nt_n guard ring noise analysis
DESCRIPTION
The purpose of this report is to provide a detailed example and analysis of a N_TN guard ring structure. This scheme could be used to separate the analogue and digital domains on chip, and thus used for noise attenuation and noise collection. Furthermore this report will hypothesis additional noise performance improvements that could be made for added noise isolation.TRANSCRIPT
1 | Adrian O’Shaughnessy
NT_N MOAT NOISE ANALYSIS
A detailed analysis of a NT_N guard ring structure
Adrian O’Shaughnessy
Expert Layout IC
April 2014
2 A detailed analysis of a NT_N guard ring structure | Adrian O’Shaughnessy
SUMMARY
The purpose of this report is to provide a detailed example and
analysis of a N_TN guard ring structure. This scheme could be used
to separate the analog and digital domains on chip, and thus used for
noise attenuation and noise collection.
Furthermore this report will hypothesis additional noise performance
improvements that could be made for added noise isolation.
3 A detailed analysis of a NT_N guard ring structure | Adrian O’Shaughnessy
1.0 INTRODUCTION
The noise isolation scheme I propose follows the format:
NWELL GR – PTAP GR – N_TN – PTAP GR – NWELL GR
This report will break this guard ring strategy down into cross
sectional views and will highlight the various parasitic components
created. Each component will be analyzed in detail.
The goal of this report is to further educate Layout Engineers on
noise isolation construction and to highlight the critical importance of
understanding the concepts of cross sectional views.
2.0 GUARD RING LAYERS
2.1 NT_N (Native) Layer
This layer is used for mask making rather than process requirements.
It is defined as a non-PWell and a non-Nwell region. In other words,
the area covered by NT_N will NOT get doped either P or N.
This is important to understand because typical CMOS design takes
place on heavily doped P-Substrate (Psub). Heavily doped Psub has
low resistivity. The reason being, Psub that is low in resistance will
provide good latch up protection. The flip side to this is that it’s bad
for noise isolation.
However if we cover an area of Psub with NT_N, this area won’t get
doped and will therefore resemble intrinsic silicon.
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Intrinsic silicon by its very nature is highly resistive. It should also be
noted the N_TN drawn layer adds no process cost and does not
consist of an extra mask.
2.2 Nwell Guard Ring
Nwell and Ptap guard rings are sometimes misunderstood and are
therefore not implemented correctly. The purpose of the Nwell guard
ring is to provide noise attenuation. With this is mind, it’s vital the
guard rings attributes are maximized. This will be discussed in detail
later.
2.2 Ptap Guard Ring
As previously mentioned, Ptap guard rings are also often
misunderstood and are therefore executed poorly. The purpose of
this guard ring is to collect noise. For this reason they are commonly
known as sacrificial collectors. It’s crucial certain factors of this guard
ring are followed in order for it to fulfill its purpose efficiently. This will
also be discussed later in detail.
5 A detailed analysis of a NT_N guard ring structure | Adrian O’Shaughnessy
3.0 MOAT CONSTRUCTION
Ok let’s take a look at the Moat guard ring:
NW
P C3
R3
NT_N Area
P NW
C1 C2
PSUB PSUB R1 R2
R4 R5
Figure 1: Isolation Scheme
Figure 2: Cross sectional view
ANALOG
NWELL GR
PTAP GR
DIGITAL
NWELL GR
PTAP GR
NT_N
X
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3.1 Noise Guard Ring Parasitic Components
In order to fully understand how the above guard ring performs as a
noise isolator, we must first consider and investigate the capacitive
and resistive elements associated with its construction.
3.1.1 Capacitive Elements C1 & C2
Capacitors C1 & C2 are created by the sidewall P-N junctions.
Remember a capacitor consists of two conducting plates, at different
potentials, separated by an insulating material called the dielectric.
In this case C1 is tied to VDDA/ GNDA and C2 is tied to
VDDD/GNDD. The dielectric in both cases is Psub. The value of
these caps is also important and therefore the spacing ‘X’ in figure1,
comes into play. Let’s recap on how to determine the capacitance of
a capacitor:
Where:
= Capacitance of capacitor
= dielectric constant of the material between the plates
= electric constant
= Area overlap of the plates
= Thickness of the dielectric
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It’s crucial to note at low frequencies, capacitors act like an open,
while at high frequencies they act as a short.
Ever wondered why this is? It’s to do with the reactance of the
capacitor. This is critically important to understand. A capacitors
reactance is determined by:
Where:
= Reactance of capacitor
= Frequency
= Capacitance of capacitor
It can be seen from the equation that capacitor reactance is inversely
proportional to frequency. In other words, as the frequency goes up,
the reactance of the capacitor goes down and eventually resembles a
short. It can also be deduced from the above equation that the
capacitance value is important. The higher the capacitor value, the
lower the capacitor reactance.
If we now apply our new found knowledge of reactance to the noise
isolation scheme, we can say at high frequencies, capacitors C1&C2
will act as shorts. But is this good or bad? This will be discussed in
detail later on.
What about the capacitor C3? We have two conductors (Ptaps) at
different potentials (star connections), separated by a dielectric which
in this case is almost intrinsic silicon. If C1&C2 act like shorts at high
frequency, then C3 could potentially short all noise across the
domains! Thankfully because the plates are so far removed etc.
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the capacitor C3 is negligible. Therefore the width of NT_N is
important. The width of NT_N also determines the resistive barrier
between the domains.
3.1.2 Resistive Elements R1,R2, R3,R4 & R5
We’ve already said the width of NT_N determines the size of R3. But
we also need to consider the Nwell resistances R1&R2.
Whenever I see a Nwell guard ring used around a block, I always
wonder about its purpose. Why is it there? Some colorful answers
have been given. So what is the purpose of an Nwell GR? Well its
purpose is to provide noise attenuation. Because Psup’s resistance is
not uniform, i.e. it gets more resistive the deeper it goes, noise
usually travels close to the top. As the noise hits the Nwell barrier, it’s
forced deeper into substrate. Depending on the width of the guard
ring, it will get further attenuated. Therefore Nwell width is crucially
important. It should also be noted the Nwells resistive integrity is
important.
We can now understand the role of the Nwell guard rings in this
particular isolation scheme -> noise attenuation.
Now let’s look at the resistors R4&R5. These represent the resistance
of the Ptap guard rings. Again we need to fully understand the role of
the Ptaps in the full isolation scheme.
Unlike Nwell GR structures, Ptap GR’s are used as noise collectors.
Their job is to collect up any stray noise and provide a path for it off
chip.
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We should now understand that it’s key to have this path as low in
impedance as possible. Usually Ptap GR’s are star connected back
to local GND pads.
To summarize:
Nwell GR’s -> Noise attenuation
Ptap GR’s -> Noise collectors
3.2 Moat Guard Ring theory
In section 3.1.1, I asked the question regarding C1&C2 acting as
shorts at higher frequencies and was it good or a bad thing? Well
now we can look at this question in the overall context of the isolation
design:
The Nwell guard rings are used to provide noise attenuation.
However the worst case scenario is some noise will still get
through.
The Ptap guard rings placed beside the Nwell guard ring can
now do their job and collect any stray noise.
Capacitors C1&C2 provide an added benefit because they act
as shorts at high frequencies. Therefore noise from the Nwell
guard ring gets directed injected into the Ptap rings. This is an
excellent added bonus in our noise isolation strategy.
Again the worst case scenario would be the Ptap GR’s don’t get
all the noise. Now the un-doped substrate comes into play.
As we’ve said, intrinsic silicon is highly resistive and therefore
provides excellent noise attenuation. Any stray noise at this
point will be further dissipated .
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It can now be seen from Figure 1, excellent noise attenuation and
filtering can be obtained.
4.0 NOISE ISOLATION IMPROVMENTS
However could we further improve this already robust scheme? I
believe so by adding in further Ptap guard ring and N_TN
placements:
NW
P C3
R3
NT_N Area
P NW
C1
PSUB C2
P NT N
P NTN
ANALOG
NWELL GR
PTAP GR
DIGITAL
NWELL GR
PTAP GR
NT_N
PTAP
GR
NT
N
PTAP
GR
NT
N
Figure 3: Extra Ptap GRs and NT_N areas
11 A detailed analysis of a NT_N guard ring structure | Adrian O’Shaughnessy
Ok let’s discuss the possibility of improving the current isolation
scheme by adding extra Ptaps guard rings to the other sides of their
respective Nwell guard rings.
As we’ve stated, Ptap rings are used as noise collectors (also known
as sacrificial collectors). I believe by adding one to each side of the
Nwell ring, greater noise isolation can be achieved. However some
important points should be considered.
Unlike the original Ptap ring, we do NOT want a short to the Nwell
tap. We want the new Ptap ring to collect noise but we also want as
much attenuation as possible before noise hits the Nwell ring. We
therefore need to ensure the sidewall junction capacitance (C2 in
figure 3), is as small as possible. Remember - small capacitance will
equate to larger capacitor reactance. We need the capacitor
reactance to remain high for as long as possible.
Let’s recap on the equations:
Capacitor reactance
Capacitor capacitance
So how can we ensure the capacitor C2 is as small as possible?
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Here’s some suggestions:
Distance between the new Ptap ring and Nwell ring should be
as wide as possible. This will ensure a greater dielectric
thickness.
Changing the dielectric constant:
= dielectric constant of the material between the plates
By introducing a new NT_N region between the new Ptap and
Nwell rings, we’ve changed the dielectric constant and
effectively decreased the value of the cap.
The new NT_N region will also have the added benefit of
providing a highly resistive substrate between the new Ptap and
Nwell ring to ensure further noise attenuation.
Unfortunately there’s a price to pay for these added benefits; Space
burn! It’s important to note that NT_N comes with some DRC
baggage. Spacing requirements to such layers as OD and Nwell are
needed. However with some added floor planning considerations, I
believe this modification could be achieved.
4.1 Triple Well Isolation
Using a buried Nwell layer (Deep Nwell) is an excellent technique for
noise isolation. Typically though this approach needs to be adopted
at the beginning of a layout design as it’s not easily migrated too later
on in the design cycle.
13 A detailed analysis of a NT_N guard ring structure | Adrian O’Shaughnessy
Triple well isolation is a paper on its own, but here’s a quick
summary:
Used to isolate noisy NMOS devices.
The MOS sits within a standard PW doped silicon region,
labeled RW, and isolated from the rest of the P-type substrate.
The isolation is the NW ring in contact with the DNW base
which forms a barrier of N-type doped material.
It is imperative the RW substrate is star-connected back to the
GND pad and NOT connected to the local GND substrate.
Doing this will effectively short out the DNW region and all
noise isolation will be lost.
It’s also important to note DNW is an extra mask and therefore
would incur extra cost.
5.0 CONCLUSIONS AND RECOMMENDATIONS
Having investigated the Moat guard ring strategy in detail, we can
conclude from a theory perspective, that the isolation scheme
currently being used seems sound and robust. We can also conclude
the placement of the Pwell taps in respect to the Nwell guard rings is
crucial to the success of the scheme. NT_N and Nwell widths are
also critical, as is the impedance of the Pwell guard ring. These must
work hand-in-hand with each other to ensure optimal noise
attenuation and collection.
I’ve recommended additional Pwell straps and additional NT_N to
further improve noise isolation. However this may prove space
prohibitive. I’ve also recommended using a triple well scheme and
highlighted its potential advantages.
Adrian O'Shaughnessy