Wow43 mining light column plug in
below are links and introctions
http://bbs.game.mop.com/viewthread.php?tid=1706914&extra=page%3D1%26filter%3Dtype%26typeid%3D217
plug in information:
plug in name: gathermate, collection assistant
plug in author: moonfann (aka kagaro), Xinhuan, ammo, nevcairiel
plug in version: r70490
plug in name: collection route routes
plug in author: grum, Xinhuan
plug in version: r69846
why three plug-ins stick together because they complement each other and are more powerful and easy to use
My plug-in package includes these three plug-ins and I think they are easy to use, It also saves resources, so I opened this post to share with you.
download on Nga!
because you can't make sure that your number will not be lost
it is recommended that you
check the Sina Warcraft column on the Internet
it seems that there is an introction
nagland
and the location of some maps
you can download it
and then have a look at it if you have nothing to do
practice makes perfect
just remember the approximate location
The formula of electric field strength of vacuum neutral point charge: e = KQ / R2 (k is electrostatic constant, k = 9.0) × 10 ^ 9N. M ^ 2 / C ^ 2)
uniform electric field strength formula: e = u / D (D is the distance between two points along the direction of electric field strength)
applicable definition formula in any electric field: e = f / Q
electric field strength between parallel plate capacitors e = u / D = 4 π KQ / es
the electric field strength of the point charge in the medium: e = KQ / (R2)
the electric field of the uniformly charged spherical shell: e = 0, e = K × Electric field intensity of Q / r2
infinite straight line: e = 2K ρ/ r ρ Is the linear density of charge, R is the distance from the straight line)
the electric field intensity of the charged semicircle to the center of the circle: e = 2K ρ/ R ρ The electric field intensity on the central axis passing through the axis is kqh / (H2 + R2) 3 / 2
extended data:
calculation:
the electric field intensity at a certain point in the electric field is numerically equal to the electric field force on the unit charge at that point. The electric quantity and volume of the test charge should be small enough to ignore its influence on the electric field distribution and accurately describe the electric field of each point
the field strength is a vector whose direction is the positive direction of the force on the test charge, and its magnitude is equal to the force on the unit test charge. The unit of field strength is v / m, 1 V / M = 1 N / Ku. The spatial distribution of electric field intensity can be visualized by electric field lines
The electric field strength follows the principle of superposition of electric field strength, that is, the total electric field strength in space is equal to the vector sum of electric field strength when each electric field exists alone, that is, the principle of superposition of electric field strength is an experimental law, which shows that each electric field is acting independently and is not affected by the existence of other electric fields. The above description is applicable to both electrostatic field and rotating electric field or general electric field composed of both. The superposition of electric field strength follows the parallelogram rule of vector compositionthe strength of electric field is related to the bearing capacity of insulating materials, the current density in conctive materials, the voltage on the terminal button, and whether there is corona or flashover, which is one of the important physical quantities to be considered in the design
reference: network electric field strength
physical attack
, according to the character's own attributes, and the physical damage of the weapon itself, plays a decisive role in the physical damage or strength or attack strength, and other attributes
personal physical attack formula:
weapon physical attack x (strength x0.004 + 1) x (1 + Weapon Specialization bonus) = personal physical attack
for example, if the roaming weapon has a physical attack power of 1000 forces and 400 points, then it should have a physical attack power of 400 points ×( one thousand × 0.004+1) ×( 1 + 0) + 0 = 2000 (no attack power increases mastery and ignore attack power, so the latter two items are zero)
if you enchant 1 point physical attack card, the attack power increase value = (400 + 1) ×( one thousand × 0.004+1) ×( 1 + 0) + 0-2000 (original attack power) = 5
If enchant 1 point of power, then the attack power increase value = 400 ×[( 1000+1) × 0.004+1] ×( 1 + 0) + 0-2000 (original attack power) = 1.6
of course, in the process of calculation, you will find that there are many places where the number can't be integer, but the system will round according to the integer (only valid in the final result), so the attack power may not be completely accurate, there will be a little error. In addition, some people say that when rounding, the system does not round up, but directly does not calculate all the following decimals. That is to say, 1.1 = 1, 1.9 = 1, that's all. But I tried to calculate it several times, and found that this statement is negative. The system will not dect the number after the decimal point, nor round it, but directly round it up and not show it. Of course, it will also be included in the calculation
I'll take my roaming to confirm that the weapon's attack power is 496. See for yourself, the attack power of enhanced 12 is 391. Then the additional attack power of enchant and left slot is 130. LZ. You can calculate it yourself. 4136's attack power is not correct.
magnetic field; The magnetic field intensity B = f / (IL) f is the electric field force. I is the current. L is the length
Lorentz force; Fro = QVB, q is the amount of charge. V is velocity. B is the intensity of the magnetic field
the physical attack power plus panel is related to your strength
the formula is
panel attack power increase = material attack increase * strength * 0.004 + material attack increase
generally it can increase by 400 ~ 500 panels
hope to adopt it
The electric field strength at a certain point in the electric field is numerically equal to the electric field force on the unit charge at that point. The electric quantity and volume of the test charge should be small enough to ignore its influence on the electric field distribution and accurately describe the electric field of each point
the field strength is a vector, and its direction is the direction of the force on the test charge, which is equal to the force on the unit test charge. The unit of field strength is v / m, 1 V / M = 1 N / Ku. The spatial distribution of electric field intensity can be visualized by electric field lines
the electric field strength follows the principle of superposition of electric field strength, that is, the total electric field strength in space is equal to the vector sum of electric field strength when each electric field exists alone, that is, the principle of superposition of electric field strength is an experimental law, which shows that each electric field is acting independently and is not affected by the existence of other electric fields. The above description is applicable to both electrostatic field and rotating electric field or general electric field composed of both. The superposition of electric field strength follows the parallelogram rule of vector composition
the strength of electric field is one of the important physical quantities to be considered in the design, which is related to the bearing capacity of insulating materials, the current density in conctive materials, the voltage on the terminal button, and whether there is corona or flashover
the electric field intensity near the earth surface is about 100V / m. ① Definition: the electric field strength of a point is the ratio of electrostatic force F to its charge quantity
② definition formula: e = f / Q, f is the force of the electric field on the trial charge, and Q is the charge amount of the test charge (Trial charge) placed at a certain point in the electric field
③ direction of electric field strength: it is defined as the direction of electrostatic force received by the positive charge placed at the point. The direction of force is the same as that of positive charge, but opposite to that of negative charge< (4) physical meaning: the physical quantity describing the strength of the electric field and the nature of the force of the electric field. The strength of the electric field depends on the electric field itself, or on the charge that excites the electric field, and has nothing to do with the force charge in the electric field
⑤ applicable conditions: applicable to all electric fields< The electric field intensity is a vector< (7) the determinant of electric field: e = KQ / R2 (only applicable to point charges). Where e is the electric field strength, K is the electrostatic constant, q is the electric quantity of the source charge, and R is the distance between the source charge and the probe charge< Electric field force: F = e × The formula of electric field strength of point charge in Q vacuum: e = KQ / R2 (k is electrostatic constant, k = 9.0) × 10 ^ 9N. M ^ 2 / C ^ 2)
formula of uniform electric field strength: e = u / D (D is the distance between two points along the direction of electric field strength)
definition formula applicable to any electric field: e = f / Q
electric field strength between parallel plate capacitors: e = u / D = 4 π KQ / es
the field strength of the point charge in the medium: e = KQ / (R2)
the electric field of the uniformly charged spherical shell: e = 0, e = K × Q / r2
electric field intensity of infinite straight line: e = 2K ρ/ r ρ Is the linear density of charge, R is the distance from the line)
the electric field intensity of the charged semicircle to the center of the circle: e = 2K ρ/ R ρ Is the linear density of charge, R is the radius of semicircle)
the electric field intensity on the central axis which is perpendicular to the plane of the ring with radius R and passes through the axis: kqh / (H2 + R2) 3 / 2
the electric field intensity formula for any charged curve: e = ∫ K ρ/ R2 DS... (R is the distance from the curve, a function of coordinates x, y, ρ Similarly, the charged surface is its surface integral