Use a barometer to forecast wind direction and the character of upcoming weather.

Here are some general statements of wind-barometer indications that are generally applicable to all parts of the country:

The following table generally summarizes wind and barometer indications in the United States. The amateur forecaster should modify the table in accordance with his or her own observations.

Wind/Barometer Table

Barometer
(Reduced to Sea Level)
Wind Direction Character of Weather Indicated
30.00 to 30.20, and steady westerly Fair, with slight changes in temperature, for one to two days
30.00 to 30.20, and rising rapidly westerly Fair, followed within two days by warmer and rain
30.00 to 30.20, and falling rapidly south to east Warmer, and rain within 24 hours.
30.20 or above, and falling rapidly south to east Warmer, and rain within 36 hours.
30.20 or above, and falling rapidly west to north Cold and clear, quickly followed by warmer and rain.
30.20 or above, and steady variable No early change.
30.00 or below, and falling slowly south to east Rain within 18 hours that will continue a day or two.
30.00 or below, and falling rapidly southeast to northeast Rain, with high wind, followed within two days by clearing, colder.
30.00 or below, and rising south to west Clearing and colder within 12 hours.
29.80 or below, and falling rapidly south to east Severe storm of wind and rain imminent. In winter, snow or cold wave within 24 hours.
29.80 or below, and falling rapidly east to north Severe northeast gales and heavy rain or snow, followed in winter by cold wave.
29.80 or below, and rising rapidly going to west Clearing and colder.
Note: A barometer should be adjusted to show equivalent sea-level pressure for the altitude at which it is to be used. A change of 100 feet in elevation will cause a decrease of 1 /10 inch in the reading.

From http://www.almanac.com/content/predicting-weather-using-barometer-and-wind-direction


Using Weather Measurements to Predict the Weather
Meteorologists collect weather data many times every day. Why? Because atmospheric conditions change constantly. Collecting so much data allows them to track the changes and make a more accurate, up-to-date forecast. It also helps climatologists (scientists who study weather over long periods of time) to better understand what might be happening with climate change.
Read the following descriptions of air measurements used to forecast the weather. Notice that all measurements have to be considered in order to make an accurate prediction. You can’t consider just temperature, or relative humidity, or wind direction alone when trying to make a forecast. You have to understand each measurement and what it could mean to the larger weather picture. Only then can you put them together to make an accurate forecast.
Temperature
Temperature is a measure of the air’s hotness or coldness and is the most measured quantity of the atmosphere. Temperature is probably is easiest weather measurement to understand. Everyone knows that it’s hot if the temperature is 90 degrees or cold if it’s 20 degrees.
Temperature can affect the type of precipitation that forms. If atmospheric conditions are such that precipitation can occur and the temperature is above freezing, then rain may form. If the temperature is below freezing, then snow may form.
The type of precipitation is also affected by the temperature in the layers of atmosphere through which the precipitation falls. For example, if precipitation starts falling from clouds as snow and then passes through warmer layers of atmosphere, rains falls. If the rain then passes through colder layers of air, hail may form. Sometimes, the precipitation will not fall to the ground at all. If the air layers are dry enough, the moisture may evaporate before reaching the ground.
Humidity Humidity is the amount of water vapor in the air. Most atmospheric water vapor comes from evaporation of water from the ocean or other bodies of water.
Water vapor in the air greatly affects the type of weather we have. It is the source of all clouds, fog, and precipitation. Water vapor also helps warm the air when it absorbs energy from the sun.
Dew Point
Dew point is the temperature that air would have to be cooled to in order for the air to be saturated with water vapor. In other words, it is the temperature at which an object, such as a blade of grass or a car windshield, will become wet with water from the air.

Dew point affects how comfortable you feel. For example, let’s say it was 70 degrees one morning when you went to school and the dew point was 68. By afternoon, it warmed up to 90 degrees, but the dew point stayed at 68. That means that the air temperature would have to be cooled to 68 degrees for saturation ( when the atmosphere has a 100% relative humidity) to occur. You would definitely feel sticky and hot and you would think the humidity was very high! This would not be the case.

Dew point and humidity are important because water in the air, in the form of water vapor, clouds, or liquid, greatly affects the weather. How can dew points be used to predict the weather? In terms of weather, dew point is a good measure of the possibility of forming fog or having thunderstorms. It can also be a tool to predict low temperatures for the night.

Since dew point is the temperature the air would have to be for saturation to occur, if the difference between the air temperature and dew point is small, there is more moisture in the air and clouds and fog will likely form.

Variations in dew point occur day-to-day when new air masses move in. If the air mass is coming from an area that is warmer and over a body of water, the humidity and the dew point would increase. This could change the weather over the area.

If there is more water vapor in the air, the air rises more quickly. When air rises, it cools and condenses to form clouds. Heat is released from the cooling air, and updrafts of air can cause thunderstorms.

Relative Humidity
Relative humidity is the measure of water vapor in the atmosphere as compared to the vapor content at saturation levels. Saturated air has a relative humidity of 100%. Relative humidity is calculated by dividing the amount of water actually in the air by the amount of water vapor the air can hold and multiplying by 100. Relative humidity is reported as a percent. How can it rain if the relative humidity is less than 100%? It only has to be 100% relative humidity where the clouds and rain form—not near the surface. If air rises and cools, clouds form, and relative humidity increases. If precipitation falls from the clouds, it often falls into layers with lower humidity. The rain will evaporate which may increase humidity, but not enough to allow precipitation.
Wind speed and Wind direction
Wind is moving air caused by differences in air pressure. Air moves from an area of higher pressure to an area of lower pressure. If there were no wind, there wouldn’t be much day-to-day difference in our weather. Winds bring in different air masses and therefore, different weather patterns. If the wind has passed over a large body of water, it will have picked up more moisture which could bring precipitation. If the wind has passed over hot, dry land, the air mass will be hot and dry.

The greater the differences in air pressure, the greater the wind speed. The unit of measure for wind speed is the knot. Wind speeds are measured either going toward or away from the radar station that is recording the measurement.

If the wind is going towards the radar, the wind speed is recorded as a negative number. If the wind is heading away from the radar, it is recorded as a positive number.

For example, let’s say you were looking at a wind speed radar map to determine the wind speed for a particular area. The color on the map for the area is a deep purple represented on the color bar key for the map at the – 1 position. That would mean that the wind speed is 1 knot and the wind is heading toward the radar station. If an area is represented by the blue shade that would be 8 on the bar below, it would mean that the wind is heading away from the radar at 8 knots.

To get the wind speed in miles per hour, multiply the speed in knots by 1.15.

We usually do not need to know whether the wind is heading away from or toward a radar station, but the wind speed is often reported using the negative or positive numbers for additional information.

Our Earth has several wind patterns that are useful in predicting the weather. The jet stream is a high-speed band of wind in the upper troposphere layer of the atmosphere. The jet stream often "steers" surface features such as fronts and low pressure systems. The prevailing westerlies are winds coming from the west in the middle latitudes. Both wind systems greatly affect weather in the continental United States.
Atmospheric Pressure
Atmospheric pressure is a measure of the weight of air in atmosphere above us. Air is made up of molecules of elements in gaseous state and minute dust particles. The particles, having mass, naturally exert a force on everything below.

Measuring changes in air pressure is a valuable tool to predicting the weather because weather patterns move around in regions of high and low pressures. For example, a high pressure area usually indicates fair weather; a low pressure area usually indicates stormy weather. A sudden drop in air pressure often means an approaching storm.
From http://www.e-missions.net/wvstorm/?cat=2&sid=1&pid=31&page=Understanding%20We
Using winds and a barometer to make forecasts Here are some general statements of wind-barometer indications that are generally applicable to all parts of the country: "When the wind sets in form points between south and southeast and the barometer falls steadily,
a storm is approaching from the west or northwest,
and its center will pass near or north of the observer within 12 to 24 hours,
with wind shifting to the northwest by way of south and southwest.

"When the wind sets in from points between east and northeast and the barometer falls steadily,
a storm is approaching from the south or southwest,
and its center will pass near or to the south of the observer within 12 to 24 hours,
with winds shifting to northwest by way of north.
The rapidity of the storm's approach and its intensity will be indicated by the rate and amount of the fall in the barometer.

"As a rule, winds from the east quadrants and falling barometric pressure indicate foul weather,
and winds shifting to the west quadrants indicate clearing and fair weather,
but again there are exceptions and in some parts of the country these rules do not apply."


The following table generally summarizes wind and barometer indications in the United States. The amateur forecaster should modify the table in accordance with his or her own observations. The following show the wind direction, the barometer reduced to sea level and the character of the weather indicated:



SW to NW, 30.10 to 30.20 and steady - Fair with slight temperature change for 1 to 2 days.
SW to NW, 30.10 to 30.20 and rising rapidly - Fair, followed within 2 days by rain.
SW to NW, 30.20 and above and stationary - Continued fair, with no decided temperature change.
SW to NW, 30.20 and above and falling slowly - Slowly rising temperature and fair for 2 days.
S to SE, 30.10 to 30.20 and falling slowly - Rain within 24 hours.
S to SE, 30.10 to 30.20 and falling rapidly - Wind increasing in force, with rain within 12 to 24 hours.
SE to NE, 30.10 to 30.20 and falling slowly - Rain in 12 to 18 hours.
SE to NE, 30.10 to 30.20 and falling rapidly - Increasing wind, and rain within 12 hours.
E to NE, 30.10 and above and falling slowly - In summer, with light winds, rain may not fall for several days. In winter, rain within 24 hours.
E to NE, 30.10 and above and falling rapidly - In summer, rain probably within 12 to 24 hours. In winter, rain or snow, with increasing winds, will often set in when the barometer begins to fall and the wind sets in from the NE.
SE to NE, 30.00 or below and falling slowly - Rain will continue 1 to 2 days. SE to NE, 30.00 or below and falling rapidly - Rain, with high wind, followed, within 36 hours by clearing, and in winter by colder.
S to SW, 30.00 or below and rising slowly - Clearing within a few hours, and fair for several days.
S to E, 29.80 or below and falling rapidly - Severe storm imminent, followed within 24 hours, by clearing, and in winter by colder.
E to N, 29.80 or below and falling rapidly - Severe northeast gale and heavy precipitation; in winter, heavy snow, followed by a cold wave.
Going to W, 29.80 or below and rising rapidly - Clearing and colder.

Source: National Weather Service http://usatoday30.usatoday.com/weather/wfbarrow.htm
Submitted by uk.sci.weather on Mon, 21/01/2008 - 7:27pm.

Table relating wind direction to change in atmospheric pressure.

Ideally, these 'rules' should be used with other 'evidence'; for example, noting how the character of the sky changes over time, whether the wind is veering or backing, how fast (or otherwise) the pressure is changing. Neither does it (always) discuss the differences between on the coast, the coastal plains, or someway inland - these will make a difference in many situations. This table covers non of these points and therefore should be used with much caution.

BAROMETER RISING

 WIND  SPRING  SUMMER  AUTUMN  WINTER
 N  Mainly dry but cold weather. Night frosts.  Cold & dry except near east coasts.  First autumn frost is not far away; dry, sunny cold weather in the southwest.  Snow showers decreasing, followed by hard frost.
 NE  Cold, cloudy weather, with sunshine on western coasts.  Cool & cloudy in the southeast but fine & sunny in west & northwest.  A fine spell except near east coast.  A spell of severe weather in the north and Midlands.
 E  As NE, but more likely to persist.  Fine spell, breaking down later with rain from the south.  As NE  Cold or very cold, dry weather with serious risk of snow to follow.
 SE  A fine dry spell, relatively mild.  Two or three days of hot weather; thunder later.  'Indian Summer' weather.  As E, especially serious in late Winters. Persistent fog inland.
 S  A short warm spell.  A short, very warm spell.  As S, but less likely to persist.  Thick and persistent fog inland.
 SW  Good growing & sowing weather. Mild & mainly dry.  A warm spell with little rain, except on western coasts & hills, where drizzle likely.  Coastal & hill fogs in the west, but fine & mild inland.  Short spell of mild, cloudy weather, much hill fog.
 W  As SW  As SW  Temporary fine, mild spell.  As SW.
 NW  Showers decreasing. Short cool, dry spell.  As in spring, but cold (for summer).  Temporary cool spell with scattered showers.  Showers of sleet or hail, decreasing in frequency.

 

BAROMETER FALLING

 WIND  SPRING  SUMMER  AUTUMN  WINTER
 N  Snow/sleet showers, possibly thunder.  Cold thundery weather with hail.  Showers followed by night frosts.  Snow or snow showers, heavy on hills.
 NE  Rain in eastern areas, remaining dry in the west.  As in spring  Little immediate change.  Snow in eastern areas but not heavy.
 E  As NE  As NE  As NE  Thaw, possibly preceded by snow.
 SE  Rain approaching southwestern areas.  Thunderstorms.  Rain in the south, possibly heavy locally.  Heavy snow in the southeast.
 S  Rain imminent.  Rain & possibly thunder.  Rain imminent, probably heavy and prolonged.  As autumn. Very mild.
 SW  Rain imminent.  Rain imminent.  Rain & gales.  As autumn. Mild.
 W  Rain or showers.  As in spring.  Rain or showers. Mild weather continuing.  As autumn.
 NW  Showers & colder weather with hail and thunder.  As in spring.  Showery weather; risk of hail or thunder: cool.  Heavy showers of sleet or snow; risk of hail & thunder.

From: 'Experiments in Meteorology'

Some other rules based on observation of the barometer - published in Rinne, J., Koistinen, J., & Saltikoff, E. : Suomalainen sääkirja - etanasta El Niñoon. (In Finnish) Otava, Keuruu 2001. ISBN 951-9435-93-X
(With thanks to Elena Saltikoff for passing this on . . .)

Very basic barometer forecast rules

(NB ... assumes the unit is working properly!)

Look at the change in 3 hours.
If the pressure is descending, there is a low pressure coming.
If it's ascending (or rising), the low is passing or a high pressure is coming.
When the pressure is changing rapidly (> 6 hPa/3 hours), it's windy (or potentially windy).

More detailed:
Sinking (falling) slowly (0.5 - 3 hPa in 3h): low is weak, dying or moving slowly. You might get some rain but typically no high winds.
Sinking (falling) moderately (3-6 hPa/3h): rapid movement or deepening low. Moderate winds and rain in warm front. The low is passing you fast so day after tomorrow will typically be fine.
Sinking (falling) 6-12 hPa/3h: Storm.

And rise is connected to gradually drier weather.

[ N.B.
hPa (hectopascal) are the same thing as mbar (millibars), and in older publications and on older barometers, you may see the abbreviation 'mb', also meaning millibar. Typically the values (at sea level) will be within a range 50 hPa either side of 1000, but allow for some extremes at either end. An older barometer might have mmHg (i.e. millimetres of mercury, with numbers near 760) or even inHg (inches of mercury). ]

From http://weatherfaqs.org.uk/node/166
WIND DIRECTION AND WEATHER FORECASTING METEOROLOGIST JEFF HABY The wind direction will have an important influence on the expected weather. You can often be given a wind direction and you will have a pretty good idea of how the weather will change and what weather can be expected with that wind direction. The typical wind direction that a location has for a certain time of the year is called the prevailing wind. When the wind is from the prevailing direction then the weather is generally typical. When the wind shifts away from the prevailing direction then it often indicates atypical or changing weather. For your forecast location, note what type of environment is located in every direction from the location. Take Dallas for example, toward the southeast is the moisture source of the Gulf of Mexico; toward the east is the typically warm and humid southeast; toward the north are the plains which can bring in cooler air in the cool season; toward the west and southwest is a very dry high elevation climate; toward the south is the transition between the coastal area and dry portions of Texas. A wind from the north in Dallas will tend to bring in cooler and drier air; a wind from the southwest will bring in very dry air; a wind from the southeast will bring in warm and humid air. Just by noting the wind direction a forecaster gains an idea of what type of air mass is moving toward the forecast area. Wind direction changes often accompany changes in the weather. The air flows cyclonically around low pressure systems. If the wind changes direction in a cyclonic fashion it often means a low pressure or front is influencing the forecast area. A wind shifting from the south often means warmer air is approaching and a wind from the north often means cooler air is approaching. When the wind changes abruptly it could be a frontal passage or wind direction change caused by thunderstorm outflow. When the wind speeds are light then a change in wind direction is not as significant. You may have heard the phrase "winds will be light and variable". When the winds are light it indicates there is not much of a steering current to move the wind. When winds are light, mesoscale influences will tend to start influencing wind direction. The winds can continue shifting from a variety of directions when winds are light. When analyzing MOS data make sure to note the wind speed and direction over the course of the forecast period. That information alone can give you clues to what weather to expect. http://www.theweatherprediction.com/habyhints2/432/

Fair or Foul? How to Use a Barometer to Forecast the Weather

vintage aneroid barometer in wood casing

Finding out the weather forecast these days is as easy as turning on the TV or checking your phone. That wasn’t always the case, though. In the hundreds of years before television and even radio, people used more rudimentary devices to predict what the skies would bring in the coming days.

One of those tools was the barometer. Once common in aircraft, ships, and ordinary households across the world, it predicts approaching weather by measuring changes in air pressure. While technological advancements have replaced the humble barometer in meteorological circles, they’re still fun to have at home and know how to read.

In this article we offer a primer on the history of barometers, how they work, and how to use one today to predict the weather. Barometers allow you to feel more connected to the natural forces at work outside your window, and free you from being completely reliant on those oft-wrong apps and local forecasts (studies have shown that local meteorologists inflate the chances for poor weather because it garners better ratings!).
A Brief History of the Barometer

torricelli first mercury barometer

What started as an experiment in 1640 to prove the existence of natural vacuums led to the discovery of atmospheric pressure. In 1643, Evangelista Torricelli filled a long tube with mercury, closed the end, and placed it in a shallow, open cistern that also contained mercury. When the tube was opened, mercury flowed out and filled the cistern, but then stopped about a quarter of the way down the tube and didn’t continue to pour out. Something had to be pushing down on the mercury in the cistern to make it stop, and that something turned out to be the atmosphere itself, which had previously been believed to be weightless. And so the first barometer was born.
vintage barometer illustration next to looking glass mirror

As seen on the right, looking glasses (mirrors) were often placed near barometers and thermometers, as they helped people decide what clothes they were going to put on that day!

In just a couple decades, the instrument became available to well-to-do gentlemen and scientists of both the professional and amateur variety. Woodworkers in the late 17th century took great pride in fashioning elaborate housings for these new weather devices, and it became a popular sign of wealth and nobility to display a barometer in one’s home. The founders of our country were among those fond of them; both Washington and Jefferson made daily recordings of the air pressure in their journals.

decorative aneroid barometer for a mantle

In 1840, the first mechanical, non-liquid barometer was invented. It quickly took hold, not because of the concerns about mercury (like there are today), but because of the simplicity of transporting these devices. They were much smaller and therefore cheaper, as mercury barometers had to be at least 3 feet tall for the air pressure to even out the liquid pressure, which is necessary for the instrument to work. By 1900, the mercury barometer was largely replaced by these mechanical, or aneroid, versions, and barometers became more accessible for the common citizen.

Up through the 17th century, making forecasts from the data gleaned from barometers remained a very imprecise science; about all they did was predict storms when the mercury rapidly fell, and no one really understood the science of weather and atmospheric pressure yet. It wasn’t until the mid-1800s that English sea captain Admiral Fitzroy did some extensive experiments with his barometers and came up with the first detailed forecasting tables. He is now credited with starting the weather forecasting industry and he discovered the predictive significance of rising and falling barometric pressure (which we’ll get to shortly). At the same time Fitzroy was at work, meteorologists and weather hobbyists all across the world were adding to the data and the scientific understanding of how weather systems operate and move by trading letters with their fellow observers.

barometer weather station vintage

Once the telegraph was invented, and this swapping of information became far easier, weather forecasting really took off. Weather observations and data could now be rapidly transmitted and therefore graphed and analyzed. Forecasts slowly became more accurate, and noting how the ability to predict storms and frosts saved lives and aided commerce, agriculture, and the military, the government founded the Weather Bureau (now the National Weather Service) in 1870. Hundreds of Weather Bureau meteorological stations around the country relied on readings from barometers, thermometers, hygrometers (measuring humidity), as well as observations from the field and at sea, to offer forecasts to farmers, sailors, and ordinary citizens.
vintage saturday evening post cover april 1946 meteorologists forecast

Meteorologists continued to use traditional barometers well into the mid-1900s.

It wasn’t until the mid-20th century that computers began to be used in weather forecasting, and the use of traditional monitoring tools like the barometer really declined. While pressure readings are still obviously a major part of forecasts, it’s done digitally rather than by the manual analysis of readings.

While “analog” barometers are no longer employed by professional meteorologists, knowing how to use one is a neat skill to have. And the first step towards gaining that know-how is understanding what atmospheric pressure really is.
What is Atmospheric Pressure?
atmospheric pressure illustration

Air pressure decreases as altitude increases.

Atmospheric pressure — or barometric pressure — is simply the weight of the air at ground level. It’s a little easier to understand when you think about the concept of water pressure first. As you get deeper in water, the pressure increases. This is because as you descend, the built up weight of the water on top of you increases. In 1 foot of water, you have the weight of that foot of water pressing down on you. In 2 feet of water, you have the weight of an extra foot of water pressing on you. It’s quite logical, really.

Now, think of land as being the bottom of the atmospheric ocean. As was proven by Torricelli, air is not weightless. So barometric pressure is the weight of the air from the top of atmosphere all the way down to you. Understandably, pressure is lower as you get higher in elevation — there’s less air on top of you.

Atmospheric pressure is generally measured in inches of mercury (in America, that is — it’s in millibars in metric nations), which goes back hundreds of years to Torricelli’s mercury barometer, which in basic form was still used up until the last decade or so. With the dangerous liquid now being outlawed in most places, and more modern barometers taking hold, the measurement is starting to be replaced by what’s called hectopascals. It is basically a measurement of pounds per square inch, which is more accurate to what’s actually happening with the air. Either way, on any consumer barometer you see today, your measurement will be in inches or millibars.

Now that we know what pressure is, let’s see how it affects our weather. Or more accurately, how the weather affects air pressure.
How Weather Affects Air Pressure

One of things you see most frequently in weather forecasts is big “H” and “L” signs moving across a map. These are large swaths — usually many hundreds of miles across — of high or low pressure. There’s no number which indicates high or low; it’s merely a relative term — an area of high pressure is higher than what’s around it.

how high and low pressure systems work weather

An area of high pressure — i.e. more downward force — pushes air down. As the air descends, it warms, which inhibits the formation of clouds and storm systems. So high pressure is almost always a sign of good or fair weather.

Air, however, wants to rise. So once it hits an area of low pressure — where downward force isn’t as great — it will have that chance. As the air rises, it cools, which condenses and forms precipitation. Hence, low pressure is associated with poor weather (“poor” is of course a relative term — some folks really like storms and rain!).

barometer forecast map noaa

So you can imagine a patchwork of high and low pressure swaths across a map. These are created by wind, the rotation of the planet, the sun — all kinds of factors that are completely outside of human control or prediction. But what we do know is the type of weather that these differences in air pressure portend.

A barometer that has a high reading — meaning high pressure — and is stable, indicates good weather. You’re in the midst of a high pressure system. A barometer that is falling indicates that a low pressure system is moving in, and you can expect poorer weather. How bad that weather becomes is the result of how great the difference is between the high pressure and low pressure system. The bigger the difference, the more volatility there is in the atmosphere, and the stronger the storm. The smaller the difference, the less likely you are to see rain or storms.

Alright — you know about air pressure, and how it’s affected by the weather. Now we can learn about the types of barometers, and how to actually use them to predict the weather.
Types of Barometers

types of barometers vintage illustration

Through the years, various types of barometers have been used to aid weather forecasters and seamen alike. Let’s briefly take a look at them and how they work:

Mercury: As we know, this was the first barometer invented. It utilizes an open mercury cistern along with a closed tube at least 30 inches in height. The air presses on the open mercury, which raises or lowers the level of the mercury in the tube. Because of its use of a dangerous substance, you can’t find new models on the market today. There are modern versions that have basically the same mechanism, but use neither mercury nor an open pool, but rather a fixed amount of gas enclosed in the tube. Ultimately, these aren’t as accurate as modern versions.

vintage aneroid barometer illustration

Aneroid: Invented in 1844, the aneroid barometer is a non-liquid device. It utilizes a small metal box — called an aneroid cell — made from an alloy of beryllium and copper. Changes in air pressure cause the box to expand or contract, which drives mechanical levers that are then displayed on the face of the barometer. These are often the beautiful devices that you imagine seeing in old ships and weather stations, and are still used today in many cases.

electronic barometer

Electronic: As with every tool in our modern age, barometers used in modern navigation and meteorology are mostly electronic. How they work is a bit hard to understand, so I had to ask meteorologist and professor Jon Van de Grift to give it to me in the most layman way possible: “Electronic barometric sensors provide the user with an estimate of elevation above sea level. These incorporate a strain gauge, which is a thin wire that changes its electrical resistance as a result of atmospheric pressure acting on a diaphragm wrapped around it. The resulting change in voltage can be amplified and read by a converter, and eventually displayed to the user.”
Which Type Should You Buy?

vintage mercury barometer illustration

To my surprise, finding a barometer was incredibly challenging. There simply aren’t many options.

The first option — and the best for the true meteorologist — is to find a digital weather station, which will likely include a barometer, as well as other readings like temperature and humidity. You can sometimes get these at big box stores, sporting goods stores, and even nurseries/floral shops, but you are likely to be limited to just 1 or 2 models to choose from. Your better bet is buying one online, like this one. It has a sensor that you hang outside which then sends measurements to a digital reader.

The other option, besides buying an antique, is to get a handsome looking aneroid barometer from an online retailer. I looked all over town for one, and couldn’t get my hands on anything. And that’s in Denver — it’s not like it’s a small town. I ended up getting this model from Fischer. Aneroid barometers work really well, and look darn good on a wall as a manly decoration piece. It doesn’t matter if they’re inside or outside, but know that some things will affect readings, such as proximity to heating or cooling vents, as well as use of air conditioners or humidifiers.
How to Use a Barometer to Forecast the Weather

forecast weather vintage illustration

Now that you know the science, being able to forecast the weather is actually rather simple. And while there are some differences in using an aneroid or digital barometer, the principles in measuring and analyzing pressure are the same.
The back of an aneroid barometer. The holes at the top of plastic backing allow for air to flow through. The small screw on the bottom right edge is what's used to calibrate the device; I had to use a small eyeglass screwdriver to do so.

The back of an aneroid barometer. The holes at the top of plastic backing allow for air to flow through. The small screw on the bottom right edge is what’s used to calibrate the device; I had to use a small eyeglass screwdriver to do so.

Setting up your barometer is easy. For an aneroid version, you need to manually calibrate it. All this means is using a small screwdriver to set the hand (like on a clock) to match the current barometric pressure in your location (I use weather.gov). Once you’ve done that, it’s all set.

Digital barometers — usually included as part of a more comprehensive amateur weather station — do that part for you.

As we already learned, barometer measurements will either be in inches or millibars. Readings will generally be between 28 and 31 inches, usually measured to the hundredth decimal. Knowing just the number itself, however, isn’t all that helpful. What matters is in which direction the needle is moving. It’s the change in barometric pressure that helps forecast the weather. This means that static numbers with no indication of rising or falling aren’t generally very useful.

So, to get accurate predictions, you need to take a look at the barometer every few hours and see how the number is changing. Keep in mind that changes will seem miniscule; in the few weeks I’ve had my barometer it’s been between 30.00 and 30.30 the entire time, usually only moving .05-.1 in either direction on any given day.

On an aneroid barometer, you’ll have two hands. One will show the barometric pressure reading, and the other is a manual dial that you align to the pressure reading whenever you take a measurement. The purpose of the manual hand is so that you can quickly and easily see which direction the needle has moved, and how far, between readings:
Adjust the manual barometer

Adjust the dial on an aneroid barometer whenever you take a reading to align the manual hand with the measurement hand.
modern aneroid barometer reading

Then, next time you take a reading, you can quickly see which direction the measurement needle has moved. The current reading here is about 30.18 inches.
stormy reading on aneroid barometer

Aneroid barometers also usually have layman’s terms like “Stormy” and “Dry” on them. The idea is that barometer readings at certain levels will portend those weather conditions. Unfortunately, those terms really only work at sea level. Here in Denver — a mile above sea level — they’re nearly worthless. No matter to me — they add to the decorative appeal of the barometer.

On a digital barometer, you’ll most likely have indications of “rising” or “falling,” and perhaps even a graph — called a barograph — showing previous readings and trends. This will be more helpful and accurate for the true amateur meteorologist. Rather than having to chart or remember previous readings, the device does it for you.
acurite digital barometer

You can see the barometer reading in the lower left corner of this digital weather station. It includes a graph — called a barograph — which shows trends and movements in pressure.

Below is a basic chart which shows barometer readings and their correlated weather patterns to help you get started. Keep in mind that every location is different, and that a number of things impact a barometric reading, including temperature, elevation, humidity, etc. In an atmospherically volatile location like Denver — with the mountains rapidly affecting weather systems — some storms form too quickly to be picked up on. That’s just the nature of weather! Also keep in mind that barometers will only help you forecast for the next 24-48 hours or so. Since pressure systems last days and sometimes weeks, it can be a while before you notice any substantial difference in your readings.
barometer forecasting table

These are readings for sea level. You can use this calculator to adjust for your elevation. In my experience, rather than the numbers themselves, the rising and falling trends are more important. You’ll come to find the how and low points of the atmospheric pressure in your area, and soon be able to not rely on the chart.

After a few weeks of taking readings, you’ll come to know your local weather pretty well, and you’ll be able to determine what’s high, what’s low, what’s surprising, etc. Get out there and get forecasting!















 When you are at a constant elevation a barometer will measure the change in composition and density of the air mass above the barometer. The composition usually changes because of changes in humidity. The density changes usually as a result of a change in temperature of the air mass.

Roughly, falling barometric pressure typically leads bad weather, and rising barometric pressure indicates improving weather. Here are some generalizations about weather conditions that one can make from wind direction and barometric measurement changes from the National Weather Service:

    When the wind sets in from points between south and southeast and the barometer falls steadily, a storm is approaching from the west or northwest, and its center will pass near or north of the observer within 12 to 24 hours, with wind shifting to the northwest by way of south and southwest.
    When the wind sets in from points between east and northeast and the barometer falls steadily, a storm is approaching from the south or southwest, and its center will pass near or to the south of the observer within 12 to 24 hours, with winds shifting to northwest by way of north. The rapidity of the storm's approach and its intensity will be indicated by the rate and amount of the fall in the barometer.
    Winds from the east quadrants and falling barometric pressure usually indicate foul weather, and winds shifting to the west quadrants indicate clearing and fair weather.








Barometer Change Indicator
BAROMETER 	WIND 	WEATHER
High, steady 	SW to NW 	Fair with little temperature change for one to two days
High, rising rapidly 	SW to NW 	Fair with warmer weather and rain within two days
High, falling rapidly 	E to NE 	Summer: rain in 12 to 24 hours
Winter: snow or rain with increasing wind
Very high, falling slowly 	SW to NW 	Fair, with slowly rising temperatures, for two days
High, falling rapidly 	S to SE 	Rain, with increasing wind, in 12 to 24 hours
High, falling slowly 	S to SE 	Rain within 24 hours
High, falling slowly 	E to NE 	Summer: light winds, fair
Winter: precipitation in 24 hours
High, falling slowly 	SW to NW 	Rain within 24 to 36 hours
Low, rising rapidly 	Shifting to W 	Colder and clearing
Low, rising slowly 	S to SW 	Clearing soon and fair for several days
Low, falling slowly 	SE to NE 	Rain for one or two more days
Low, falling rapidly 	E to N 	Northeast winds heavy with rain or snow, followed in winter by cold