"Ready for sounding!", historical reconstruction film of a hydrographic survey in the early 1800s

This short film explains how the depth of the ocean was measured to make nautical charts during La Fayette’s time.

The Shom is the heir of the first national hydrographic service, the Dépôt des cartes et plans de la Marine, created in 1720.
Production by ECPAD, with the support of the Amicale des hydrographes, the Hermione - La Fayette association and the Ecole navale.

 A minute is a document used to prepare marine maps. It shows measured depths.
Minute of Gravelines (Hauts-de-France), 1879 

This movie (above) by the Shom has been produced on the occasion of the celebration of 300 years of French hydrography anniversary.

France was the first nation to establish a national hydrographic service.

On 19 Novembre 1720, was created the Dépôt des cartes et plans de la marine, which is Shom's precursor.

Saildrone forecast takes a data-driven approach to weather visualization

Saildrone Forecast iOS App Globe

From SailDrone

Saildrone Forecast for iOS is one of only a few weather apps to leverage the power of Apple’s Metal framework to animate global and local weather on one beautiful and accurate map.

No matter where you live on the planet, knowing the weather is integral to your daily routine: In deciding what to wear to work, school, or play, if you need to carry an umbrella or can leave your jacket at home, if the garden will get enough water or if the frost will come early.
Weather impacts transportation, commerce, and public health and safety around the world.
Many of us check the weather several times per day—starting with an early morning notification delivered to the lock screen on our smartphone.

Customize your daily weather notifications inside Saildrone Forecast or swipe right to add the Saildrone Forecast widget to your home screen for quick access to the forecast for your last searched location.

Weather forecasting is a notoriously tricky business.
Forecasters get little credit when they get it right, and a whole lot of flak when they get it wrong. Historically, one of the limitations to weather forecasting has been a lack of data.
While this is still true, especially over the oceans, the other significant challenge is how forecasts are communicated to the end user—you.

Satellites, weather buoys, and airport weather stations have drastically increased the amount of data forecasters have to generate weather models, but data deserts—like the deep regions of our global oceans—still exist, which is why Saildrone is working to deploy regional fleets of autonomous ocean drones from pole to pole, including the Atlantic and Tropical Pacific, to augment existing data collection infrastructure with the goal of improving global weather and climate models.

Saildrone believes that better inputs make better outputs, but communicating those outputs requires better visualizations that can provide insights at the planetary level as well as at the local street level, wherever users might be located around the world.
This is what drove us to develop an animated globe, rather than the more traditional static map typical of local weather reports.

Achieving this feat boils down to a complex data compute task that needs to be efficiently managed right on the user’s device.
Saildrone Forecast is one of only a few weather apps to leverage the full power of Metal, a breakthrough graphics processing framework developed by Apple.
Metal is extremely popular in the game world because it provides real-time graphics; in the Saildrone Forecast iOS app, it makes visualizing data on the globe possible.

The globe in the Saildrone Forecast iOS app is developed on Apple’s Metal framework.

Spin the globe around and watch as it loads temperature data in and out (shown on iPad).

Most apps (and websites) present the weather as a static or animated series of pictures.
The National Weather Service’s Doppler Radar National Mosaic shows precipitation moving across the country by looping several flat images together.
Projecting a globe onto a flat surface creates inherent distortions to the distance, shape, and/or size of countries and regions, making it even more difficult to display accurate weather forecasts—the size and intensity of storms, contours of clouds and temperature gradients, and the movement of winds around the planet.
Not to mention ocean currents.

Saildrone Forecast sends highly optimized weather data directly to the device and uses the Metal framework to visualize it on a 3D globe.
The result is not only smoother, more accurate animations over a selected time range, but it also creates the ability to customize the visualization on the fly—activating Local Colors on the Temperature layer, for example—and combine data together.
Saildrone Forecast uses a combination of precipitation and temperature to visualize rain, snow, and mixed precipitation.
In the wind layer, you can switch between wind particles and wind barbs that show the speed and direction of the wind in any given location as you move around the globe because we’re sending wind speed and direction data to the app.

On the left, exploring the life of humpback whales in Google Earth; on the right, wind conditions on the US eastern seaboard.

Saildrone Forecast also provides information about wind gusts as well as average wind in the Weather Graph.

The experience of exploring the globe in the Saildrone Forecast iOS app is a little like spinning the globe in Google Earth, except that Google Earth is essentially a globe-shaped geo-spatial encyclopedia of the planet combining satellite imagery and Google’s vast repository of knowledge, while Saildrone Forecast takes a data-focused approach providing a revolutionary view of global andlocal weather, updated sub-hourly.

The engineering challenge of rendering Earth as a 3D globe was accomplished a while ago; the next challenge is adding a large amount of dynamic data to a 3D globe with a lightning-fast user experience.
We wanted to create something new and magical, where the data feels continuous as you spin the globe around and zoom in and out.
Loading the data for the layer you’re exploring has been a significant engineering challenge, but we are proud of the result and hope you will enjoy the experience.

Watch as moisture that has evaporated from the Pacific Ocean falls as rain and snow over land.

Zoom all the way out, and you can watch clouds formed by evaporation in the Pacific Ocean make landfall over North America.
Zoom in, and you can see if those clouds will release rain or snow in your neighborhood messing up your morning commute.
When you zoom out, you’re looking at standard definition global weather—it’s a satellite’s-eye view of planetary weather.
As you zoom in, the definition increases, revealing finer gradients in wind, temperature, and precipitation.

In some regions, like around San Francisco, Saildrone Forecast uses a hyper-local Weather Research and Forecasting (WRF) model to display ultra-high-definition weather data that takes into account local topography to visualize how the wind funnels under the Golden Gate Bridge and wraps north around Angel Island (wind is forecasted at an industry-standard level of 10 meters [33 feet] above the surface).

Saildrone is committed not only to providing the data needed to further advance long and short-term weather forecasting—we’re also committed to putting the power of the weather forecast in your hands.
And, as Metal and the hardware that powers it continues to improve, so will Saildrone Forecast.

Download Saildrone Forecast for free from the App Store for iPhone and iPad.
An Android app is also in the works!
As always, we welcome your feedback as we continue to re-invent the weather forecast experience.

Resources:

European Centre for Medium-Range Weather Forecasts, "Experts review ocean surface observations for NWP," January 29, 2018

Links :

• Saildrones Complete First Unmanned Passage of Strait of Gibraltar / Saildrone & NASA: Increasing the Value of Remote Sensing Data / Surveying Commercially Important Fish Stocks in the North Sea

• Geogarage blog : The new ocean explorers / Saildrone launched with seafloor mapping ... /
  Ocean internet : sailing the wired seas / CSIRO to launch 'sailing drones' to monitor ... / No sailors needed: robot sailboats scour the ... / The drone that will sail itself around the world / Saildrone : a wind-propelled autonomous ... 

Canada (CHS) layer update in the GeoGarage platform

47 nautical raster charts updated & 1 new chart added

see GeoGarage news

American researchers want to fill the oceans with sensors

Ocean of Things

From The Economist by

Monitoring the high seas : They could track ships, storms, wildlife and weather

There is twice as much water on Earth as land.
Oceanographers are nevertheless fond of saying that science knows less about the high seas than it does about the moon.
If John Waterston gets his way, though, that could soon change.

Mr Waterston is the head of the “Ocean of Things” project at the Defence Advanced Research Projects Agency (darpa), an American military think-tank that has helped develop everything from the internet to stealthy fighter planes.
The project’s name is a play on the “Internet of Things”, the awkward phrase which describes the trend for stuffing sensors and an internet connection into all manner of ordinary objects, from cars and toothbrushes to factory robots and doorbells.
The Ocean of Things aims to likewise wire up the high seas with swarms of floating, connected sensors.

Such devices are not in themselves new.
There are around 6,000 floating sensors deployed around the world’s oceans, run by navies and research institutes.
What is unprecedented is the scale of Mr Waterston’s ambition.
Over the next few years he hopes to deploy 50,000 sensors across 1m square kilometres of sea, an area considerably larger than Texas.
The eventual goal—much more distant—is to enable the continuous monitoring and analysis of a significant fraction of the world’s oceans.

Peering into Neptune’s kingdom

The project’s main aim, mindful of the “d” in darpa’s name, is tracking ships.
But rather than building something that can do just one job, Mr Waterston wants the Ocean of Things to supply a wealth of other information, from water temperature to wave heights, weather conditions, nearby wildlife and more.
All this would then be made freely available to scientific and commercial users.

Existing “floating instrument packages”, known as floats or drifters, are often custom-built, and usually contain the highest-quality instruments available.
They therefore tend to be expensive, and are bought only in small numbers.
A typical existing float, designed for scientific research, is the Argo.
It costs around $20,000, and can measure water temperature and salinity.

The Ocean of Things takes the opposite approach.
The aim is to cram as many cheap, off-the-shelf components as possible into a single low-cost package.
Current float prototypes cost around $750, and Mr Waterston hopes that economies of scale could drive the cost down further.
That would allow tens of thousands to be deployed without breaking the bank.
Large numbers are crucial for coverage.
They also help compensate for inaccuracies in individual instruments.
“Can a $5 sensor do the same things as a $1,000 temperature gauge?” Mr Waterston asks rhetorically.
“The answer is ‘yes’ if you have a lot of them, because you can cross-correlate.
Maths solves the problem for you.”

The project’s researchers are evaluating three designs from different manufacturers, ranging in size from about six to 18 litres.
One, proposed by Xerox’s Palo Alto Research Centre, is made of glass, like a traditional Japanese fishing float.
A second, from a firm called Areté Associates, has an aluminium shell, and uses wood for buoyancy.
Both models feature solar panels.
The third, made by a company called Numurus, is made of lacquered cardboard, and relies entirely on its batteries.
All three are designed to last for a year or so and are made to be as environmentally friendly as possible, with minimal use of plastics.
That is important because, at the end of their mission, the floats are designed to scuttle themselves.

Some of the instruments on offer are common to any smartphone—gps sensors, accelerometers to detect motion, a compass, a microphone, temperature sensors and a camera.
Others are more directly tailored for the job, such as an underwater microphone, a gizmo to measure the water’s conductivity (and therefore its salinity), and detectors to pick up radar and radio signals, including transmissions from marine anti-collision beacons.
Some data from these instruments will be crunched on board, but most will be sent back to land in bursts, for onshore analysis.
For now, that connectivity is provided by the Iridium network of geosynchronous satellites.
But the modems necessary to talk to those satellites, says Mr Waterston, are the most expensive and power-hungry devices on the floats.
He hopes that new, lower-flying satellite networks, currently being built by firms such as Spacex and OneWeb, will provide cheaper alternatives.

Having lots of different sensors will help the floats build the best possible picture of what is going on around them.
For example, if the microphone picks up a sound at the same time as the accelerometer shows movement, it could mean that a bird has landed on the float.
Several birds landing on several floats could show how a flock is moving.
Their presence, in turn, might be an indicator of shoals of fish or other biological activity.

Similarly, a ship sailing through a float field will leave all sorts of traces.
It might be detected by its radio beacon, or its radar.
It might sail close enough for a float to take a picture, or hear it on the hydrophone, or be disturbed by its wake.
Correlating data from several floats will reveal the ship’s speed and direction.
By building a database of such encounters, the project’s scientists hope to learn quickly how to tell different sorts of craft apart.
Fishing vessels might be using fish-finding sonar or noisy trawl nets.
A giant supertanker will sound different from a naval frigate.

The range of sensors on a float will also produce a mass of data of interest to oceanographers, meteorologists and biologists.
The cameras and microphones on a field of floats could, for example, detect and track whales and dolphins.
At the moment, whenever a marine mammal is spotted in the shipping lanes off Los Angeles harbour, one of the busiest in America, traffic is slowed down.
Better tracking would allow traffic to be rerouted, benefiting both critters and commerce.
Float fields could watch for illegal fishing, smuggling and icebergs.
They could monitor and track oil spills and algal blooms.

That, at least, is the long-term goal.
So far, darpa has bought around 4,500 floats, and has tested them only in small numbers.
The next stage, starting this spring, will see fields of 1,000 at a time deployed in the Gulf of Mexico and in the waters off California.
The plan is to deploy one float for every three square kilometres of ocean.
The hope is that, as the technology matures, useful data could be gleaned from densities as low as one float per 20 square kilometres.
With 361m square kilometres of ocean on the planet, a true Ocean of Things, monitoring everything on and under the water, would require about 18m floats.
That will not happen for a while yet.
But Mr Waterston’s plans are a start.

Links :

• Datanami : DARPA Floats an ‘Ocean of Things’
• Signal AFCEA : DARPA's Ocean of Things Ripples Across Research Areas 
• GCN : DARPA takes the IoT to sea 
• Analytics India Mag : How India could use ocean-of-things to monitor its marine environment
• Entreprise Talk : DARPA Invests in Putting IoT Sensors At Sea
• Satellite Today : An Ocean of Things: IoT’s Role in Maritime Connectivity 
• Futurism : A Web of Sensors May Uncover Secrets of the Deep Oceans

‘We used to be leaders’: the collapse of New Zealand’s landmark ocean park

Kina barrens have proliferated with the decimation of their natural predators

From The Guardian by Kate Evans

Two decades since its creation the Hauraki Gulf Marine Park is overfished and overrun with sea urchins. Community groups are calling for urgent action to save the once abundant habitat 

Tiritiri Matangi is one of the jewels of New Zealand’s Hauraki Gulf.
For the past 35 years the island, which is within sight of Auckland’s skyscrapers, has been a protected nature reserve.

Tiritiri Matangi island in the Hauraki Gulf with the GeoGarage platform (Linz nautical chart)

Step ashore and you’re enveloped in birdsong: kiwi and takahē thrive here, and vegetation envelops the cliffs to the sea.
But beneath the waves it’s a different story.

Marine ecologist Dr Roger Grace warned of the destruction of the gulf’s ecosystem

“It was solid kelp forest, beautiful ecklonia, crayfish bristling out of every crevice,” marine biologist Roger Grace, who started diving here in the early 1960s, told me shortly before he died last year.
Now, the kelp and the crays are almost gone.

The bare rock is overgrazed by sea urchins, or kina, which flourishin the absence of snapper and crayfish, their natural predators.
The entire seascape is an impoverished and degraded landscape.
“People just don’t realise what’s happened before their eyes, because it’s out of sight,” Grace had said.
“Unless there are some radical changes, it’s not going to get better.”

Tiritiri Matangi is one of the island sanctuaries in the nature reserve

In 2000, New Zealand established its first national park of the sea, the Hauraki Gulf Marine Park. Covering 13,900 sq km (5,370 sq mile), the park’s objective was to protectthe gulf’s “life-supporting capacity”, its nature and its history.
The legislation required the slew of local councils and government departments with jurisdiction over the gulf to consider these objectives in planning or fisheries decisions.

However, with the exception of a handful of tiny marine reserves, commercial and recreational fishing was allowed to continue throughout the entire gulf.
Twenty years later, the creation of the park has failed to prevent ecosystem collapse.

Last week the government body charged with administering the park, the Hauraki Gulf Forum, released a report highlighting what had changed over those two decades.
“It certainly hasn’t lived up to the vision we all had, which was a thriving and healthy Hauraki Marine Park,” says Nicola MacDonald, the Māori co-chair of the forum.
“Our taonga [treasure] is dying.”

It remains legal to drag dredges and trawls across the sea floor, even recreationally, and no-take marine reserves have increased just 0.05% in two decades, to 0.3% of the Hauraki park.
Crayfish are functionally extinct in most of the gulf: the few that are left play no meaningful role in the ecosystem, for example in keeping urchin numbers down.
Kina barrens – those forests of sea urchins – are proliferating.

In 2019, after dramatic declines in the commercial crayfish take, the government slashed the daily recreational quota from six crayfish to three. Most divers are lucky to even find one.
The snapper population is down to about 20% of what scientists calculate pre-fishing numbers would have been.
Lifelong fishermen report the virtual disappearance of baitfish such as anchovies and pilchards.

In 2000, 4% of the seabird species in the gulf were threatened with extinction.
Today, 22% are.
Spotted shags, which once flourished in their tens of thousands, are down to 300 pairs; scientists suspect a lack of food.

On Auckland’s beaches, stormwater and sewage overflows make 38% of the 50 monitored sites frequently unsafe to swim.
Three sites are never safe to swim.

The dairy industry is another disruptive factor.
The nearby Hauraki Plains are New Zealand’s dairy heartland, and despite efforts by farmers to fence off waterways and plant trees, the rivers still pump fertiliser and effluent – and 3,730 tonnes of nitrogen – into the gulf each year.
High nitrate levels lead to algal blooms and ocean acidification.
Some estuaries are badly affected by sediment flows.

Human settlements are growing, too – faster around the gulf than anywhere else in New Zealand. Land clearing has caused sediment to collect elbow-deep in some estuaries, choking delicate organisms.

Critics say this is all the more upsetting given New Zealand’s past role as a marine-protection trailblazer.
The country is unlikely to meet its commitment under the UN sustainable development goals (SDGs) to conserve at least 10% of coastal and marine areas by this year, let alone contribute to the global push to protect 30% of the world’s oceans by 2030.

The minister for conservation, Eugenie Sage, admits the government won’t meet the SDG target this year. “Overseas, we’ve seen visionary initiatives by some of our Pacific neighbours – Palau, the Cook Islands – to extend marine protected areas,” Sage says.
“We are a long way back, and that’s really disappointing.”

Stormwater and sewage overflows disrupt the delicate marine environment

“We had the first no-take marine reserves in the world. What happened to that leadership position?” says James Frankham, the publisher of New Zealand Geographic magazine.
“We’re 20 years on from our landmark national park of the sea, and it’s crashing.”

Frankham, 45, grew up sailing, fishing and diving in the gulf, watching the water roil as seabirds plunged among kahawai and kingfish.

Last week he came away fuming from an event run jointly by the department of conservation and Auckland council, commemorating the Hauraki Gulf Marine Park’s 20th anniversary.
“I don’t come to outrage very easily as a person, but I was outraged by the lack of political action [being planned to address the issue].
“I’ve seen incredible change over my lifetime in the Hauraki Gulf, and my father and grandfather had stories [of an abundance of biodiversity] that were equally preposterous to me as the stories I’m telling my children today. It’s really heartbreaking. I can’t describe it as anything other than a collapse.”

Simon Thrush, head of the Institute of Marine Science at the University of Auckland, says the decline in animal populations is extremely concerning, although there is still time to turn things around.
“You can think of these collapses [in biodiversity] as a series of ratchets. It’s not a waterfall that’s 100 feet high and it tumbles off the top and smashes on the cliffs at the bottom.
It comes down in steps. We can still stop it falling off the next step.”

He argued for immediate action on every problem at once: more marine reserves, a halt to trawling and dredging, and more efforts by developers and farmers to keep sediment out of the gulf.
Although more research is necessary, too, he called for action on the studies already done: for example, his research in the 1990s demonstrated the negative biodiversity effects of bottom-impacting fishing gear, but fisheries management has not adapted to the problem.

“We need agencies to not just commission another report and have another meeting, but to do something,” he says.
“We need citizens to vote appropriately. We want as many people as we can to stick their thumb in the dike.”

There have been some positive developments.
A voluntary speed limit for container ships of 10 knots has effectively eliminated whale collisions.
The creation of the island sanctuaries, such as Tiritiri Matangi, appears to have reduced mammalian pests.
Commercial longline fishers are collaborating with NGOs and the government to reduce seabird by-catch, including trialling a device to bait lines underwater so birds don’t get caught in them. Community and local Māori groups are reintroducing native species to the islands, removing old moorings from bays and seeding juvenile mussels, which act as natural water purifiers.

Auckland council, meanwhile, admits many building sites haven’t complied with sediment control regulations and is trialling new ways to enforce them.
Stricter rules for farmers aimed at curbing run-off will come into force this year.

In 2016, a report titled SeaChange – a collective effort from a diverse group of gulf users, including commercial and recreational fishers, Māori and conservationists – made ambitious recommendations to address these issues.
This summer, four years later, a special government committee will finally report on which to adopt.

 Crayfish are now functionally extinct in most of the gulf

In the past, however, commercial and recreational fishers have blocked many protection efforts.
“In the marine space there are many who assert their rights and fewer who assert their responsibilities,” says Sage, the minister for conservation.
“Any change is hotly contested, and I hope now that people realise how serious it is and how urgent. Our shared goal must surely be a healthy Hauraki Gulf. I hope people are putting aside their individual interests on behalf of the common purpose of restoring the mauri [life force] of the gulf.”
“The one thing that everyone around the table wants is a return to abundance – but the means of getting there is going to hurt,” Frankham says.
“If we could have taken an aspirin 20 years ago, we’re on to chemotherapy now.”
“It’s critical if we’re going to argue that we’re truly a sustainable nation,” Thrush says.
“The Hauraki Gulf is an exemplar of how we manage what most of New Zealand is – ocean.”