Analog Layout - PowerPoint PPT Presentation

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Analog Layout

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Title: Mixed-Signal Design for Power Management and Distribution Systems for SOAC Subject: Mixed-Signal Design for PMAD for SOAC Author: blalock – PowerPoint PPT presentation

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Title: Analog Layout


1
Analog Layout
2
Analog Layout
  • MOSFET Layout
  • layout example (with schematic)

3
Analog Layout
  • CMOS Passive Elements
  • Poly1-poly2 capacitor structure

4
Analog Layout
  • CMOS Passive Elements
  • Parasitics associated with the poly1-poly2
    capacitor structure

5
Analog Layout
  • CMOS Passive Elements
  • Careful layout can reduce parasitic resistance
    associated with cap structure

6
Analog Layout
  • CMOS Passive Elements
  • Additional options for implementing capacitors in
    CMOS technology include
  • metal1-metal2 capacitors
  • MOS caps (drain shorted to source MOSFET
    operating in SI)
  • n or p diffusions to well or substrate
  • Well-to-substrate

7
Analog Layout
  • CMOS Passive Elements
  • Good analog design utilizes ratioing of
    components

8
Analog Layout
  • CMOS Passive Elements
  • Guard ring components to isolate them from
    substrate noise

9
Analog Layout
  • CMOS Passive Elements
  • Good example of layout of matched elements (R1
    R2)
  • consistent orientation (horizontal in this case)
  • consistent parasitics
  • dont forget to guard ring!

10
Analog Layout
  • CMOS Passive Elements
  • Common-centroid layout improves element matching
    (at the expense of uneven parasitics between the
    elements)
  • in Fig. 7.7(a), RA 16 and RB 20
  • in Fig. 7.7(b), RA 18 and RB 18

11
Analog Layout
  • Common-centroid structure for four elements
    (resistors, MOSFETs, or capacitors)

12
Analog Layout
  • Also use dummy elements to improve matching

13
Analog Layout
  • Beware of poly under etching in layout of
    capacitor unit cells!
  • Circular poly structures guarantee consistent
    under etching

14
Analog Layout
  • Good layout practices for analog circuits
  • Use gate lengths several times larger than the
    technologys minimum gate length if all possible.
    This helps reduces ? effects while improving
    matching.
  • Use multiple source/drain contacts along the
    width of the transistor to reduce parasitic
    resistance and provides evenly distributed
    current through the device.

15
Analog Layout
  • Good layout practices for analog circuits
    (continued)
  • Interdigitize large aspect ratio devices to
    reduce source/drain depletion capacitance. Using
    an even number (n) of gate fingers can reduce
    Cdb, Csb by one-half or (n 2)/2n depending on
    source/drain designation. Typically it is
    preferred to reduce drain capacitance more so
    than source capacitance. Also use dummy poly
    strips to minimize mismatch induced by etch
    undercutting during fab.

16
Analog Layout
  • Good layout practices for analog circuits
    (continued)
  • Matched devices should have identical
    orientation. An example of what not to do is
    shown below.

17
Analog Layout
  • Good layout practices for analog circuits
    (continued)
  • Interdigitization can be used in a multiple
    transistor circuit layout to distribute process
    gradients across the circuit. This improves
    matching.
  • Use common-centroid structures.

18
Analog Layout
  • Matching Errors in MOSFET Current Mirrors
  • Good layout design is essential for circuits
    needing matched devices.
  • Layout techniques are effectively used to
    minimize first-order mismatch errors due to
    variations in these process parameters
    gate-oxide thickness, lateral diffusion, oxide
    encroachment, and oxide charge density.

19
Analog Layout
  • Matching Errors in MOSFET Current Mirrors
    (continued)
  • Considering only the effects of threshold voltage
    mismatch within the simple current mirror, its
    current ratio is described by
  • for SI saturation operation if a symmetric
    distribution in threshold voltage across the
    circuit is assumed (i.e., VTHN1 VTHN ? 0.5?VTHN
    and VTHN2 VTHN 0.5?VTHN). Note the
    dependence on VGS. A reduction in VGS increases
    the input/output error in current mirrors induced
    by threshold voltage mismatch.

20
Analog Layout
  • Matching Errors in MOSFET Current Mirrors
    (continued)
  • Considering only transconductance parameter
    mismatch,
  • where the value of KPn is the average
    transconductance parameter between the two
    transistors within the simple current mirror.
  • Considering only VDS and ? effects SI sat. ,
  • These, too, can be a significant source of error
    (e.g., 11! if VDS1 2V, VDS2 4V, (?c ?m)1
    0.04V-1, and (?c ?m)1 0.05V-1).
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