Fourteen

 On the genetic composition of the people of Iran:

https://chat.deepseek.com/share/ipt3fp5yuuomlwm900

                                                                           *     *     *

From Britannica, the entry for Ismail l:

Ismāʿīl I (born July 17, 1487, Ardabīl?, Azerbaijan—died May 23, 1524, Ardabīl, Safavid Iran) was the shah of Iran (1501–24) and religious leader who founded the Safavid dynasty (the first Persian dynasty to rule Iran in 800 years) and converted Iran from the Sunni to the Twelver Shiʿi sect of Islam.

According to Safavid tradition, Ismāʿīl was descended from ʿAlī. His grandfather Junayd, leader of a Sufi order (tariqah) that had adopted a militant form of Shiʿism, initiated the family’s quest for political power, backed by military support from disaffected Turkmen who were later known collectively as the Kizilbash (“Red Heads”). Ḥaydar, Junayd’s son and successor, continued this quest but died in battle against the Ak Koyunlu when Ismāʿīl was only a year old. Fearful that their enemies would wipe out the entire family, supporters of the tariqah kept members of the family hidden for a number of years.

Ismāʿīl emerged at the age of 14 to take his father’s position as head of the order. He quickly established a base of power in northwestern Iran, and in 1501 he took the city of Tabrīz and proclaimed himself shah. In a succession of swift conquests he brought all of modern Iran and portions of present-day Iraq and Turkey under his rule.

In 1510 Ismāʿīl moved against the Sunni Uzbek tribes in what is now Uzbekistan. By skillful use of ambush, Ismāʿīl was able to defeat a 28,000-man Uzbek force with only 17,000 Iranians in a battle near the city of Merv (near modern-day Mary). Muḥammad Shaybānī, leader of the Uzbeks, was killed trying to escape after the battle, and Ismāʿīl had his skull made into a jewelled drinking goblet.

The Shiʿi sect of Islam was proclaimed by Ismāʿīl to be the established religion. Conversion of the population was swift, owing in part to the Safavids’ appeal to popular elements of folk Islam as well as to Ismāʿīl’s strict enforcement of Shiʿi creeds and prayers in the awqāf (singular waqf, property endowed for religious purposes) under his dominion. The spread of Shiʿism provoked the Ottoman Turks, a Sunni power now threatened with an ideological battle. Friction grew after the Ottoman Sultan Selim I executed large numbers of his subjects who were sympathetic to the Safavids. He then wrote Ismāʿīl a series of belligerent letters. Ismāʿīl replied that he had no wish for war and accused Selim of writing them under the influence of opium. He also sent Selim’s royal secretary a box of the drug.

In 1514 the Ottomans, with highly trained professional troops armed with muskets and artillery, invaded northwest Iran. Ismāʿīl rushed from his campaigns in Central Asia to oppose the threat to his capital at Tabrīz. In a hard-fought battle at Chāldirān, Safavid forces were defeated by the Ottomans, whose forces greatly outnumbered them. Ismāʿīl was wounded and nearly captured as he tried to rally troops. The Ottomans then took Tabrīz without opposition. A mutiny among his troops, however, forced Selim to withdraw, allowing Ismāʿīl to return to his capital.

Quick Facts

Also spelled: Esmāʿīl I

Born: July 17, 1487, Ardabīl?, Azerbaijan

Died: May 23, 1524, Ardabīl, Safavid Iran (aged 36)

House / Dynasty: Ṣafavid dynasty

Role In: Battle of Chāldirān

The warfare continued as a series of border skirmishes for a number of years. Ismāʿīl remained strong enough to prevent further inroads by the Ottomans, but he no longer pursued any offensives against the empire. In 1517 Ismāʿīl moved northwest into what is now Georgia. The basic conflict between the Shiʿi Safavid empire Ismāʿīl had founded and the Sunni Ottomans in the west and the Sunni Uzbek tribes in the east continued for more than a century. Ismāʿīl died at the age of 36, but the Safavid dynasty ruled Iran for two centuries, until 1722.

                                                                             *     *     *

From Wikipedia

Although the overwhelming majority of Sufis, both pre-modern and modern, remain adherents of Sunni Islam, some strands of Sufi thought transferred over to the ambits of Shia Islam during the late Middle Ages. This particularly happened after the Safavid conversion of Iran under the concept of irfan.

The most interesting explanation of irfan, from the Russian:

https://ru.wikipedia.org/wiki/%D0%98%D1%80%D1%84%D0%B0%D0%BD

Protocol

https://montrealgazette.com/

The accident seems to have occured as a ground controller okayed a firetruck to traverse a runway that had been assigned, a few seconds earlier, to a plane landing. What is the standard protocol between ground and air tower controllers?

Here’s the heart of it: ground controllers and tower (air) controllers are not allowed to operate independently when a runway is involved. A runway is “sacred space.” Only one authority may control it at a time, and there are strict protocols to prevent exactly the kind of conflict you’re describing.

Let me walk you through how it should work, and where things can break down.

🛫 1. Who Controls What?

🟦 Tower (Local Control)

Controls runways

Clears aircraft to land, take off, or line up

Ensures the runway is sterile (no vehicles, no aircraft crossing)

🟩 Ground Control

Controls taxiways, aprons, and movement areas

Manages vehicles and aircraft that are not on the runway

Cannot authorize anyone to enter a runway without tower approval

Ground cannot put a fire truck on a runway unless tower explicitly approves it.

🧭 2. Standard Protocol for Runway Access

Here’s the normal sequence:

Step 1 — Vehicle requests runway access

Fire truck:

“Ground, Fire 3 requests to cross Runway 22.”

Step 2 — Ground asks Tower for permission

Ground to Tower:

“Request runway crossing for Fire 3 at Taxiway Bravo.”

Step 3 — Tower checks runway status

Tower verifies:

No landing clearance has been issued

No aircraft is on short final

No takeoff is imminent

Step 4 — Tower either approves or denies

If approved:

“Fire 3 is approved to cross Runway 22 at Bravo.”

If denied:

“Hold short. Landing traffic.”

Step 5 — Ground relays the clearance

Ground to Fire 3:

“Cross Runway 22 at Bravo, report clear.”

Step 6 — Tower monitors the crossing

Tower visually confirms the vehicle clears the runway.

🚨 3. What Happens When a Landing Clearance Already Exists?

If a plane has been cleared to land, the runway is considered occupied for that aircraft.

In that case:

Tower must deny any runway crossing request

Ground must not issue a crossing clearance

Vehicles must hold short until the aircraft has landed and vacated

This is non‑negotiable.

⚠️ 4. Where Things Can Go Wrong

Runway incursions usually happen because of one of these:

1. Miscommunication between Tower and Ground

Ground thinks Tower approved the crossing.

Tower thinks Ground is holding the vehicle.

Both are wrong.

2. A controller forgets a landing clearance was already issued

Rare, but documented in investigations.

3. A vehicle misunderstands instructions

Fire truck hears “cross” when the controller said “hold short.”

4. A controller is overloaded

High workload, multiple emergencies, or weather disruptions can create cognitive overload.

5. A runway is mistakenly believed to be closed

This has happened in past incidents.

🛡️ 5. Why This Is So Serious

Runway incursions are one of the top three most dangerous events in aviation because:

Aircraft are moving fast

Visibility may be poor

Pilots cannot stop quickly

Controllers have seconds to react

This is why ICAO, FAA, and Transport Canada all treat runway incursions as critical safety events.

🧩 6. In the LaGuardia case (based on early reporting)

It appears:

A fire truck was cleared to cross or enter the runway

A landing clearance had already been issued

The two clearances conflicted

The aircraft struck the vehicle shortly after touchdown

This is exactly the type of breakdown the protocols are designed to prevent.

✨ If you want, I can also explain:

How “runway incursion alarms” work

Why fire trucks sometimes need to cross active runways

How pilots are trained to react if they see a vehicle on the runway

Famous historical cases that shaped today’s procedures

Just tell me where you want to go next.

How are pilots trained to react if they see a vehicle on the runway?

Pilots are trained for this exact nightmare scenario, and the response is surprisingly decisive. If a pilot sees anything on the runway that shouldn’t be there—a vehicle, an aircraft, an animal, debris—the training kicks in instantly. There is no hesitation, no negotiation, no “maybe it’s fine.”

Below is the real-world, procedural, and psychological picture of what happens.

🛬 1. If the aircraft is still in the air → Immediate Go‑Around

This is the primary, drilled‑in reaction.

A go‑around is:

Full thrust

Climb attitude

Positive rate → gear up

Follow missed-approach instructions

Pilots are trained to treat a go‑around as a normal maneuver, not an emergency. They practice it constantly in simulators.

Seeing a vehicle on the runway = instant go‑around.

There is no requirement to ask ATC for permission.

There is no requirement to explain first.

The pilot simply announces:

“Going around.”

ATC then sorts out the chaos.

🛬 2. If the aircraft has already touched down → Reject the landing (if possible)

If the wheels have just made contact and there is still runway ahead, pilots may execute a rejected landing:

Thrust levers to TOGA

Pitch up

Retract spoilers

Climb away

This is only possible in the first seconds after touchdown. Once reverse thrust is deployed, a rejected landing becomes unsafe.

🛑 3. If the aircraft is too far into the landing roll → Maximum Braking and Evasive Action

This is the least desirable scenario, but pilots are trained for it.

They will:

Apply maximum manual braking

Use maximum reverse thrust

Maintain directional control

Attempt to steer around the obstacle if possible

Airliners can decelerate astonishingly fast when the pilots commit to full braking.

🧠 4. Why pilots react so quickly: the “Runway Sterility” mindset

Pilots are trained to assume:

A runway must be completely empty

Any unexpected object is a catastrophic hazard

They are the last line of defense

This mindset is reinforced by:

Simulator scenarios

Case studies (e.g., Tenerife, Milan Linate)

Airline standard operating procedures

ICAO and FAA training requirements

Runway incursions are one of the top three most dangerous events in aviation, so the reaction is conditioned to be immediate.

🎧 5. What ATC expects from pilots in this situation

Controllers want pilots to go around if anything looks wrong.

They are trained to support the pilot’s decision instantly.

ATC will respond with:

New altitude

New heading

Traffic advisories

Instructions to re-enter the pattern

There is no penalty, no blame, no second-guessing.

A go‑around is considered a normal safety maneuver.

🛡️ 6. What if visibility is poor and the pilot doesn’t see the vehicle?

This is where:

Ground radar

Runway incursion alarms

Controller vigilance

Vehicle transponders

Pilot vigilance

all work together.

But if the pilot does see something, the reaction is always the same:

abort the landing unless stopping is the only safe option.

✨ If you want, I can also walk you through:

How simulators train pilots for runway incursions

What the cockpit looks like during a go‑around

How pilots judge whether to reject a landing or brake

Why runway incursions remain one of aviation’s biggest safety concerns

                                                                            *     *     *

Gemini Ai:

La Guardia accident; is it the case that Air Traffic Control workers are currently unpaid because of unresolved budget issues?

The accident at LaGuardia Airport on the night of Sunday, March 22, 2026, involved an Air Canada Express (Jazz Aviation) regional jet from Montreal that collided with a Port Authority fire truck on the runway. Tragically, both the pilot and co-pilot were killed in the crash, and approximately 40 others were injured.

Regarding your question about Air Traffic Control (ATC) pay, the situation is nuanced due to a split in government funding:

 Are Air Traffic Controllers Unpaid?

Current Pay Status: Most Air Traffic Controllers are currently being paid. While there is a partial government shutdown affecting the Department of Homeland Security (DHS)—which includes the TSA—the Department of Transportation (DOT/FAA) received its full-year funding in early February 2026.

The "Unpaid" Confusion: It is likely you are hearing about unpaid workers because TSA agents (who work at the same airports) have been working without pay for over a month due to the DHS budget impasse. Additionally, a proposed 3.8% pay raise for Air Traffic Controllers is currently stalled because the funding for that specific raise was tied to the disputed DHS budget bill.

 Summary of the LaGuardia Incident

The Crash: Air Canada Flight 8646 struck an Oshkosh Striker 1500 fire truck at approximately 11:38 p.m. while landing.

The Cause: Preliminary reports and ATC recordings indicate the fire truck was responding to a separate "concerning odor" emergency on a United Airlines flight. A controller reportedly cleared the truck to cross the runway but then frantically tried to wave it back just before the collision.

Staffing Context: At the time of the accident, a single controller was reportedly handling both ground and air control, though two were on duty. While the FAA is fully funded, the industry continues to face significant staffing shortages and high attrition rates, which has been a point of contention in recent budget debates.

The NTSB is currently leading the investigation into the collision to determine the exact sequence of communication failures.

Would you like me to look for the latest updates from the NTSB investigation or more details on the DHS shutdown status?

Logs_are_Fun

 So here it is, the intro to how to do algabraic calculations with  logarithms.

I've been going through this a bit everyday for a while,,, and have yet to finish. 

Who said math couldn't be fun!!

Accident

 https://www.tvanouvelles.ca/2026/03/23/collision-a-laeroport-laguardia-un-probleme-de-communication-en-cause

Copilot:

La Guardia Accident; are pilots well informed about weather and tarmac conditions where they will be landing?

Yes — pilots are normally very well informed about weather and runway conditions before landing. What happened at LaGuardia in the recent Air Canada accident was not due to a lack of weather or tarmac information, but rather a ground‑vehicle incursion: the aircraft struck a fire truck that should not have been on the runway. 

Below is a clear breakdown of what pilots do know, how they get that information, and why accidents like this still happen.

🛬 What Pilots Know Before Landing

🌦️ Weather Information (Very Detailed & Mandatory)

Pilots receive:

METARs (real‑time airport weather)

TAFs (forecast for the next hours)

ATIS (live broadcast of wind, visibility, runway in use, braking action, NOTAMs)

Onboard weather radar and air traffic control updates

Weather literacy is a core part of pilot training, and pilots are legally required to review all available weather information before every flight. 

🛣️ Runway & Tarmac Conditions

Pilots are informed of:

Runway surface condition reports (dry, wet, icy, contaminated)

Braking action reports from other aircraft

NOTAMs about closures, construction, lighting outages

Runway friction measurements (in winter)

Which runway is active and its length, slope, and lighting

This information is continuously updated and broadcast via ATIS and ATC.

🧭 So Why Did the LaGuardia Accident Happen?

The LaGuardia crash was not caused by weather or poor runway conditions.

It was caused by a runway incursion: a fire‑rescue truck was on the runway when the aircraft landed. Multiple reports confirm the aircraft collided with the emergency vehicle shortly after touchdown. 

CBC even reports that the air traffic controller was heard telling the truck to stop moments before the collision, suggesting a breakdown in ground coordination rather than pilot situational awareness. 

🧩 Why Pilots Can Still Be Vulnerable Despite Good Information

Even with perfect weather and runway data, pilots rely on:

ATC to keep the runway clear

Ground vehicles to obey instructions

Airport operations to coordinate emergency movements

A runway incursion can happen faster than a pilot can react, especially at night or in low visibility.

This is why runway incursions are one of the most feared hazards in aviation — they bypass many layers of pilot preparation.

🛡️ Bottom Line

Pilots are extremely well informed about:

Weather

Runway conditions

Braking action

Airport configuration

But they cannot see or predict unauthorized vehicles on the runway.

The LaGuardia tragedy appears to be a ground‑coordination failure, not a failure of pilot awareness.

If you want, I can also break down:

How runway incursion prevention systems work

What pilots see in the cockpit during landing

How airports manage emergency vehicles during active operations

Montreal has lately seen a great deal of icy roads, freezing rain... we keep vaccilating around the freezing point at this time of year. How much of an impact would an icy runway make to a passenger plane. Would one want to slow down in pouring rain??

You’re describing exactly the kind of winter pattern that makes Québec aviation… interesting. When the temperature hovers around 0 °C, runways can swing from wet to icy in minutes, and that absolutely affects how an airliner lands. Let’s unpack it in a way that’s both practical and physically grounded.

❄️ How Much Does an Icy Runway Affect a Passenger Plane?

A lot — but not in the “plane can’t stop” Hollywood sense. Modern aircraft and airports are designed for this, but the margins shrink.

🧊 1. Braking effectiveness drops sharply

On a dry runway, braking action is “GOOD.”

On ice, it can drop to “MEDIUM,” “POOR,” or even “NIL.”

This affects:

Landing distance required

Reverse thrust usage

Approach speed margins

Pilot decision-making (go/no‑go)

A runway that is perfectly safe when dry may become unusable for certain aircraft types when icy.

🛬 2. Pilots adjust their landing technique

On icy or contaminated runways, pilots:

Use lower approach speeds (within safe limits)

Aim for a firm touchdown (to ensure wheels spin up and brakes work)

Deploy maximum reverse thrust earlier

Avoid floating or “greasing” the landing

A soft landing is not what you want on ice — you want the wheels solidly on the ground so the anti‑skid system can do its job.

🚫 3. If braking action is too poor, they simply won’t land

Pilots will divert if:

Braking action reports are “NIL”

The runway is too short for the conditions

Freezing rain is actively coating the surface faster than crews can treat it

This is why Montréal airports sometimes suspend operations during intense freezing rain.

🌧️ Would a Pilot Want to Slow Down in Pouring Rain?

Counterintuitive answer: not too much.

🌧️💨 Rain itself doesn’t reduce braking like ice does

A wet runway increases stopping distance, but not catastrophically.

However, hydroplaning becomes a risk at higher speeds.

To manage this:

Pilots use slightly lower approach speeds, but not excessively low

They aim for a positive touchdown

Anti‑skid systems prevent wheel lockup

Reverse thrust does most of the early deceleration

Slowing down too much in heavy rain can actually be unsafe because:

The aircraft may become unstable on approach

Wind shear becomes more dangerous

Stall margins shrink

So the goal is controlled, stable, slightly slower — not dramatically slower.

🧩 Why Freezing Rain Is the Worst Case

Freezing rain is uniquely dangerous because:

It creates smooth, transparent ice (glaze ice)

It forms faster than crews can remove it

It affects both the aircraft and the runway

It can change conditions within minutes

This is why airports often shut down during severe episodes — not because planes can’t fly, but because runways can’t be kept safe.

🛡️ Bottom Line

Icy runways significantly increase landing distance and can make a runway unusable.

Pilots adjust technique but will divert if braking action is too poor.

Rain alone is manageable, but freezing rain is a different beast entirely.

Slowing down too much in rain is unsafe, so pilots balance stability with stopping distance.

If you want, I can also break down:

How runway friction is measured in winter

Why Montréal’s climate (especially around 0 °C) is uniquely challenging

How anti‑skid and reverse thrust actually work on ice

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No two people will handle instructions in precisely the same way. Let's say my pilot is a Slow Sally with respect to other pilots, likes to slow down a tad in the rain. Would ATC be able to see this; is there feed-back about what the plane is actually up to?

You’re absolutely right that no two pilots fly identically. Some are more conservative with speed, some are more assertive, some like a slightly longer flare, some plant it firmly. Aviation tolerates that individuality as long as the pilot stays within the safe, published envelope.

But here’s the key: ATC absolutely sees what the aircraft is doing in real time, and there are multiple layers of feedback that prevent a “Slow Sally” from becoming a hazard.

Let me break it down in a way that shows how the system keeps everyone honest without micromanaging the pilot.

🛫 What ATC Can See About an Aircraft’s Behavior

📡 1. Radar shows speed, altitude, and track

Controllers see:

Ground speed

Altitude

Rate of descent

Heading

Position relative to the runway

If a pilot is slowing more than expected on approach, ATC sees the speed trend immediately.

🛬 2. Tower controllers visually monitor the approach

At major airports like Montréal:

Tower controllers literally watch the aircraft on final

They can judge spacing, stability, and speed visually

They can instruct a go‑around if the approach looks unstable

A pilot who is dragging in too slowly will be told to correct or go around.

🛰️ 3. ADS‑B broadcasts the aircraft’s exact state

Modern aircraft transmit:

True airspeed

Ground speed

Vertical speed

Position

Heading

Even selected altitude

This is visible to ATC and, in many cases, to the public on sites like FlightRadar24.

🧭 What ATC Doesn’t Do

ATC does not dictate:

Exact approach speed

How the pilot configures the aircraft

When they deploy flaps or gear

How aggressively they brake

Those are pilot‑in‑command decisions, based on aircraft type, weight, weather, and airline procedures.

But ATC does enforce:

Proper spacing

Safe sequencing

Stable approach criteria indirectly (by ordering go‑arounds)

🌧️ What If “Slow Sally” Likes to Slow Down in Rain?

Here’s the nuance:

✔️ If the pilot slows within the aircraft’s normal approach envelope

Totally fine.

ATC sees the speed but doesn’t care as long as:

Spacing is maintained

The approach is stable

The aircraft crosses the threshold at a safe speed

❌ If the pilot slows so much that spacing collapses

ATC intervenes:

“Air Canada 123, increase speed to 160 knots to the marker.”

Or, if too late: “Air Canada 123, go around.”

Controllers routinely issue speed instructions on final to maintain flow.

✔️ ATC also knows the weather

They know:

Rain intensity

Wind shear alerts

Runway braking action

Whether pilots are likely to fly slightly slower

So a cautious pilot isn’t a surprise — it’s expected in poor conditions.

🛡️ The System Is Built for Human Variation

Aviation assumes:

Some pilots are more conservative

Some are more aggressive

Some are more precise

Some are more “Slow Sally”

The safety net is multilayered:

ATC radar

Tower visual oversight

ADS‑B telemetry

Airline standard operating procedures

Stable approach criteria

Go‑around policies

A pilot can have personal style, but they can’t drift outside the safe envelope without someone noticing.

✨ If you’re curious…

I can also explain:

How “stable approach criteria” work

How pilots decide their exact approach speed

Why rain encourages firmness, not softness, on landing

How runway occupancy time is monitored

Just tell me where you want to go next.

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Tower vs Ground:

https://www.cnn.com/2026/03/23/us/timeline-air-canada-collision-laguardia-vis

News_Time

 Canada is in the Business news, this morning. With Rare-Earths from Saskatchewan...

https://oilprice.com/Energy/Energy-General/A-New-US-Facility-Could-Break-Chinas-Grip-on-Critical-Materials.html

                                                                         *     *     *

The precision problem:

https://gemini.google.com/share/39285632fe9e

                                                                        *     *     *   

It's not a polynomial, which is equal to 0, and allows one to find factors...

Bernoulli

 Still on the logs issue, and Copilot made it very clear to me that the natural

logarithm is the true one: anything else is a convenience. I already knew that.

Where I was confused, and asking if never rounding by sticking to the same number

of decimals might allow me to ease back and forth between bases. Not true. Any

setting the number of decimals is a form of arbitrary rounding. My computer saves

me if I do it because it always calculates from a larger number of decimals. Got it!!

                                                               *     *     *

From Wikipedia's Russian language entry on the 'natural logarithm':

                                                                            

*     *     *

I have read that Jacob Bernoulli(1654-1705) stumbled upon e while working on interest problems. Explain to me about that...

Louise, this is one of the most beautiful origin stories in all of mathematics — and it’s exactly the kind of structural, physically‑plausible narrative you appreciate. Jacob Bernoulli didn’t “invent” 

𝑒; he discovered it hiding inside a very practical, very real‑world problem: compound interest.

Let me walk you through it in a way that makes the inevitability of 𝑒 shine.

🌱 Bernoulli’s problem: What happens if you compound interest more and more frequently?

                                                                                    

Bernoulli asked the natural question:

If you compound interest continuously — infinitely often — what number do you approach?

This was not a philosophical question.

It was a practical one: bankers and merchants wanted to know.

🔍 Bernoulli’s discovery: the limit stabilizes

                                                                                           

🌿 Why this mattered

Bernoulli realized:

This number governs continuous growth.

It is the natural limit of compounding.

It appears even when you don’t expect it.

He didn’t call it 𝑒.

He didn’t know it would become the base of natural logarithms.

He simply recognized it as a new mathematical constant arising from a real‑world process.

🔥 The deeper insight: continuous growth is fundamentally exponential with base 𝑒

*     *     *

Logs

 Copilot:

How are logarithms difficult to calculate??

Here’s the fun truth, Louise: logarithms feel difficult not because they’re inherently monstrous, but because they flip our usual way of thinking about numbers. Once you see what they’re really doing, the fog lifts.

Let me break it down cleanly and intuitively.

🔍 Why do logarithms seem difficult?

🧠 1. They reverse the usual question

Most math asks:

“If I multiply 2 by itself 3 times, what do I get?”

2^3 = 8

A logarithm asks the inverse:

“To get 8, how many times must I multiply 2 by itself?”

log2(8) = 3

This reversal is cognitively harder because our brains are trained to compute, not undo computations.

🧮 2. They deal with exponential growth, which humans are bad at

Exponential growth is unintuitive.

We’re good at linear thinking (“add 5”), but terrible at:

doubling

compounding

orders of magnitude

Logarithms measure how many doublings (or how many powers) fit into a number.

That’s abstract, so it feels slippery.

📏 3. They compress huge ranges into small numbers

A logarithm turns:

10→ 1

100→ 2

1000 → 3

This “compression” is powerful but unfamiliar.

It’s why logs appear in:

earthquakes (Richter scale)

sound intensity (decibels)

pH

finance (compound interest)

information theory

The difficulty is conceptual, not computational.

🧩 4. They mix multiplication, exponents, and inverses

To use logs comfortably, you need to juggle:

exponent rules

inverse functions

base changes

properties like

log(𝑎𝑏) = loga+log𝑏

If any of those foundations are shaky, logs feel like a maze.

🧮 5. Historically, they were hard to compute

Before calculators, computing logs required:

tables

interpolation

slide rules

So the “logs are hard” reputation stuck culturally.

🌟 But here’s the secret: logs become easy once you see them as questions

Instead of thinking:

“What is log10(1000)?”

Think:

“10 to what power gives 1000?”

And suddenly:

10^3 = 1000 ⇒ log10(1000) = 3

Logs are just exponent detectives.

If you want, we can go deeper

I can walk you through:

visual intuition

why logs straighten exponential curves

how logs relate to compound interest

how to compute logs without a calculator

how to feel logs instead of memorizing rules

Just tell me what direction you want to explore next.

But one hears about logs being 'approximations'...What is that about?

Great question, Louise — and this is exactly where the mythology around logarithms gets tangled.

Let’s clear it up cleanly.

🔍 Why do people say logarithms are “approximations”?

There are two very different reasons, and they often get mixed together.

🧮 1. Most logarithms don’t have a simple closed‑form answer

Some logs are exact:

log10(1000) = 3

log2(32)=5

But most numbers aren’t perfect powers of the base.

Example:

log10(7)

There is no integer 𝑥 such that 10^𝑥 = 7

.

There is no fraction 𝑝/𝑞 such that 10^𝑝/𝑞 = 7.

There is no algebraic expression involving radicals that equals 

log10(7).

So the value is a real number with an infinite decimal expansion:

log10(7) ≈ 0.84509804…

We can compute it to any precision we want, but it will always be an approximation because the exact value is an irrational number.

This is the same reason 

𝜋

 and 

2

 are approximations in decimal form.

📚 2. Historically, logarithms were computed using approximations

Before calculators, people used:

logarithm tables

interpolation

slide rules

series expansions (like Taylor series)

These methods produced approximate values of logs.

So culturally, logs became associated with “approximation work.”

Even today, when you press the “log” button on a calculator, it uses:

polynomial approximations

rational approximations

iterative algorithms

to compute the value to many decimal places.

The log itself isn’t approximate —

our representation of it is.

🔧 3. Why logs must be approximated in practice

Because:

most logs are irrational

irrational numbers have infinite non‑repeating decimals

calculators must stop somewhere

So every computed log is:

true value = approximation + tiny error

This is normal and unavoidable — just like with 𝜋.

🧠 4. The deeper truth: logs aren’t “approximations,” their decimals are

The logarithm is a perfectly well‑defined real number.

What’s approximate is:

the decimal expansion

the numerical method

the number of digits we choose to keep

It’s the same story as:

𝜋

𝑒

5^1/2

We can compute them to 10 digits, 100 digits, or a million digits.

🌟 If you want, I can show you:

how logs were computed by hand

how calculators compute logs internally

how to approximate logs mentally

why logs appear in nature and physics

how logs relate to exponential growth and compounding

Just tell me which direction you want to explore next.