Sunday, October 27, 2024

USCG License Exams Come of Age — Tide Wise

 In 2020 NOAA announced that this was the last year they were going to authorize an annual set of tables for tides or for currents. The tables were called:

Tide Tables

2020 East Coast of North and South America Including Greenland

2020 Europe and West Coast of Africa Including the Mediterranean Sea

2020 Central and Western Pacific Ocean and Indian Ocean

2020 West Coast of North and South America Including the Hawaiian Islands

Tidal Current Tables

2020 Atlantic Coast of North America

2020 Pacific Coast of North America and Asia.

Prior to 2021, these were "the official sources." All other third-party printed or electronic  presentations of  US tide and current data, readily found along the waterways and cybersphere, were derived from these, sometimes mixing up actual locations or confusing standard times and daylight times. 

These are what we called "The Tide Tables" or "The Current Tables" that were either required or recommended to be on all vessels. These tables included daily data for numerous Reference Stations and then a Table 2 that included corrections to be applied to thousands of Secondary Stations.

That ended in 2021. And despite the fact that some third party companies still print these tables including the Table 2 data that they reproduce from the 2020 tables, the data are not valid. Hundreds of those secondary stations have been discontinued and values for many others have changed.

But more to the point at hand, up till just recently, the USCG license exams still tested on the Table 2 procedures using the old Table 2 data, which has been totally wrong for nearly 5 years now. Many schools around the country still teach this method as well.

The USCG has now corrected that and their new exams treat tides and currents in the modern, correct manner, which is outlined below.  This greatly simplifies this important part of navigation.  We wrote several notes on this in the past:

No More Tide and Currents Table 2 — Navigation Students Celebrate!  

and

NOAA Discontinues Tide and Current Books — What Do We Do Now?

You can review these for background and in the second one for step by step procedures for most efficient access to the new data, including how to make your own set of annual tables

Another aspect of the simplicity (progress) is that tide and current questions are now essentially the same for entry level OUPV license exams as they are for unlimited ocean master.

Here is an example.


The diagrams included are:


The solution to #36 is fast. Go to the time on the graph and read the speed, then note that the harmonic directions are given in the figure titles. 

That is the right answer to the test question, but not at all the guaranteed answer on the water. These currents are treated as pure reversing, with two directions only, but in practice they rotate, flowing with some strength in an ellipse of directions. The direction given is just the average direction around the time of peak flow at the long axis ends of the ellipse.

Question #35 asks about rotary currents, which is interesting in that the discontinued annual current tables did have a Table 5 listing details of rotary currents along the coasts. But like Table 2, much of the Table 5 data were not considered unreliable, so they have been discontinued. If we want coastal tidal currents, we should use the OFS model forecasts, which are very good. Nevertheless, we can answer this question by looking up any coastal station along the East Coast and seeing how long it takes between successive floods or ebbs, and it will be about 12 hr.

The tide problem, #37, is just as direct. We are between two stations that have different heights but we are only asked for time, and that is the same for both. If they had ask for height the answer would, presumably,  be (0.51+0.29)/2 = 0.4 ft.



(Tide heights are pretty uniform over large areas of open water, so the tide values are more likely to be correct out on the water than the current values — assuming the atmospheric pressure is about normal, and the wind has not been strong over the past 12h, and there is no unusual river run off, all of which can throw the water level predictions off a foot or two.)

Likewise for the other end of the license exam spectrum, unlimited master.



This the same as #36, but we have to adjust the time. Starting at 0130 we must travel 15 nmi at 10 kt which takes 1.5h so we get there at 0300.

Question #6 for unlimited master is the same as the #37 for OUPV.


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So the summary is the USCG exams now follow the existing procedures for tides and currents, which is tremendously easier and faster than it was before. It is a pity that the invalid Table 2 data (for tides and currents) are still being published by third party printers, but we should just know this, and move on.

Our main resource for all tide and current data is now www.tidesandcurrents.noaa.gov.  Please refer to the article above (What do we do now?) for the exact steps for the most efficient use of the NOAA site. The best procedure is not intuitive. What might seem an intuitive approach can lead to other types of data that you likely do not want. We want the types of data shown in these USCG exam diagrams. In that article there is also a video showing the steps.

The article also shows how to make annual tables for any station. It takes just 4 pages per year, per station. We do not need the historic books that covered all of North America. We need just the stations covering the tidal waters we navigate.

Our book Inland and Coastal Navigation covers the use of the NOAA website, and our Navigation WorkBook 18465Tr  has practice exercises. In practice a new challenge arises in finding the nearest station you care about (illustrated in the links above), or you can use a program like qtVlm or OpenCPN that used tested harmonic data from NOAA and they show where all the stations are.




Here is a video summary of this article, which includes a demo of our recommended approach to the NOAA data.



* * * Thanks to Seattle Maritime Academy instructor Robert Reeder for alerting us to these USCG exam updates.









Tuesday, October 1, 2024

Wreck Symbols on Electronic Navigational Charts (ENC)

The International Hydrographic Organization (IHO) describes light symbols as the most complex electronic navigational chart (ENC) symbols in their own published standard for the symbols called IHO Pub S-52, Annex A, Presentation Library. Anyone can download Pub S-52, but the Presentation Library costs 500 euros! Draft copies found online have many errors, and can lead to hours of wasted time with no productive results.

But the IHO does not give themselves all the credit they deserve regarding complex symbols. Let's take a look at the rules for wreck symbols on ENC, for example.

There are six wreck symbols presented below with the official IHO Symbol Explanations, followed by our notes on the required attributes, which are explained in more detail later in the post. Five of the six are essentially the same wreck symbols used on paper charts, but the complexity comes into play because now we know the rules that determine which symbol is used for which category of wreck, and this new specificity is both a virtue and a challenge to those who must display the proper symbols or write books on their meanings. Plus we have the all new concept of isolated danger symbol unique to ENC.

This type of symbol inquiry is good practice working with ENC objects and attributes, which will become more important to mariners as we learn to live without traditional paper charts, relying on the ENC as the only official nautical charts.

______________________________________________________________


Symbol Name: SY(WRECKS01) 

IHO Symbol Explanation: wreck showing any portion of hull or superstructure at level of chart datum. 

Attributes: VALSOU not given;  CATWRK = 4 or 5  or WATLEV = 1, 2, 4, or 5. This symbol means there is no sounding given for the wreck and some part of it is showing at all stages of the tide.

The IHO reference to "chart datum" means "sounding datum," which is always zero tide height on all ENC from any nation. 

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Symbol Name: SY(WRECKS04)

IHO Symbol Explanation: non-dangerous wreck, depth unknown.

Attributes: VALSOU not given; CATWRK = 1;  and WATLEV = 3. In other words, no sounding given, it is charted as not dangerous, and it is always underwater.

______________________________________________________________


Symbol Name: SY(WRECKS05)

IHO Symbol Explanation: dangerous wreck, depth unknown.

Attributes: VALSOU not given; CATWRK = 2;  and WATLEV = 3. In other words, no sounding given, charted as dangerous, and always underwater. 

Some symbol reference books imply that "dangerous" or "non-dangerous" is determined by the location of the wreck relative to the safety contour, but that is not the case. Dangerous or non-dangerous is coded into the ENC by the Hydrographic Office that made the chart, using rules they set. As noted below, NOAA charts all wrecks known to be shallower than 20.1 m as dangerous, keeping in mind that these are wrecks whose exact soundings are not known.

______________________________________________________________

Wrecks can also be plotted as a generic hazard (meaning rock, wreck, or obstruction) with one of these symbols when the value of sounding (VALSOU) of the wreck is known.

______________________________________________________________

Symbol Name: SY(DANGER01)

IHO Symbol Explanation: underwater hazard with a defined depth.

Attributes: VALSOU less than or equal to the mariner's choice of Safety Depth. The known  sounding is then printed in the center of the symbol. Black if less that the safety depth; gray if deeper.

______________________________________________________________

Symbol Name: SY(DANGER02)

IHO Symbol Explanation: "underwater hazard with depth greater than 20 metres." [SIC]

Attributes VALSOU greater than the mariner's choice of Safety Depth. 

The official IHO Symbol Explanation given above, taken from the latest edition Presentation Library, is not correct. There is a detailed Conditional Symbology Procedure (CSP) explaining when to use this symbol, and it is based on the Safety Depth, not on a fixed 20 meters depth. Both the US and the UK Chart No. 1 booklets include the incorrect reference to 20 meters. Consequently, some navigation apps (ECS) also do not make this depth distinction correctly, so the symbols in those apps do not change from blue to clear at the correct sounding. It is not a major effect navigationally, but reflects the complexity of the symbol.

The known  sounding is then printed in the center of the symbol. Black if less that the safety depth; gray if deeper.

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Wrecks can also be plotted as an isolated danger, depending on its location relative to the navigator's choice of requested safety contour.

______________________________________________________________

Symbol Name: SY(ISODGR01)

IHO Symbol Explanation: isolated danger of depth less than the safety contour.

Attributes:  This is a complex, but valuable symbol unique to ENC. It automatically replaces hazard symbols depending on the depth and location of the hazard. It warns us of hazards (based on our own definition of safe depth) that are located in deeper water where we would not expect them. 

Specifically, if a wreck is outside of the displayed safety contour and it has a sounding less than the requested safety contour—or its sounding is not given—then the wreck symbol is replaced with the isolated danger symbol—depending on several other properties of the wreck.  That procedure applies to all hazards (rocks, wrecks, and obstructions). 

Most ENC users are familiar with that role of the isolated danger symbol, but not so many realize that the reference sounding is the requested safety contour, not the displayed safety contour, and this is not at all clear in the IHO Symbol Explanation.

We have in practice two safety contours. We have the one we requested, say 8 m, and we have the one displayed on the screen, which might be 10 m, because only contours native to the ENC can be assigned as the displayed safety contour. This special contour is then made bold and it separates two prominent water colors, and also triggers various alarms when crossed. If our requested contour is not in the ENC, the next deepest contour is selected for display.

For example, we request a safety contour of 8 m, but there is none in the ENC, so the active safety contour displayed is at 10 m.  On the deep side of the 10 m safety contour there is a wreck with a sounding of 7 m. This is shallower than our requested 8 m and outside the displayed safety contour at 10 m, so this one will be replaced by an isolated danger symbol.

If we then change our requested safety contour to 6 m, the displayed safety contour will stay at 10m, but now our wreck is deeper than our requested safety contour, so it will not be replaced with an isolated danger symbol.

I might stress that this symbol depends on a value of the safety contour; whereas the distinction between DANGER01 and DANGER02 above (blue or clear inside a dotted oval) depends on the value of the safety depth. Some nav apps (ECS) do not follow the IHO and IMO guidelines of having a user selected safety depth in addition to the safety contour, so they then use the same value for both symbols.

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Those are all of the possible symbols for a wreck. Any wreck on the chart will be one of those symbols. The tricky part is how does a specific nav app (electronic charting system, ECS), decide which symbol to show? This is not such an easy question. The rules (outlined briefly above) are spelled out in the S-52 Presentation Library, which in turn depend on the specific attributes of the object WRECK. These attributes are encoded into the ENC using rules from another IHO standard called S-57.

The attributes of the object WRECK that determine how it should be plotted are:

WATLEV, water level effect 

VALSOU, value of sounding  

CATWRK, category of wreck

EXPSOU, exposition of sounding

Every WRECK must have a WATLEV, plus it must have either a VALSOU or a CATWRK. You can review these attributes at caris.com/s-57.


WATLEV describes the visibility of the wreck as the tide changes.   The options are:

ID    Meaning

1 partly submerged at high water  

2 always dry

3 always under water/submerged

4 covers and uncovers

5 awash

6 subject to inundation or flooding   

7 floating

A wreck with WATLEV = 3, always submerged, with no sounding given, will have one of the traditional wreck symbols we are used to from  traditional paper charts, WRECKS04 or WRECKS05.


VALSOU is a single number, the depth of the water over the wreck when the tide is 0.  This can be a positive number, such as 3.5 m, meaning when the tide is 0, the top of the wreck is 3.5 m below the surface, or it could be -3.5 m, meaning when the tide is 0, the top of the wreck is 3.5 m above the water. Negative soundings are drying heights. Depending on the range of the tide and the location of the object, it could be underwater at all tide levels, or it could cover and uncover with the tide, or it could be always visible to some extent regardless of tide height. A drying height sounding is shown underlined on the screen. We see wrecks that cover and uncover with known drying heights along or in the foreshore.

A known VALSOU means the wreck will be shown as one of the the three danger symbols shown above, and not the type of wreck symbol we were accustomed to on traditional paper charts.

The VALSOU relative to the mariner's choice of Safety Depth determines the symbol DANGER01 vs DANGER02, regardless of other attributes.

CATWRK can have a direct influence on the symbol used. The options are:

 ID Meaning

1 non-dangerous wreck

2 dangerous wreck

3 distributed remains of wreck

4 wreck showing mast/masts

5 wreck showing any portion of hull or superstructure

Each nation making ENC have to establish how they are going to define a wreck as dangerous or not.  It is not spelled out in the IHO S-57.  NOAA's own Chart Manual, Vol 3, Section 6.3.2 on ENC production states that all NOAA ENC will encode any wreck as dangerous if it is known to be shallower than 20.1 m. They do not need to know its actual sounding, only this limit.


EXPSOU has a more subtle effect on the symbol. The options are:

ID Meaning

1 within the range of depth of the surrounding depth area

2 shoaler than the range of depth of the surrounding depth area

3 deeper than the range of depth of the surrounding depth area

This attribute only affects whether or not a wreck symbol (or any hazard) can show up as an isolated danger symbol. If the exact sounding of a wreck is not known, but it is known that the depth of the wreck is deeper than the shallowest contour of the depth area it is in (ie EXPSOU = 1) then this wreck will not show as an isolated danger symbol. The goal is to avoid the unnecessary display of isolated danger symbols.

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This last detail (some hazards not showing up as danger symbols when similar ones do) is not crucial in practical use of ENC because the first thing we learn is we must cursor pick any object that might be crucial and the pick report will tell us all about the object and its attributes. Furthermore, isolated danger symbols are an all new concept in ENC that we are not familiar with on paper charts, so it would be rare to even know something is unique about any specific example.

Also we note the commonality of all hazard symbols on ENC. For most encounters it does not matter at all if we are avoiding a rock, wreck, or obstruction, and indeed more often than not they have the same symbols.

Here is a graphic summary of the wreck symbols


1.   Top of the wreck is 3 m above the water when the tide is zero. The underline means drying height.

2.   Sounding not known, but some part of the wreck must show when the tide is zero.

3.   Same as 2, but can be in deeper water if tall enough to show when tide is zero, i.e., if it is 5 m tall it could be in a sounding of 4 m.

4.   Sounding to the top of the wreck is 5 m, which is less than the safety depth so the sounding is printed black. 

5.   Encoded in the ENC as dangerous wreck, with no sounding given.

6.   Same as 5.

7.   Wreck located on the deep side of the displayed safety contour with a sounding less than the requested safety contour, which is usually same as safety depth, or the sounding is not given.

8.   Sounding to the top of the wreck is 15 m, which is more than the safety depth so the sounding is printed in gray. Black vs gray on the sounding color is a property of the sounding itself, not the wreck. It changes at the safety depth for all soundings on the screen.

9.   Encoded in the ENC as a non-dangerous wreck, with no sounding given.


Note this display uses the 2-color option, but using the 4-color option does not affect the wreck symbols.

A couple last details about the object Sounding (SOUNDG). 

A wreck with known sounding can also have an attribute Technique of sounding (TECSOU), and value 6 means "Swept by wire drag," so the the sounding is accurate.  When TECSOU=6,  the sounding gets underlined with a horizontal bracket, as shown below, which is in a sense a different wreck symbol, but it is actually the sounding symbol, not the wreck, that is different. These are fairly common in some areas. 



In contrast to that precsion, we have the opposite condition of a sounding or position that is uncertain, in which case we would see this wreck plotted this way,


A circle around any sounding, not just those on a wreck, means the value of the sounding is uncertain. There is an attribute QUASOU, quality of the sounding, that applies to wrecks and soundings in general, which can take on values of:

1 depth known
2 depth unknown
3 doubtful sounding
4 unreliable sounding
5 no bottom found at value shown
6 least depth known
7 least depth unknown, safe clearance at value shown
8 value reported (not surveyed)
9 value reported (not confirmed)
10 maintained depth
11 not regularly maintained.

Any value 3, 4, 5, 8, or 9 will trigger the circled sounding, which is SY(SOUNDC2).

Likewise, an uncertain position of the wreck, can also trigger SY(SOUNDC2).  The attribute QUAPOS, quality of the position, can have values of:

1 surveyed
2 unsurveyed
3 inadequately surveyed
4 approximate  (the old PA from printed charts)
5 position doubtful (the old PD from printed charts)
6 unreliable
7 reported (not surveyed)
8 reported (not confirmed)      
9 estimated
10 precisely known
11 calculated.

Any value not equal to 1, 10, or 11 will also trigger the low accuracy sounding symbol SY (SOUNDC2).

If there is such a QUAPOS value for the wreck, then an additional low accuracy symbol (?) will be attached to the wreck symbol as shown. This is symbol SY(LOWACC01). These can important annotations to the symbols, being the ENC equivalent of the "PA" (position approximate) or "PD" (position doubtful) labels that were very common on paper charts.  Very few non-ECDIS nav apps can show these symbols. Turn on Low-accuracy symbols in qtVlm to see them in action.

One thing we miss in the new NOAA Custom Charts (NCC) is the lack of these low accuracy indicators. The information is programmed into the ENC that the printed NCC are based upon, but the present version of the NCC app does not print them. 


Saturday, September 21, 2024

Learning Chart Navigation Using NOAA Custom Charts (NCC)

We are in the midst of a revolution in US nautical charting. Traditional paper charts (TPC) have been discontinued by NOAA — a process that started five years ago and is essentially completed now, Fall, 2024. There are a few TPC that can still be purchased from the NOAA print on demand (POD) outlets, but these are all marked "Last Edition" and none have been updated for many months, and never will be.

In short, there are no more TPC for marine navigation, but this is not such a shocking state of affairs as it might appear. There is a new style of paper chart that is intended to replace the TPC called NOAA Custom Charts (NCC) and going forward we will use these for our traditional chart plotting just as we did with the discontinued TPC. 

These new charts have in fact notable advantages over the TPC: one being we can make our own NCC using a NOAA online app that lets us choose the area we want to cover — we are no longer bound to the old, fixed regions of the TPC.  

We can also choose the chart scale we want and the paper size we want. The products we create are high-resolution precisely-scaled PDFs that we can print as we see best. We have an article on NCC printing options for the several standard NCC sizes. Quite a bit of money can be saved if we do not need the largest sizes printed on high-quality chart paper.  If we do want big charts on traditional chart paper, then we can have our own creations printed at one of the POD outlets by sending them your PDF, or you can without doing anything online, just contact them and ask for an NCC version of your favorite TPC.

The new version you will get for a favorite TPC will be essentially identical with regard to the charing in the water, even using the same ATON symbols you are used to. The land areas will have less detail for the time being, but this will improve in the coming months. In the end, the land areas of the charts could well have much more useful detail than the TPC they are replacing.

The NCC are based on the latest electronic navigational charts (ENC), which are updated daily at about 0500 UTC. 

The most important fact about these new charts is this: the way we plot our courses and solve for piloting fixes on a paper chart is exactly the same on NCC as it was with TPC. We will just be using chart sizes and areas of our choosing, rather than the fixed TPC options we had in the past. Now we can have a chart of our own Bay on 11x17 paper that we print at home or at the local Office Depot, or an overview that spans three of the past TPC.

Navigation schools also have much more freedom to set up practice exercises in various parts of the country since chartlets can be printed on letter paper. Note that when making your NCC, you have the option to add compass roses where yu want. So this, too, is an advantage as you can place these where ever you think best.

One handicap that they should overcome shortly is the absence of the Mean High Water (MHW) value for the chart. We need this to predict the range of lights and hilltops as well as to compute bridge clearances. Thus we must learn to look this up at www.tidesandcurrents.noaa.gov and then write it on the chart somewhere. Strangely, this important number is not so easy to find at NOAA, the video below shows how to find it from the ENC in the background of the NCC app.  MHW was always on every TPC, but they have yet to figure how to add it to NCC.

We have several related resources you can use to get involved with the new charts. Here are a couple:


How to make a simple NOAA Custom Chart




The State of NOAA charts last half of 2024


Resources on NCC including links to NCC app and videos on its usage.

NCC printing options

NCC POD Outlets


How do get a copy of a discontinued NOAA TPC


TPC are being replaced by ENC. Here is our portal to all issues related to ENC

www.starpath.com/getcharts

Nautical Chart Notes on NCC, TPC, and ENC


In our online navigation courses we now include exercises using NCC.


Friday, July 26, 2024

How to Get a Copy of a Discontinued NOAA Chart

Part 1. I know the name or number of the discontinued chart I want. 

(a) Go to Part 3.

 


Part 2. I do not know what charts were available that no longer exist.

(a) First we need to find out what charts existed. There is a list of all charts at NOAA but we cannot tell from that what they covered, so we use a trick to learn the names of charts and what they covered.  Download this file Historic_NOAA_charts.kml that we will then load into Google Earth (GE), which will show all the historic chart outlines.

 

Above is what you see after dragging the KML file onto GE, or maybe just double clicking the file might open GE and load the KML file.  Then you can zoom into see the charts.


(b) Mouse over a chart outline to highlight it then left click to get the info. This is an example of a discontinued chart, 18433 Haro Strait Middle Bank to Stuart Island. We once had a full set of these spanning the San Juan Islands at 1:25,000 but they are all gone. For now there is just one 1:80,000 for the whole region—but we should get new reschemed 1:22,000 set of ENC sometime early next year.

(Note that if the chart still exists, you can click one of the preview options and see it, but it is easier by other methods to do that....see starpath.com/getcharts.)

For this example, we assume this is the only one we want, ie we want a copy of the Last Edition of this chart, which was discontinued about two years ago—so the one we get is going to be out dated.

(c) Now that we know the chart we want, we can go to Part 3.



Part 3. Get a copy of a chart whose name or number I know

(a) Go this NOAA link historicalcharts.noaa.gov.

(b) On the first page, click the link to Hide the map search.


(c) Then enter the chart number... space is too small but it will take it!  Then press Search.



(d)  Now we see the chart we want, Last Edition of 18433. We can download a JPG of PDF of the image. These PDFs are not georeferenced, like the NCC PDFs are. So if we want to load this chart into a nav program, we might as well use the JPG, which we can manually georeference in several nav programs.  

We can also take a look at the chart with the Preview link. Again, we are looking at an historic item. We could have several reasons to want this, but we must remember it is outdated.


Same image zoomed in to show it is a high-res image.





Part 4. How to load a historic chart (georeferenced) into a navigation program

(a) To be added. It takes just a few steps and a minute or two!