Show Posts

This section allows you to view all posts made by this member. Note that you can only see posts made in areas you currently have access to.


Topics - Aphid

Pages: [1]
1
Touhou Puppet Dance Performance / Suspect List Topic
« on: January 05, 2015, 11:59:06 AM »
This is a list of puppets that seem really powerful, to the point where every team needs to dedicate their strategy to beating them, or which might have a very undesirable effect on the game by existing (Moody comes to mind). When/if stuff is being investigated, perhaps interesting to look here first. As moveset information is not fully available yet this should be taken as a tentative list, additional puppets are to be added and removed as more information becomes available and playtest data is gathered. In most cases, it seems that the 'ability' of the puppet is the thing that is most worrisome, there are a few really good ones.

Nimble

Nimble as an ability doubles a statistic. Doubling a statistic is the same as adding a whole lot of BST to your puppet, effectively 50 plus the value of the stat being doubled.

Power Sakuya

Nimble gives her effective 635 BST, but she can't carry items. She outspeeds almost anything, the exceptions being weather puppets, Yamame, and her own Speed variant, and has an excellent 135 base ATK (only 8 puppets have higher attack). Also has a good movepool, with several coverage options, and of course access to stat-enhancement to top it all off.

Power Yamame

Moody

Moody raises stats by +1 each turn. Since the stat being raised is random, it could be evasion. If it is evasion, Moody can cause a lot of trouble, becoming a truly unrivalled stalling ability. It is present on 5 puppets. Especially Suwako, Kokoro, and Komachi seem dangerous users.

Speed Suwako
Power Komachi
Defense Kokoro
Defense Kotohime
Assist Kosuzu

Up Tempo

The TPDP equivalent of Speed Boost, this ability instantly landed Blaziken into Ubers when added to it. Speed Boost was previously only attainable by the very fragile and otherwise quite useless Ninjask, which ended up being a popular lead anyway because of it. Anything with access to speed boost and especially also Backup Plan is automatically suspect. This ability is present on 6 puppets. Notice how 4 of these are power forms which have high damage output. These are dangerous in particular when they have access to attack boosts and/or backup plan:

Speed Miko
Power Rin
Power Kana
Power Cirno
Power Mystia
Assist Merlin

Boundary Blurrer / Power Mary

Present only on Power Mary, Boundary Blurrer doubles 4 statistics in all weather conditions, giving her a 675 effective BST in weather. If weather happens to be somewhat prevalent, Mary might be 'too good', her power is comparable to that of legends in Pokemon. Her Illusion typing gives her only 2 weaknesses, one of which is her own type.

Assist Satori

She is basically Wobbuffet. She can pretty much wall and lock a very high percentage of the puppets, generally getting a 2-1 trade.

Vanishing Act

If Evasion Clause is standardized, Vanishing Act might be criticized as well. Note that it is only present on four puppets, none of which are actually defensive by nature.

Power Remilia
Speed Remilia
Power Wriggle
Assist Wriggle

Divine Protection

Divine Protection is another interesting ability with a lot of potential. Many stat-boosting moves exist that also lower another stat because they would be unfair otherwise. This ability also synergises with Moody.There is only one user.

Speed Sanae


High Stats

While stats are less variable than they are in pokemon, the puppets do vary in stat total from about 450 (barring a few exceptions with abilities to counteract it) to 600.

Shinki

Both Power and Speed Shinki have a BST of 600, which is the third highest in the game. (Two puppets have a BST of 630, but they have a crippling ability that will probably prevent them from ever seeing much play in either case.). Furthermore, All-Weather and Dark Clothing are both interesting abilities.

Fast and powerful

Puppets have a rather unique combination of very high speed and very high attack. Most other puppets with 120+ attack are slow. Depending on the movesets available, they might cause overcentralization. A comparable pokemon would be Garchomp.

Speed Tojiko
Speed Gengetsu
Speed Yorihime

Edits:

1) Updated Satori's Information to reflect struggle war fix.
2) Removed Divine Protection from suspect list -- If it only functions for the user, it is far less unfair. Can someone else confirm these findings too?


2
Touhou Puppet Dance Performance / Speed Tiers
« on: January 05, 2015, 10:24:05 AM »
I made a little spreadsheet with the speed tiers for all (Max EV, Nature) Touhoumons.

https://docs.google.com/spreadsheets/d/1BkFHzMDoYZ6U9bF7n-_XQnfOQWz0s87BOwFnQFwdPY0/edit?usp=sharing

As far as I know, the formula seems to be 5 + 2 * Base + EV + IV, where IV ranges from 0-15. This means your stats should be one point higher at lv. 100 than the equivalent Pokemon stats. This comes into play with rounding at times for looking to outspeed things.

The way to read the spreadsheet is to look at the column. For example, let's take a Speed Shinki which uses Intimidation (Known in regular Pokemon as Dragon dance or DD). It's got 95 speed, filling that into the ' my speed' box gives us a base of 225 to start with. If we want to outspeed everything except weathers, sakuya, and aya at +1 speed we need 271 speed. So a speed EV of 46 is good enough if we want a SAtk nature, for a spread of 46 speed, 64 SAtk, and 20 HP to outspeed most stuff after a single use of Intimidation.

Note: There might be some commonly competitively used puppets that will reasonably always run less than full EVs and no speed nature. In that case it might be relevant to include the specific case as another tier, but it is simply to early to tell what/when will happen, so only the 'max' speeds are included here.




3
General Metagame / Calculating Defensive EV spreads
« on: December 08, 2014, 02:58:27 PM »
I see fairly often that guides feature suboptimal defensive EV spreads.

The purpose of defensive EVs is often one of the following three goals, in order of how common they are:

1) Maximize defenses against a chosen type of attack.
2) Maximize defenses against a mixed 'barrage' of attack.
3) Maximize defense against an opponent that picks the most effective type.

In order to understand defensive EVs, let's first consider the attack damage formula. Effectively, this formula says the damage percentage from an attack is 100 * A * P * C * R/ (D * H), where A is the attacking puppet's attack stat, while D is your defense stat. P is the move's power, C is a certain constant, and R varies between 0.85 and 1 randomly. (Both puppets are assumed to be level 100). Since only 'D' and 'H' here is within our control we can observe a simple fact:

EHP = D * H * C

Where EHP is your `effective` health. The higher this number, the more attacks a puppet can withstand. Now EV's raise the 'H' and 'D' statistics by exactly one point per 4 EVs.

Goal <1>

When D > H, it is obvious raising 'H' by one point will provide you with more EHP than raising 'D' by one point, so it is best to spend your EVs in the lower of the two values. There is some 'optimal' amount of EVs to invest in either attack or hp before reaching the cutoff point. Let h be your HP stat, and d be your defense stat. The cutoff point is at d = h + 52.5.

Suppose d < h + 52.5. Then we need more defense. So first invest (h  - d) * 8 + 420 EV's into defense, then split equally.
If h < d - 52.5, then we need more HP. First invest (d - h) * 8 - 420 EV's into HP, then split equally.

Let's do an example: We have a puppet with the following stats:

HP: 80
DEF: 140

And we want to maximize physical defense, having 240 EV's available for this in our build. In order to do so, notice how h < d - 52.5. (d - h) * 8 - 420 = 60, so first invest 60 EV's into HP, then split equally. Then you get the following EV spread:

HP: 150
DEF: 90

Because EV's are rounded in multiples of 4, we can optimize for rounding by using this instead:

HP: 152
DEF: 92

Now, suppose we have a +def nature. By using that spread, the actual value ends in a '9' before nature (339 HP, 339 def). So we can win an extra +1 defense point by investing 4 extra EV's into this, which is very much worth the investment. So the final EVs become:

HP: 148
DEF: 96

Remark:

For the more 'complicated' goals mathematically it can be very useful to convert base stats into actual real stats, as we can work with real stat points instead of having to work with base stats, which makes the formulas much more complicated, introducing a lot of extra terms. Convert a base stat into a real stat like this:

HP: H = h * 2 + 141
Others: X = x * 2 + 35

Goal <2>

In order to satisfy goal <2> we want to maximize the following, letting HP = H, Defense = D, Special Defense = S:

H / (1 / D + 1 / S)

Under this condition, we can express H = h0 + Eh, D = d0 + Ed, S = s0 + Es, where h0 = 8 * h + 564, and d0 = 8 * d + 144, similar for s0. The formula becomes:

(h0 + Eh)(d0 + Ed)(s0 + Es) / (d0 + Ed + s0 + Es).

This formula can be solved using the method of Lagrange Multipliers, but this is quite more complicated than strictly necessary. First, observe that if d = s or D=S, we have a simple case. At this point, we want to invest in HP as long as 2 * H < D = S, in other words, the turning point is now at:

d = h / 2 + 17.5

So, when:

d < h / 2 + 17.5
D < H / 2

Invest into defenses until this formula is no longer satisfied, then invest 2 EV's into HP for every 1 EV into defenses.

And, when:

d > h / 2 + 17.5
D > H / 2

Invest into health until this formula is no longer satisfied, then invest 2 EV's into HP for every 1 EV into defenses.

Now we turn to the more complicated case. What if D < S (the opposite case is a mirror, so we may assume that 'defense' is the lower of the two defenses).

Solving for H we get:

H = D*D / S + D

And for D:
D = 0.5 * (-S + sqrt(S^2 + 4 * H * S))

If H > D*D / S + D invest EV's into Defense
If H < D*D / S + D invest EV's into Health.

Note that S here is the special defense 'before' any nature benefits.
At this point, natures do matter. Because the sequence of application of EVs does 'not' matter we want the 'most' EHP (if we pick a defense nature) out of it as possible. We can do so by checking whether the 'low' or the 'high' defense stat is a better pick. This involves solving the formula (1 / (1/(ax) + 1/b)) / (1 / (1/a + 1/(bx))) > 1, for which the conclusion is that the 'high' stat is the better pick (not really a weird conclusion there). However, as for the valuation of the low stat and the distribution of EVs, it stays of course the case that nature should be ignored due to the way it works (as a multiplier)  for optimal results, which results in an eventual stat spread of (given enough EVs to work out the kinks in the natural spread) 2:1.1:1, where the 1.1 is in the higher starting def. However, in most cases the natural deviations from the ideal spread are big enough that we can only approach it, and the way most effective to do so as a procedure is best illustrated with examples.

Let's do an example now for case <2>. Suppose we have a 'mon with the following stats:

300 EVs to invest in defenses.
HP: 150
DEF: 100
SDEF: 150

This yields the following 'base real stats':

H: 441
D: 235
S: 335

So we calculate our target HP for the given Defense and Special defense:

H = D^2 / S + D = 235^2/335 + 235 = 400

So we are basically overspent on HP and investing in 'def' is the more efficient choice. So apply the reverse formula:

D =  0.5 * (-S + sqrt(S^2 + 4 * H * S)) = 252

This means the first 68 EV's should be spent in 'Defense'. After this, we have the following stat spread:

H: 441
D: 252
S: 335

Now in order to maximize gains we have to divide EV's between defense and HP in a peculiar way, namely to follow the curve H = D^2 / S + D. At this point we have to solve for both H and D given the constraints. Our constraints are:

S = 335
D = 252 + 1/4x
H = 441 + 1/4v - 1/4x
Subject to:
H = D^2 / S + D

Where v is the total remainder EV we want to invest, and x is the amount of defense ev's. The amount of HP ev's then obviously is x - v. Note that S > D + 63, so we're never going to reach the point where investing in special defense is worthwhile. The solution for the eq. is:

x = 2 sqrt(335) sqrt(v + 4112) - 2348) = 64.666

Rounding down to a multiple of 4 we get 64 extra defense EV's, and 232 - 64 = 168 HP EV's. 64 + 68 = 132, so our final spread is:

HP: 168
DEF: 132
SDEF: 0
Nature: +SDEF

This spread will give you the most effective health against a 50/50 mix of damage given the provided stats.

Remark:

If defense and special defense are 'close together' you will need to see if you have enough EV's that defense = special defense when following the quadratic formula obtained as a solution to the problem. At this point HP will be 2* defense as well (due to the way the formula was derived). If this is true, then we can simply forego any further calculations, and start from that point using the 'simple' solution (for def = sdef).

Remark #2:

It is possible to solve the system directly. In this case, we have:

Maximize:
H*D*S / (D*S)
Under the constraints:
D = D0 + 1/4d
S = S0 + 1/4s
H = H0 + 1/4h
d+s+h = v
d >= 0
s >= 0
h >= 0
0 <= v <= 512

But since we've covered all possible sensible cases, the only reason to bother with lagrange techniques here is as a math curiosity.

Edit: Changed notation. Now using capitals for all final stats and small letters for ev's and base stats.

Case <3>

An observant reader will notice a similarity between this and case <1>. Simply pretend the higher defense stat does not exist and treat it as case <1>. Are the defense stats close enough that investing your allotted EV's will balance them out? Then split the remainder as per the simple case <2>. There is one exception which we will come to later.

Let's do a simple example for this special scenario:

HP: 130
DEF: 80
SDEF: 70
EV to spend: 500

This yields the following stats:
HP: 401
DEF: 195
SDEF: 175

First, we equalize the defenses. so spend 80 to SDEF. Then we need an additional 6 points in both defenses, and 1 in HP to get the 2:1:1 distribution, spending an additional 24 in both defenses, and 4 in HP. This yields:

4 HP
24 DEF
104 SDEF
Total spent: 132.

There are now 368 points left. 368 / 4 = 92, so spend another:
184 in HP
92 in DEF
92 in SDEF

For a total of:
188 HP
116 DEF
196 SDEF

Which means stats of:
448 HP
224 DEF
224 SDEF

Now comes the exception, which is 'natures'. This is rather a bit annoying as you see, we can't simply ignore nature here. If we use a boosting nature, then it makes the most sense to boost the lowest defense if they are far apart (for it is impossible to equate the defenses using EVs). However, once it becomes possible to equate the defenses with EV's there's a certain 'tipping point' where you will want the higher def to be chosen for the nature, and then a second tipping point where it won't matter which one you choose. When there's a boosting nature, equalize the defenses after applying the nature.

In order to get 11 defense and 11 special defense, we need to spend 21 points. In other words, we get a 22/21 deal here (22 points for 21). So the ideal distribution 'WITH' a nature for balanced defenses is 21:11:11 if we're behind the second 'tipping point'. Before the first 'tipping point' the ideal distribution is 2:1.1 (the higher def stat doesn't matter).

Finding the first 'tipping point' is quite simple: As soon as the lower defense stat exceeds the higher with both nature and EV's we are in trouble. The same with the second 'tipping point': if we can't equate the lower nature to the higher with a nature applied using EV's, we are in trouble.

Tipping point 1:
1.1 * D + Ed > S

Tipping point 2:
D + Ed' < S * 1.1

Where Ed is obtained using part '1' technique and Ed' is obtained using part '2' technique

In between (when both equations are true), the answer is quite complex.

 


 



 

Pages: [1]