Yield D0 Die Calculator

1. Yield to Poisson D0 and BE DD
Yield =	%	input yield number
Chip Area =	cm²	input chip area
Poisson D0 =	1/cm²
Complexity Factor =		default complexity factor for each process node can be found at ARIMA model section below
Product Pre-factor =		default = 1
k-Factor		default = 1
BE DD =	1/inch²
Calculate
2. Poisson D0 → BE DD
Poisson D0 =	1/cm²	input Poisson D0 for conversion
Chip Area =	cm²	input chip area
Yield =	%
Complexity Factor =		default complexity factor for each process node can be found at ARIMA model section below
Product Pre-factor =		default = 1
k-Factor		default = 1
BE DD =	1/inch²
Calculate
3. BE DD → Poisson D0
BE DD =	1/inch²	input BE DD for conversion
Complexity Factor =		default complexity factor for each process node can be found at ARIMA model section below
Product Pre-factor =		default = 1
k-Factor		default = 1
Chip Area =	cm²	input chip area
Yield =	%
Poisson D0 =	1/cm²
Calculate

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ARIMA Model (see more)
Technology Node
(Poisson) Df		1/cm²	Saturated Poisson D0. Typcially < 0.1/cm ²
ARIMA LR		%	Monthly reduction of Poisson D0. Industry average is 91-93% (7-9% reduction per month), and PDF can help customer double the learning (14 - 18% reduction per month, or LR = 82 - 86%). (see more)
Starting Poisson D0		1/cm²
Chip Area =		cm²
Complexity Factor =			we help you pick the default value based on the technology node of your choice
Product Pre-factor =			defaul = 1 (k-factor is set as 1)
Calculate
ARIMA curve
Month Index	Month		Poisson D0 (1/cm²)	BE DD (1/inch²)

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Good Die Per Wafer Estimation
die height		mm	input die height
die width		mm	input die width
die size		mm²
scribe width		mm	input scribe width
die + scribe height		mm
die + scribe width		mm
die + scribe area		mm²
edge exclusion		mm	input edge exclusion here
wafer size		mm	select wafer size
Complexity Factor =
Product Pre-factor =			we use default k-factor = 1
Gross Die per Wafer
	Yield Scenario 1 known yield number		Yield Scenario 2 known BE DD number
Best-In-Class (BIC) situation
BIC Yield		(←input here) %		%
Good Die per Wafer
Poisson D0 / BE DD		(D0) 1/cm²		(←input here, BE DD) 1/inch²
Your Fab situation
Fab Yield		(←input here) %		%
GDPW'
Poisson D0 / BE DD		(D0) 1/cm²		(←input here, BE DD) 1/inch²
Best-In-Class vs Your Fab
delta(GDPW)		less die per wafer vs BIC		less die per wafer vs BIC
delta(GDPW %)		%		%
Wafer ASP		input $/wafer		input $/wafer
die price		$		$
Fab KWPM		input KWPM		input KWPM
Your Fab opportunity if reach BIC		M USD per month		M USD per month
Calculate

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