mitchr...@gmail.com <mitchr...@gmail.com> wrote:
On Saturday, March 25, 2023 at 12:31:08 PM UTC-7, Jim Pennino wrote:
mitchr...@gmail.com <mitchr...@gmail.com> wrote:
They knew how to name it right.Yet it is used every day in real world applications but you would not
Square roots don't apply to quantities
that don't even exist. There is no
quantity below zero to use a square
root operation with.
Mitchell Raemsch
know that as your math understanding is 3rd grade at best moron.
There is no below zero. math has convinced itself that its imaginary
makes it important. There is no solution for the i formula.
Stop moving your i around jim. It does not change your "imaginary" plane.
Mitchell RaemschConfused, meaningless, moron babble.
On Saturday, March 25, 2023 at 9:01:12 PM UTC-7, Jim Pennino wrote:
mitchr...@gmail.com <mitchr...@gmail.com> wrote:
On Saturday, March 25, 2023 at 12:31:08 PM UTC-7, Jim Pennino wrote:Confused, meaningless, moron babble.
mitchr...@gmail.com <mitchr...@gmail.com> wrote:
They knew how to name it right.Yet it is used every day in real world applications but you would not
Square roots don't apply to quantities
that don't even exist. There is no
quantity below zero to use a square
root operation with.
Mitchell Raemsch
know that as your math understanding is 3rd grade at best moron.
There is no below zero. math has convinced itself that its imaginary
makes it important. There is no solution for the i formula.
Stop moving your i around jim. It does not change your "imaginary" plane. >> >
Mitchell Raemsch
Imaginary math produces imaginary results. Dumb, gullible people believe this nonsense.
People that believe in imaginary math are unable to show that it is useful. But when asked they will demonstrate that it is internally consistent and declare victory.
There is a world of Jim Penninos out there that are happy to prretend to understand what actually makes no sense.
Claudius Denk Delusionally Insane Crackpot
Imaginary math produces imaginary results. Dumb, gullible people believe this nonsense.
People that believe in imaginary math are unable to show that it is useful. But when asked they will demonstrate that it is internally consistent and declare victory.
There is a world of Jim Penninos out there that are happy to prretend to understand what actually makes no sense.
You might try Googling: electrical engineering complex numbers .
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:complex numbers.
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in thecomplex plane.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:complex numbers.
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in the
Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
What do you think this means?
Claudius Denk / Delusionally Insane Crackpot
.
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
What do you think this means?
Claudius Denk <claudi...@gmail.com> wrote:complex numbers.
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in the
Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"If you were not terrified to read any books you would know that ALL
math is a "representation".
What do you think this means?That you would think this way means you are an uneducated delusional crackpot.
Claudius Denk / Delusionally Insane Crackpot
.
On Monday, March 27, 2023 at 6:01:10 AM UTC-7, Jim Pennino wrote:complex numbers.
Claudius Denk <claudi...@gmail.com> wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
the complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in
Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.
If you were not terrified to read any books you would know that ALL
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
math is a "representation".
What do you think this means?That you would think this way means you are an uneducated delusional
crackpot.
Claudius Denk / Delusionally Insane Crackpot
.
The i formula has no solution. That is why math named it right.
It is something they manipulate... but only in their imagination...
On Monday, March 27, 2023 at 6:01:10 AM UTC-7, Jim Pennino wrote:
Claudius Denk <claudi...@gmail.com> wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
If you were not terrified to read any books you would know that ALL
math is a "representation".
What do you think this means?That you would think this way means you are an uneducated delusional
crackpot.
Claudius Denk / Delusionally Insane Crackpot
.
The i formula has no solution. That is why math named it right.
It is something they manipulate... but only in their imagination...
On 2023-03-27 2:26 AM, Claudius Denk wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
What do you think this means?That your assertion that complex math isn't useful
Claudius Denk <claudi...@gmail.com> wrote:complex numbers.
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in the
Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"If you were not terrified to read any books you would know that ALL
math is a "representation".
On Monday, March 27, 2023 at 6:01:10 AM UTC-7, Jim Pennino wrote:are complex numbers.
Claudius Denk <claudi...@gmail.com> wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote: >>
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i
the complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in
capacitance. Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
Fortunately, not all math is an imaginary representation.So, it's a "representation"If you were not terrified to read any books you would know that ALL
math is a "representation".
On Monday, March 27, 2023 at 6:01:10 AM UTC-7, Jim Pennino wrote:complex numbers.
Claudius Denk <claudi...@gmail.com> wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote:
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i are
the complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in
Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the capacitance.
If you were not terrified to read any books you would know that ALL
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
math is a "representation".
Fortunately, not all math is an imaginary representation.
On Monday, March 27, 2023 at 6:26:44 PM UTC-7, Claudius Denk wrote:are complex numbers.
On Monday, March 27, 2023 at 6:01:10 AM UTC-7, Jim Pennino wrote:
Claudius Denk <claudi...@gmail.com> wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:
On Sunday, March 26, 2023 at 4:42:40 PM UTC-7, Joel Davidson wrote: >> > >>
You might try Googling: electrical engineering complex numbers .Well, since you suggested it, I asked an AI source, pasted here...
"In electrical engineering, complex numbers are often used to represent sinusoidal waveforms and the behavior of electrical circuits.
A complex number is a number of the form a + bi, where a and b are real numbers, and i is the imaginary unit, which is defined as the square root of -1.
In electrical engineering, complex numbers are often used to represent voltages, currents, and impedances in AC circuits. For example, the voltage across a resistor R with current i flowing through it can be represented as V = iR, where V and i
the complex plane.
The magnitude of a complex number is given by its absolute value, which is the square root of the sum of the squares of its real and imaginary parts. The phase of a complex number is given by the angle it makes with the real axis when plotted in
capacitance. Similarly, the impedance of an inductor is given by Z = jwL, where L is the inductance.
The behavior of circuits with capacitors and inductors can also be represented using complex numbers. The impedance of a capacitor is given by Z = -j/(wC), where j is the imaginary unit, w is the frequency of the AC signal, and C is the
Fortunately, not all math is an imaginary representation.If you were not terrified to read any books you would know that ALL
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
math is a "representation".
The complex plane is. Stop moving your i around...
it does nothing...
Mitchell Raemsch
On Monday, March 27, 2023 at 12:02:01 PM UTC-7, Joel Davidson wrote:
On 2023-03-27 2:26 AM, Claudius Denk wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:That your assertion that complex math isn't useful
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
What do you think this means?
I never said this.
believe this nonsense.Imaginary math produces imaginary results. Dumb, gullible people
useful. But when asked they will demonstrate that it is internallyPeople that believe in imaginary math are unable to show that it is
prretend to understand what actually makes no sense.There is a world of Jim Penninos out there that are happy to
On 2023-03-27 9:23 PM, Claudius Denk wrote:
On Monday, March 27, 2023 at 12:02:01 PM UTC-7, Joel Davidson wrote:
On 2023-03-27 2:26 AM, Claudius Denk wrote:
On Sunday, March 26, 2023 at 7:38:25 PM UTC-7, Paul Alsing wrote:That your assertion that complex math isn't useful
By using complex numbers, it is possible to perform calculations involving AC circuits using the same algebraic rules as for real numbers. This makes it easier to analyze and design circuits, especially those with multiple components."
So, it's a "representation"
What do you think this means?
I never said this.On 2023-03-26 1:20 PM, Claudius Denk wrote:
believe this nonsense.Imaginary math produces imaginary results. Dumb, gullible people
useful. But when asked they will demonstrate that it is internally consistent and declare victory.People that believe in imaginary math are unable to show that it is
prretend to understand what actually makes no sense.There is a world of Jim Penninos out there that are happy to
*Ahem.* I quoted that in my first message to you
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