RC Modeling and Logical Effort Basics

RC Modeling and Logical Effort Basics

Logical Effort Components
Template Template Width Scaled by a Input Capacitance increases by a · Ctemplate Resistance decreases by Rtemplate / a Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort Input Capacitance
Cox  eox / tox (unit: F/m2) Leff = L – 2xd Cgate = CoxWLeff = CoxWL(1 – 2xd / L) k1 = Cox(1 – 2xd / L) Input Capacitance Cin is the sum of the gate capacitances Cin(inv) = k1WnLn + k1WpLp Scaling all transistor widths by a, scales Cinv by a C = k1aWnLn + k1aWpLp = a Cin Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort Resistance
R = (r / t) (L / W) ohms Rchannel = Rsheet (L / W) ohms Rsheet = 1 / ( mCox ( Vgs – Vt )) ohms m = surface mobility Rchannel = L / (mCoxW ( Vgs – Vt )) ohms Scaling the transistor width by a factor a, results in: R = L / (mCoxaW ( Vgs – Vt ) ) = Rchannel / a Resistance is inversely proportional to a Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort Parasitics
Cja junction capacitance per m2 Cjp periphery capacitance per m W width of diffusion region m Ldiff length of diffusion region m Scaling the transistor width by a factor a, results in: Parasitic capacitance scales proportional to a Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

thl delay derivation for step input
Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay derivation (cont.)
Saturation: Linear: Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Substituting R Rchannel = L / (mCox ( Vgs – Vt ) W) ohms Yeilds an RC Delay model k Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

tlh delay derivation for step input
Concerns: Vtn and Vtp mn and mp Must distinguish Rchannel(tlh) and Rchannel(thl) Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Handling Pull-up and Pull-down
For tlh we refer to Rchannel as Rup Rup = Lp / (mpCoxWp( Vgs – Vtp )) ohms For thl we refer to Rchannel as Rdown Rdown = Ln / (mnCoxWn( Vgs – Vtn )) ohms For now lets assume that Vdd-Vtp = Vtn Rup = Lp / (mpCoxWp( Vgs – Vt )) ohms Rdown = Ln / (mnCoxWn( Vgs – Vt )) ohms For the same length and width, difference is due to mobility. Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Equalizing Pull-up and Pull-down
How to equalize Rup and Rdown Example: Assume 2mn = mp and Lp = Ln Rup = Lp / (0.5mnCoxWp( Vgs – Vt )) ohms Rdown = Ln / (mnCoxWn( Vgs – Vt )) ohms To equalize resistance, Wp = 2Wn When Rup = Rdown, tlh = thl for the same output load Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

RC Model for a CMOS logic gate
Graphical Representation of RC model: Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

RC Model for a CMOS logic gate
Can use this model for any static CMOS gate: Find the equivalent resistance for the pull-up and pull down paths of the logic gate Assume parasitic only occur at output node Example: 2-input NAND gate (* 2mn = mp) Rup = Rp(a) or = Rp(b) Only 1 transistor on pull-up path… Rdown = Rn(a) + Rn(b) Want Rup = Rdown 2 transistors in the pulldown. Can treat as resistors in series. For inverter occurs when Wp = 2Wn Here occurs when Wp = Wn Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay of each gate is the same, right?
We can equalize the delay associated with RCout However RCp depends on the gate Is the only difference between gates RCp? Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay of each gate is the same, right?
We can equalize the delay associated with RCout However RCp depends on the gate Is the only difference between gates RCp? We forgot about Cin We equalized the resistance of each gate, but the capacitance Isn’t the same…. Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Moving to Logical Effort (accounting for Cin)
* t refers to the template Gate Template a Scaled Gate Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort Gate Delay Model
Simplify Analysis by Normalizing to Inverter Template Logical Effort Parasitics Electrical Effort Doesn’t change with a Doesn’t change with a Same derivation can be performed for tlh Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Technology independence
Relative delay of gates is ~ technology independent. Allows for comparisons to be fairly accurate across technologies Anyone heard of fanout of four (FO4)? 4C C or C C C C C Before transistor sizing The delay of an inverter Loaded with 4 inverters With transistor sizing The delay of an inverter loaded with 4 identical inverters Can cause some confusion… FO4 is not exactly logical fanout…. Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Examples: Estimating g and p of Gates
Inverter NAND2 NOR2 2 2 4 2 4 2 1 2 1 1 g = (2+1)/(2+1) = 1 p = Cp-inv/Cinv = pinv g = (2+2)/(2+1) = 4/3 p = [(2+2+2)/(2+1)]pinv = 2pinv g = (4+1)/(2+1) = 5/3 p = [(4+1+1)/(2+1)]pinv = 2pinv Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Obtaining LE Values from Simulation
In real world we don’t have a step input… What do the delay characteristics of a gate look like when simulating? Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Vojin G. Oklobdzija: High-Performance System Design
130nm Delay of Gates vs. h NOR2 NAND2 Inverter Slope = t = 7.3ps Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Normalized Delay of Gates vs. h
t = 7.3ps NOR2: g=1.57, p=1.89 NAND2: g=1.14, p=1.45 Inverter: g=1, p=0.93 Effort Delay Parasitic Delay Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Normalized Delay Estimate of Gates vs. h
Note: To simplify analysis Assume Cp-inv = Cinv NOR2: g=5/3, p=2 NAND2: g=4/3, p=2 Inverter: g=1, p=1 Effort Delay Parasitic Delay Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Finding Optimal delay How should we size the gates to get the best delay? Given Cout = 64Cin [Harris, Sutherland] Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

LE Path Delay Gate 1 Gate 2 Gate 3 Cout Input Capacitance Cin C2 C3 Logical Effort: g1 g2 g3 Parasitic Delay p1 p2 p3 Stage Effort: f1 f2 f3 Any n-stage path can be described using Logical Effort Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

LE Path Delay Optimization

LE Path Delay Optimization (cont.)
By Definition, Cin and Cout are fixed. Solve for C2 and C3: Minimum delay occurs when stage efforts are equal Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Simplified Path Optimization
We want the effort of each stage to be equal. = Path Effort = Stage Effort To quickly solve for F: = Logical Effort of the path Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay Optimization Example
Cin = 1 C2 C3 C4 g f = gh Ci Gate 1 1 Gate 2 1 Gate 3 1 Gate 4 1 81 Total Delay = (84 + 4pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Cin = 1 C2 C3 C4 g f = gh Ci Gate 1 1 Gate 2 1 Gate 3 1 40.5 Gate 4 1 2 40.5 Total Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Cin = 1 C2 C3 C4 g f = gh Ci Gate 1 1 Gate 2 1 10.1 Gate 3 1 4 10.1 Gate 4 1 2 40.5 Total Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Cin = 1 C2 C3 C4 g f = gh Ci Gate 1 1 10.1 Gate 2 1 10.1 Gate 3 1 4 10.1 Gate 4 1 2 40.5 Total Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Optimal Sizing for Delay
Cin = 1 C2 C3 C4 g f = gh Ci Gate 1 1 3 Gate 2 1 3 Gate 3 1 3 9 Gate 4 1 3 27 Optimal Delay = (12 + 4pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay Optimization and Sizing Example
Cin = 1 C2 C3 C4 Use Logical Effort to optimize sizes for Delay Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Delay Optimization and Sizing Example Cin = 1 C2 C3 C4 Size from output to input using fopt Delay Estimate Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 2: Path Optimization
C2 C4 Cin = 1 C3 g f = gh Ci Size Gate 1 1 Gate 2 5/3 5/3*3/5 1 Gate 3 4/3 4/3*3/4 1 Gate 4 1 81 Total Delay = (85 + 6pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 2: Path Optimization
Cin = 1 C2 C3 C4 g f = gh Ci Size Gate 1 1 3.66 Gate 2 5/3 3.66 2.2 Gate 3 4/3 3.66 8.06 6.04 Gate 4 1 3.66 22.1 Optimal Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 2: LE Solution Cin = 1 C2 C3 C4 Size from output to input using fopt S1 = 1, S2 = 2.2, S3 = 6.04, S4 = 22.1 Delay Estimate Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort for Multi-path
From LE, and Minimum delay occurs when Da = Db or Fa = Fb (ignoring parasitics) Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort for Multi-path (cont.)
Branching: Ratio of total capacitance to on-path capacitance Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Logical Effort for Multi-path (cont)
Substituting C0 and C3 Since Minimum Delay occurs when Da = Db or Fa = Fb Similarly Branching = 2 when Ga = Gb and Cout1 = Cout2 Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 3: Uniform Branching C6 C5 Cout2 = C5+C3 Cin = 1 C2 C4 C3 g f = gh Ci b Gate 1 1 Gate 2 5/3 10/3 1 2 Gate 3,5 4/3 1 Gate 4,6 1 81 Total Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 3: Uniform Branching C6 C5 Cout2 = C5+C3 Cin = 1 C2 C4 C3 g f = gh Ci b Gate 1 1 4.36 Gate 2 5/3 4.36 2 Gate 3,5 4/3 4.36 5.69 1 Gate 4,6 1 4.36 18.6 Optimal Delay = ( pinv)t Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Example 3: LE Solution C6 Cout2 = C5+C3 C5 Cin = 1 C2 C3 C4 Size from output to input using fopt Delay Estimate Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

Complex Multi-path Optimization
If each path has internal branching, ba and bb are as follows Note: This solution and previous solution differ from that described in LE book (which is incorrect) Fall 2005 Vojin G. Oklobdzija: High-Performance System Design

RC Modeling and Logical Effort Basics

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