can cursor pick any place on the chart to see what the local value is at that point. ENC get the latest values (magvar drifts slowly with time) from the World Magnetic Model (WMM), which is updated every 5 years on the even 0s and 5s. The most recent is 2020; next update is 2025.

The image below shows how magvar varies over the country, along with its annual rate of change.


You can get a high res PDF copy including one for AK at the WMM link above. 

The line separating E and W variation goes through New Orleans. The 2020 value at the NW corner of the US at Cape Flattery is about +16º (16º E) with an annual rate of change in minutes of about -6'/yr (6' W)—at present rate, every 10 years it will change by 1º; but the rate of change also changes with time. The spatial distribution of this change is on the edge of a col (saddle point) at this location, so it is not easy to read from this plot, but the actual values are well known at all locations (see WMM link). The reference year for these values is 2020.

Why ENC are so much better than paper charts on this topic is tied to the fact that traditional paper charts are being discontinued and all will be gone by the end of 2024. Consequently they are not being updated except in crucial matters—getting the magvar wrong by a degree or so once in a while is not really crucial in most circumstances.

Most current (July 2022) ENC have the 2021 values encoded in the charts (corrected from 2020 WMM), whereas the latest paper charts or the raster navigational charts (RNC) made from them could be very old. Two examples are below.



This latest edition of 18484, Neah Bay at Cape Flattery, WA, refers to magvar data from 2006. If we use that to predict the present value, which you would have to do if this is the only chart you have, even with it being the most current version, we would figure 2022 -2006 = 16 yr x 11'/yr = 176' = 2.93º. In 2006 it was 18º 15' = 18.25º, so the 2022 value would be 18.25 - 2.93 = 15.32º E, which would round to 15º E. Paper charts refer to the change as annual "increase" or "decrease," whereas with ENC we have to think though the algebraic use of + and – signs. E is +; W is –.

Checking the latest ENC for this area we get 


Thus we see that the actual variation is 16º E - 1yr x 6'/yr, which is no notable change, leaving 16º E. In short, this latest paper chart has magvar wrong by just 1º even using this older data.

Neah Bay is remote, but Elliott Bay is not, being the access to Seattle. Below is the latest Elliot Bay Chart, 18449.


This latest printed chart value is from 2017, which means corrected from 2015 WMM. At 2022 we have 5 yr x 9'/yr = 45'=0.75º, which implies a current magvar of 15.25º E. We find the actual value from the latest ENC below.

An ENC pick report using the NOAA online ENC viewer. Here we are reminded that some ECS use only plain language names of objects and attributes, whereas others use only the so called acronyms (actually just abbreviations) for them... and some use both or offer the option, which is my preference.

The object is magnetic variation (MAGVAR); the attributes to this object are:

LNAM = "Long Name" a combination of several object ID parameters (not related to navigation; it is an object identifier, not an object attribute; rarely if ever shown in ECS)

RYRMGV = Reference year for magnetic variation

SORDAT = Source date, which, in this case, is date the data was posted

SORIND = Source indication, which is where the data comes from, an internal NOAA doc number.

VALACM = Value of annual change in magnetic (in arc minutes per year)

VALMAG = Value of magnetic variation (in whole degrees for an area magvar report.)

We always use RYRMGV for figuring the annual change, not the Source Date. In 2022, we have only a 6' change, so the actual variation at the moment is still 15º E, which is essentially what we got from the old data on the printed chart. This means that the rate of change changed at Neah Bay, but not so much here in Elliott Bay. It also shows why updating this magvar data is not a crucial paper chart update in most cases, and hence is not being done.

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With those basics behind us, there are a couple more subtleties regarding magvar in ENC. Below is an expanded section from our book Introduction to Electronic Chart Navigation.

2.13 Magnetic variation

We can get spoiled using ECS navigation, because we just push buttons to switch back and forth between magnetic and true directions. In a dark sense, we don’t even need to know what the variation is. It is rather like not needing to know how to divide, since we have a calculator in our phone, or how to spell, when there is a spell checker in everything we write with. This is just a small part of the slippery slope of electronic navigation, but still one to be avoided.

Magnetic variation (MAGVAR) is an S-57 object that can be encoded into an ENC as either an area or a point object. Area examples are shown in Figure 2.13-1. Some hydrographic offices include this data, but others (i.e., Canada) do not—inland ENC (Appendix 8) do not include MAGVAR in either the US or international versions. When MAGVAR is present as an area object we can find the value of the variation with a cursor pick at almost any place on the chart. The object has a scale minimum attribute (SCAMIN), so it might not be reported on all display scales. On NOAA charts, the SCAMIN value for MAGVAR seems to be the same as used for the soundings, so if you can see soundings you can see the variation symbol, and if not, you can’t—assuming the soundings display has not been turned off.



Figure 2.13-1. Another example of the value of the NOAA Online ENC viewer (Section 1.8), which has the instructive feature of outlining the boundaries of line and area objects when selected. Thus we can see the extents of MAGVAR area objects. We have made a composite of the reports to illustrate this pattern. In actual use, only one report at a time can be viewed. The MAGVAR areas can have other shapes, and the symbol changes locations as you view the area in different perspectives (called a “centered” symbol) The left-side inset shows the area object MAGVAR symbol; the right-side inset is a point MAGVAR object, showing just the value at that specific point. A hollow version of either symbol marks magnetic anomalies. The acronyms used in the pick report are explained in Figure 2.13-2. The scale minimum attribute of MAGVAR is typically the same as the soundings, so don’t expect the MAGVAR object to show up in a report if soundings are not showing. This image is from 2016.


There are symbols for magnetic variation seen periodically on the chart, although, as noted, we do not need to click it specifically to get variation. The symbols mark the identifying locations of the various MAGVAR area objects. These are the areas over which the variation is the same within one degree. These symbols are sparse in regions where the variation is not changing by one degree over the geographic span of the ENC cell. There is no correlation between the location of these MAGVAR symbols on an ENC and the placement of compass roses on the corresponding paper charts. On any ENC where we see a lot of these symbols it means the variation is changing by about 1º between the symbols. 

A sample cursor pick report for a MAGVAR area object is shown in Figure 2.13-2. This is in principle the same data we get from a compass rose on a paper chart—if the paper charts were being kept up to date in this regard, but they are not. Often we do not need the value any more precisely, and since we are unlikely to be using old ENCs (as opposed to sometimes using old paper charts) it would be rare we needed to correct for the annual change in ENC values.



Figure 2.13-2. Cursor pick report for object Magnetic variation (MAGVAR) at a point. Point symbols include a text label showing the Value of the variation (VALMAG) to the hundredth of a degree at that specific point (15.83º E) and the Reference year (RYRMGV). The actual point report (top) includes values to the tenth of both variation (positive values are east) and its attribute Value of annual change in magnetic variation (VALACM), which is always in arc minutes, with an annual change toward the east being positive, and toward the west negative. 

     The bottom part of the report is for the area value of the variation at that location, which will always be rounded to the nearest whole degree that is the average value for the local area. You would get this same area report by cursor picking any place near this point on the chart.

     Also shown is a MAGVAR area symbol, which is larger, in a fainter magenta, with no label. These symbols mark the area where the variation is constant to within 1º. These are elusive symbols (called “centered”), because they move on the chart as you change the display, staying as near the center of your screen as possible. They are identifying an area on the chart, not a point. Some ECS choose not to include these MAGVAR area symbols, as we can always get the variation with a cursor pick on the chart that reports the variation in that area. The only value of the symbol is to mark where the average variation is changing by 1º. More symbols (as seen farther north) indicate more change in the variation. Note that it can happen that an area average (15º in this case) is not the same as a point value in that area rounded to the nearest degree (15.8º in this case).

     Also shown for comparison is the symbol for a point report of a magnetic variation anomaly. An area of anomaly symbol is the same as the area symbol shown, but in outline only (see Chapter 4, Section B).


The exception comes when doing a compass calibration, in which case we want this as accurate as possible. On paper charts, variation is marked East or West and the change is marked "Increasing" or "Decreasing," but on electronic navigational charts (ENC) only algebraic signs are used. East is + and West is –. Thus when the variation and the change have the same sign, the value is increasing with time; when they are opposite, the variation is decreasing. A value with no sign is +.

The correction is done in the normal manner. Using the value of annual change from Figure 2.13-2, in 2024, which is 3 years after the reference year, the correction would be 3 x -6’ = -18’ = -0.3º. The variation is 15º E, correcting to the west, so the corrected value is 15º - 0.3º = 14.7º E in 2024. We do not use the high precision point value for this because that is the value at just that one point, which is unlikely to be where we are at the time. If the correction and the variation are in the same direction, then it is getting bigger with time.

A main takeaway here is that even though the charts are updated weekly and the computer knows the time and date, we must still treat magnetic variation obtained from an ENC as if we were reading it from a paper chart. With that said, we note that this data is typically no more than a year old in ENC, so it is rare that we would need this correction.

Direct computation of magnetic variation

One reason some hydrographic offices might decide they do not need to encode the magnetic variation is because many ECS programs (and presumably some ECDIS as well) have incorporated special software that can compute the magnetic variation accurately for any location and date. One example of such a program is geomag.exe from the National Centers for Environmental Information (NCEI). This program can be downloaded for personal use, even if not used as part of an ECS. See References.

With this, or a similar program, running in the background, a user can interrogate any location on the chart to obtain the magnetic variation—even without an ENC loaded for that location. What information you get from that and how you execute the request depends on the specific ECS that has this feature. It could simply report the variation in plain language or present something similar to an ENC pick report. When using this supplemental ECS feature to find variation for a specific date and place, it would be good practice to check that it agrees with the value given in the ENC for the location. 

These details of magnetic variation are important because ship captains are trained to make compass corrections accurate to a few tenths of a degree, which requires correspondingly accurate data. Accurate (point values) of the variation can be found at ngdc.noaa.gov/geomag/WMM. The World Magnetic Model (WMM) used for this is updated every five years. This program provides the variation values shown on ENC, so they should always agree.

Compass navigation is another advantage of ENC over traditional paper charts still in place that are in the process of being discontinued. Most paper charts do not have the latest MAGVAR data, some based on 2010 WMM data or even earlier models.


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