SCBA017

Application Report
SCBA017D – February 2004
Quad Flatpack No-Lead Logic Packages
Frank Mortan and Lance Wright
SLL Package Development
ABSTRACT
Texas Instruments (TI) Quad Flatpack No-lead (QFN) 14/16/20-terminal Pb-free plastic packages
meet dimensions specified in JEDEC standard MO-241, allow for board miniaturization, and hold
several advantages over traditional SOIC, SSOP, TSSOP, and TVSOP packages. The packages are
physically smaller, have a smaller routing area, improved thermal performance, and improved
electrical parasitics, while giving customers a pinout scheme that is consistent with the previously
mentioned packages. Additionally, the absence of external leads eliminates bent-lead concerns and
issues. These QFN packages have reliable solderability with either SnPb or Pb-free solder paste and
are packaged to industry-standard tape-and-reel specifications. Package marking is in accordance
with TI standards.
1
2
3
4
5
6
7
8
9
10
Contents
Introduction..................................................................................................................................... 4
1.1 Product Offerings...................................................................................................................... 4
Physical Description ...................................................................................................................... 5
2.1 Package Characteristics ........................................................................................................... 5
2.2 QFN Pinout ............................................................................................................................. 11
2.3 Package Nomenclature .......................................................................................................... 12
2.4 Power Dissipation ................................................................................................................... 12
2.5 Electrical ................................................................................................................................. 21
2.6 Board-Level Reliability ............................................................................................................ 24
Board-Level Assembly................................................................................................................. 25
3.1 PCB Design Guidelines .......................................................................................................... 25
3.2 PCB Land-Pattern Design ...................................................................................................... 26
3.3 Stencil Design......................................................................................................................... 29
3.4 Component Placement and Reflow ........................................................................................ 31
3.5 Rework.................................................................................................................................... 34
Tape-and-Reel Packing ................................................................................................................ 35
4.1 Material Specifications............................................................................................................ 35
4.2 Labels .................................................................................................................................... 38
4.3 Dry-Pack Requirements for Moisture-Sensitive Material ........................................................ 40
4.3.1 Symbols and Labels.................................................................................................... 42
Symbolization ............................................................................................................................... 44
Test Sockets ................................................................................................................................. 44
Features and Benefits .................................................................................................................. 45
Conclusion .................................................................................................................................... 45
Acknowledgments........................................................................................................................ 45
References .................................................................................................................................... 46
1
SCBA017D
Figures
Figure 1. Cross Section of a Generic QFN Package ............................................................................. 5
Figure 2. 14-Pin QFN Package Dimensions .......................................................................................... 6
Figure 3. 16-Pin QFN Package Dimensions .......................................................................................... 7
Figure 4. 20-Pin QFN Package Dimensions .......................................................................................... 8
Figure 5. 20-Pin QFN Comparison to Alternative Package Solutions.................................................... 9
Figure 6. 16-Pin QFN Comparison to Alternative Package Solutions.................................................. 10
Figure 7. 14-Pin QFN Comparison to Alternative Package Solutions.................................................. 10
Figure 8. 20-Pin QFN Package Standard Pinout................................................................................. 11
Figure 9. 14-Pin QFN Package Standard Pinout................................................................................. 12
Figure 10. 20-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card ................. 15
Figure 11. 16-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card ................. 15
Figure 12. 14-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card ................. 16
Figure 13. The Effect of Board Layers and Vias on 20-Pin QFN Power Dissipation
(JEDEC Test Cards and Zero Airflow) ............................................................................. 16
Figure 14. Effect of Board Layers and Vias on θJA (JESD 51-3 vs JESD 51-5)................................... 17
Figure 15. Effect of Board Layers and Vias on θJA (JESD 51-7 vs JESD 51-5)................................... 17
Figure 16. Modeled θJA vs Number of Thermal Vias on JESD 51-5 Test Card (20-Pin QFN) ............. 18
Figure 17. Modeled Thermal Impedance of 20-Pin QFN vs Alternative Packaging............................. 19
Figure 18. Modeled Thermal Impedance of 16-Pin QFN vs Alternative Packaging............................. 19
Figure 19. Modeled Thermal Impedance of 14-Pin QFN vs Alternative Packaging............................. 20
Figure 20. Modeled 20-Pin Package-Parasitics Comparison .............................................................. 22
Figure 21. Modeled 16-Pin Package-Parasitics Comparison .............................................................. 23
Figure 22. Modeled 14-Pin Package-Parasitics Comparison .............................................................. 23
Figure 23. Critical Dimensions of 14-Pin QFN Package Land Pad...................................................... 25
Figure 24. Cross Section of QFN Terminal-Land-Pad Geometry ........................................................ 26
Figure 25. Recommended PCB Land-Pad Design for 20-Pin QFN Package ...................................... 27
Figure 26. Recommended PCB Land-Pad Design for 16-Pin QFN Package ...................................... 28
Figure 27. Recommended PCB Land-Pad Design for 14-Pin QFN Package ...................................... 28
Figure 28. Stencil-Design Recommendation for 20-Pin QFN Package ............................................... 30
Figure 29. Stencil-Design Recommendation for 16-Pin QFN Package ............................................... 30
Figure 30. Stencil-Design Recommendation for 14-Pin QFN Package ............................................... 31
Figure 31. Pb-Free-Paste Reflow Profile ............................................................................................. 32
Figure 32. Generic SnPb Reflow Profile .............................................................................................. 33
Figure 33. Carrier-Tape Dimensions ................................................................................................... 36
Figure 34. Reel Specifications ............................................................................................................. 37
Figure 35. Carrier-Tape Cavity Quadrant Location for Pin 1, Per EIA-481B ....................................... 37
Figure 36. Pin-1 Orientation of QFN Packages in Carrier Tape .......................................................... 38
Figure 37. Reel Labeling...................................................................................................................... 38
Figure 38. Regular Shipping-Box Label Placement ............................................................................. 39
Figure 39. Label Placement On Shipping Box with Flap ..................................................................... 39
Figure 40. Child-Lot Label Placement on Shipping-Box Label Flap .................................................... 39
Figure 41. Humidity Indicator Card ...................................................................................................... 40
Figure 42. Label Placement on Tape-and-Reel Moisture-Barrier Bag................................................. 41
Figure 43. Moisture-Sensitivity Symbol ............................................................................................... 42
Figure 44. MSID Label ......................................................................................................................... 42
Figure 45. Moisture-Sensitivity Caution Label for Levels 2–5a............................................................ 43
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Quad Flatpack No-Lead Logic Packages
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Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 8.
Table 9.
Table 10.
Table 11.
Table 12.
Table 13.
Tables
Product Technology Families for 14-, 16-, and 20-Pin QFN Packages ..............................4
QFN Package Physical Attributes.......................................................................................5
Modeled 20-Pin QFN Thermal-Impedance Values...........................................................13
Modeled 16-Pin QFN Thermal-Impedance Values...........................................................14
Modeled 14-Pin QFN Thermal-Impedance Values...........................................................14
Modeled 20-Pin QFN Package-Parasitics Comparison....................................................21
Modeled 16-Pin QFN Package-Parasitics Comparison....................................................21
Modeled 14-Pin QFN Package-Parasitics Comparison....................................................22
Board-Level Package Shear Values for QFN Packages (n = 19).....................................24
Carrier-Tape Dimensions..................................................................................................36
Dry-Pack Requirements for MSL Level 1 and Level 2 Packages .....................................40
Floor Life Under Conditions Other Than 30°C and 60% Relative Humidity......................41
Device-Marking Guidelines...............................................................................................44
Quad Flatpack No-Lead Logic Packages
3
SCBA017D
1
Introduction
As worldwide mobility increases, consumers wanting to "stay connected" in the digital world
have demanded smaller and lighter products. Consumer-electronics manufacturers are striving
to reduce product size to meet this demand. Smaller, thinner, and thermally enhanced
packages help achieve product miniaturization. A performance analysis has shown that quad
flatpack no-lead (QFN) packages have better thermal performance than dual in-line surfacemount technology (SMT) packages. Other benefits of the QFN packages are low inductance
and capacitance, small package volume, smaller board routing area, and no external leads,
compared to conventional leaded packages. Texas Instruments (TI) has chosen the QFN
packages as one of the vehicles that allows electronic-component manufacturers to achieve
product miniaturization.
QFN packages of 14-, 16-, and 20-pins will be offered in many logic or linear product families,
as defined in Section 1.1, Product Offerings. This package is ideal for space-constrained
products such as cellular, DVD/CD players, MP3 players, VCRs, digital STB, DSC, notebook
computers, PC cards, and personal digital assistants (PDAs). These packages also are best
suited for products with increased thermal and electrical requirements.
The QFN packages are depopulated and dimensionally align with JEDEC standard MO-241.[1]
The package construction allows the pinout to remain consistent with current SOIC, SSOP,
TSSOP, and TVSOP packages. Package features, characteristics, and performance are
defined in this application report.
1.1
Product Offerings
Table 1 shows the product families to be offered initially in 14-, 16-, and 20-pin QFN packages.
Available functions are too numerous to list. Additionally, based on customer demand, the
product-family list is expected to grow. Please see the TI website at www.ti.com for the latest list
of product families and functions.
Table 1.
Product Technology Families for 14-, 16-, and 20-Pin QFN Packages
Family
4
Description
Pins
ABT
Advanced BiCMOS Technology
14, 20
AHC/AHCT
Advanced High-Speed CMOS
14, 16
ALVC
Advanced Low-Voltage CMOS Technology
14
CBT
Crossbar Technology
14, 16, 20
CBTLV
Low-Voltage Crossbar Technology
14, 16, 20
GTLP
Gunning-Transceiver Logic Plus
LV
Low-Voltage HCMOS Technology
14, 16, 20
LVC
Low-Voltage CMOS Technology
14, 16, 20
LVT
Low-Voltage BiCMOS Technology
Quad Flatpack No-Lead Logic Packages
16
14, 20
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2
Physical Description
2.1
Package Characteristics
Figure 1 shows the cross section of a generic QFN package.
Figure 1.
Cross Section of a Generic QFN Package
Table 2 summarizes the package attributes for the 14-, 16-, and 20-pin QFN packages. Figures
2, 3, and 4 show dimensions on package outline drawings.
Table 2.
QFN Package Physical Attributes
Attribute
Pin count
Square/rectangular
Package length, mm nominal
Package width, mm nominal
Lead finger length, mm nominal
Lead finger width, mm nominal
Exposed pad length, mm max.
Exposed pad width, mm max.
Thickness, mm nominal
Package weight, g
Lead finish
Shipping media, tape and reel (units per reel)
MSL level
QFN-14
14
Square
3.5
3.5
0.4
0.23
2.15
2.15
0.90
0.032
Matte tin
1000
Level 2/260°C
QFN-16
16
Rectangular
4.0
3.5
0.4
0.23
2.65
2.15
0.90
0.036
Matte tin
1000
Level 2/260°C
QFN-20
20
Rectangular
4.5
3.5
0.4
0.23
3.15
2.15
0.90
0.043
Matte tin
1000
Level 2/260°C
Quad Flatpack No-Lead Logic Packages
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SCBA017D
Top View
Side View
Bottom View
All dimensions are in mm.
Figure 2. 14-Pin QFN Package Dimensions
6
Quad Flatpack No-Lead Logic Packages
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14-Pin QFN Package Dimensions
Top View
Side View
Bottom View
All dimensions are in mm.
Figure 3. 16-Pin QFN Package Dimensions
Quad Flatpack No-Lead Logic Packages
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Top View
Side View
Bottom View
All dimensions are in mm.
Figure 4. 20-Pin QFN Package Dimensions
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Figures 5 through 7 compare the QFN package size, height, and weight to that of alternative
package solutions.
SOIC-20
(DW)
SSOP-20
(DB)
TSSOP-20
(PW)
TVSOP-20
(DGV)
QFN-20
(RGY)
Length, mm
12.82 ±0.13
7.20 ±0.30
6.50 ±0.10
5.00 ±0.10
4.50 ±0.15
Width, mm
Attribute
10.40 ±0.25
7.80 ±0.40
6.40 ±0.20
6.40 ±0.20
3.50 ±0.15
Height, Max. mm
2.65
2.00
1.20
1.20
1.00
Pitch, mm
1.27
0.65
0.65
0.40
0.50
Footprint, mm2
133.33
56.16
41.60
32.00
15.75
Weight, g
0.495
0.151
0.075
0.055
0.043
Area savings, %
88.19
71.96
62.14
50.78
-
Figure 5. 20-Pin QFN Comparison to Alternative Package Solutions
Quad Flatpack No-Lead Logic Packages
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SOIC-16
(D)
Attribute
SSOP-16
(DB)
TSSOP-16
(PW)
TVSOP-16
(DGV)
QFN-16
(RGY)
Length, mm
9.90 ±0.10
6.20 ±0.30
5.00 ±0.10
3.60 ±0.10
4.00 ±0.15
Width, mm
6.00 ±0.20
7.80 ±0.40
6.40 ±0.20
6.40 ±0.20
3.50 ±0.15
Height, Max. mm
1.75
2.00
1.20
1.20
1.00
Pitch, mm
1.27
0.65
0.65
0.40
0.50
Footprint, mm
59.40
48.36
32.00
23.04
14.00
Weight, g
0.150
0.140
0.062
0.040
0.036
Area savings, %
76.43
71.05
56.25
39.24
-
2
Figure 6. 16-Pin QFN Comparison to Alternative Package Solutions
SOIC-14
(D)
SSOP-14
(DB)
TSSOP-14
(PW)
TVSOP-14
(DGV)
QFN-14
(RGY)
Length, mm
8.65 ±0.10
6.20 ±0.30
5.00 ±0.10
3.60 ±0.10
3.50 ±0.15
Width, mm
6.00 ±0.20
7.80 ±0.40
6.40 ±0.20
6.40 ±0.20
3.50 ±0.15
1.75
2.00
1.20
1.20
1.00
Attribute
Height, Max., mm
Pitch, mm
1.27
0.65
0.65
0.40
0.50
Footprint, mm
51.90
48.36
32.00
23.04
12.25
Weight, g
0.127
0.122
0.055
0.040
0.032
Area savings, %
76.40
74.67
61.72
46.83
-
2
Figure 7. 14-Pin QFN Comparison to Alternative Package Solutions
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2.2
QFN Pinout
The standard pinout configurations for 14-, 16-, and 20-pin QFN packages resemble the
conventional arrangement of 14-, 16-, and 20-pin dual-in-line packages. Figures 8 and 9 show
standard QFN pinouts for 14- and 20-pin QFN packages. These pinouts are accurate for most
devices; however, some functions vary, especially in the 16-pin package. Please refer to the
device data sheet to confirm specific pinouts. Note the flow-through design afforded by the
package configuration.
1§
1
20 †
2‡
19 §
3‡
18 ‡
4‡
17 ‡
5‡
16 ‡
6‡
15 ‡
7‡
14 ‡
8‡
13 ‡
9‡
12 ‡
10 ¶
20
11 ‡
† = VCC
‡ = I/O and Signal
§ = Control
¶ = Ground
NOTES: A. Schematic is not drawn to scale.
B. No ground connection exists through die back side to pad.
Figure 8. 20-Pin QFN Package Standard Pinout
Quad Flatpack No-Lead Logic Packages
11
SCBA017D
1‡
14 †
2 ‡
13 ‡
3‡
12 ‡
4‡
11 ‡
5‡
10 ‡
6‡
9§
7¶
8§
† = VCC
‡ = I/O and Signal
§ = Control
¶ = Ground
NOTES: A. Schematic is not drawn to scale.
B. No ground connection exists through die back side to pad.
Figure 9. 14-Pin QFN Package Standard Pinout
2.3
Package Nomenclature
These packages are referred to generically in this application report as QFN. The TI package
designator for these 14-, 16-, and 20-pin QFN packages is RGY. This common designator refers
to these three packages with a common width of 3.5 mm. The designator is extended to RGYR
to designate parts packed using the tape-and-reel method (see Section 5, Tape-and-Reel
Packing).
2.4
Power Dissipation
When thermal dissipation is crucial, the QFN package has an advantage over standard dual
and quad leaded packages. The leadframe die pad is exposed at the bottom of the package
and should be soldered to a properly designed thermal pad on the printed circuit board (PCB).
This provides a more direct heat-sink path from the die to the board, and the addition of thermal
vias from the thermal pad to an internal ground plane will dramatically increase power
dissipation. Soldering the exposed pad also significantly improves board-level reliability during
temperature cycling, key push, package shear, and similar board-level tests.
Unless otherwise stated, the model data shown in Tables 3, 4, and 5 assume that the packages
have the exposed pad soldered to the thermal pad on the PCB. The thermal effects of
intentionally omitting solder from the exposed pad also is shown later in this section for
informational purposes. The standards used for these models are available for downloading at
http://www.jedec.org/download/default.cfm.[2,3,4] Customers are highly encouraged to
familiarize themselves with these standards when comparing the power-dissipation
performance of similar or alternative packaging, to ensure that the comparison is made on
equivalent terms.
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Quad Flatpack No-Lead Logic Packages
SCBA017D
It is important to understand that the modeled data is intended for comparison of the QFN
package to alternative packages under similar conditions (the standards mentioned previously).
System-level performance is heavily dependent upon board thickness, metal layers, component
spacing (thermal coupling), airflow, and board orientation in the system. The model data
provided also can be used to construct system-level thermal models to predict performance in
any particular system, but does not reflect the package’s performance in any system as listed,
except in accordance with the standards under which it was modeled.
For data in Tables 3, 4, and 5, values are given for each standard. All standards use the same
land pad and thermal pad design; however, they differ in internal board construction. Test cards
that comply with JESD 51-3 do not have internal metal layers and are, naturally, the worst case
in performance. The shorthand reference for this board design is 1S0P, meaning one signal,
zero planes. JESD 51-5 has two internal metal layers and thermal vias connecting the upper
layer to the thermal pad. These vias are 0.30-mm diameter and are spaced 1.2 mm, center to
center. The vias are allowed to populate only the region defined by the perimeter of the thermal
pad and cannot extend beyond the perimeter. This is referred to as 1S2P direct-attached
method. JESD 51-7 test cards have the same two metal layers as the JESD 51-5 test card, but
no vias are allowed. This is referred to as 1S2P. The standards also allow for a second signal
trace on the backside (2S2P or 2S0P), but the backside signal traces make little difference
(<2%) in most cases. These three standards give a wide range of conditions under which
alternative packages can be compared.
Table 3.
Modeled 20-Pin QFN Thermal-Impedance Values
20-Pin QFN Per JESD 51-5 (1S2P Direct-Attach Method)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJP (°C/W)
θJB (°C/W)
0
29.9
15.2
0.52
5.2
150
23.1
250
21.2
500
19.5
20-Pin QFN Per JESD 51-7 (1S2P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJB (°C/W)
15.2
8.7
0
46.8
150
40.5
250
38.2
500
36
20-Pin QFN Per JESD 51-3 (1S0P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
0
77.5
15.2
NOTES: A. θJB is neither applicable nor defined for JESD 51-3 test cards.
B. θJP is junction-to-pad thermal impedance.
Quad Flatpack No-Lead Logic Packages
13
SCBA017D
Table 4.
Modeled 16-Pin QFN Thermal-Impedance Values
16-Pin QFN Per JESD 51-5 (1S2P Direct-Attach Method)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJP (°C/W)
θJB (°C/W)
16.23
0.6
4.3
0
31.2
150
24.4
250
22.5
500
20.7
16-Pin QFN Per JESD 51-7 (1S2P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJP (°C/W)
θJB (°C/W)
16.23
5.33
10.0
0
49.6
150
42.4
250
40.1
500
37.8
16-Pin QFN Per JESD 51-3 (1S0P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
0
79.9
16.23
NOTES: A. θJB is neither applicable nor defined for JESD 51-3 test cards.
B. θJP is junction-to-pad thermal impedance.
Table 5.
Modeled 14-Pin QFN Thermal-Impedance Values
14-Pin QFN Per JESD 51-5 (1S2P Direct-Attach Method)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJP (°C/W)
θJB (°C/W)
17.37
0.75
4.9
0
31.6
150
25.1
250
500
23.1
21.4
14-Pin QFN Per JESD 51-7 (1S2P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
θJB (°C/W)
17.37
10.3
0
52.5
150
46
250
42.9
500
40.5
14-Pin QFN Per JESD 51-3 (1S0P)
Airflow, LFM
θJA (°C/W)
θJC (°C/W)
0
81.9
17.37
NOTES: A. θJB is neither applicable nor defined for JESD 51-3 test cards.
B. θJP is junction-to-pad thermal impedance.
14
Quad Flatpack No-Lead Logic Packages
SCBA017D
Figures 10 through 12 show power dissipation of QFN packages on the JEDEC standard test
cards.[2, 3, 4] All power-dissipation values assume a junction temperature of 150°C and are
modeled.
Power Dissipation – W
7.5
6.5
5.5
LFM=0
LFM=150
4.5
LFM=250
LFM=500
3.5
2.5
1.5
20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95
TA – Free-Air Temperature – °C
Figure 10. 20-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card
6.5
Power Dissipation – W
6
5.5
5
LFM=0
4.5
4
LFM=150
3.5
LFM=250
3
LFM=500
2.5
2
1.5
20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95
TA – Free-Air Temperature – °C
Figure 11. 16-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card
Quad Flatpack No-Lead Logic Packages
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SCBA017D
Power Dissipation – W
7
6
5
LFM=0
LFM=150
4
LFM=250
LFM=500
3
2
1
20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95
TA – Free-Air Temperature – °C
Figure 12. 14-Pin QFN Power Dissipation on JESD 51-5 (1S2P Direct Attach) Test Card
The largest single factor affecting power dissipation is board construction. For the JEDEC test
cards that were used to obtain the results in Figures 10 through 12, the JESD 51-5 direct-attach
standard offers the best performance. Figures 13 through 16 show the effect of board
construction on power dissipation and thermal impedance for the QFN packages.
4.5
Power Dissipation – W
4
3.5
3
2.5
JESD 51-5 (1S2P With Vias)
2
JESD 51-7 (1S2P)
1.5
JESD 51-3 (1S0P)
1
0.5
0
20
30
40
50
60
70
80
90
TA – Free-Air Temperature – °C
Figure 13. The Effect of Board Layers and Vias on 20-Pin QFN Power Dissipation
(JEDEC Test Cards and Zero Airflow)
16
Quad Flatpack No-Lead Logic Packages
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90
80
81.9
79.9
77.5
70
θJA – °C/W
60
50
JESD 51-3
40
30
31.6
31.2
29.9
JESD 51-5
20
10
0
20 QFN
16 QFN
14 QFN
Figure 14. Effect of Board Layers and Vias on θJA (JESD 51-3 vs JESD 51-5)
60
50
52.2
49.6
46.8
θJA – °C/W
40
30
29.9
31.2
31.6
JESD 51-7
JESD 51-5
20
10
0
20 QFN
16 QFN
14 QFN
Figure 15. Effect of Board Layers and Vias on θJA (JESD 51-7 vs JESD 51-5)
Quad Flatpack No-Lead Logic Packages
17
SCBA017D
50
46.8
45
θJA – °C/W
42.2
40
39
35.1
35
32.8
31.4
30.8
30
29.9
25
0
2
4
6
8
10
12
14
Number of Thermal Vias
Figure 16. Modeled θJA vs Number of Thermal Vias
on JESD 51-5 Test Card (20-Pin QFN)
18
Quad Flatpack No-Lead Logic Packages
16
18
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Figures 17 through 19 compare the junction-to-ambient thermal impedance of the QFN
packages to popular packaging alternatives. These modeled values are on the applicable
high-thermal-conductivity boards, as specified by JESD 51-5 and JESD 51-7.
100
90
91.9
83
80
69.5
θJA – °C/W
70
57.7
60
50
40
29.9
30
20
10
0
TVSOP-20
TSSOP-20
SSOP-20
SOIC-20
QFN-20
Figure 17. Modeled Thermal Impedance of 20-Pin QFN vs Alternative Packaging
140
120
119.8
108.4
100
θJA – °C/W
82
73.1
80
60
40
31.2
20
0
TVSOP-16
TSSOP-16
SSOP-16
SOIC-16
QFN-16
Figure 18. Modeled Thermal Impedance of 16-Pin QFN vs Alternative Packaging
Quad Flatpack No-Lead Logic Packages
19
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140
127.1
120
112.6
95.8
100
θJA – °C/W
86.2
80
60
40
31.6
20
0
TVSOP-14
TSSOP-14
SSOP-14
SOIC-14
QFN-14
Figure 19. Modeled Thermal Impedance of 14-Pin QFN vs Alternative Packaging
20
Quad Flatpack No-Lead Logic Packages
SCBA017D
2.5
Electrical
Inductance is related directly to the length of a wire and its proximity to the ground plane. Any
wire naturally creates an inductor. The longer the wire, the greater its inductance. Inductance
occurs when current is induced into a wire, creating an electromagnetic field. The closer this
induced electromagnetic field is to ground, the less effective it becomes. As the wire gets
shorter and/or closer to the ground plane, its inductance decreases.
Capacitance is created when two plates (wires, lines, or layers) overlap and are separated by a
given distance. This distance can be insulated by air, plastic, glass, or other materials.
Capacitance can be calculated by:
C = (0.225εrA) / d
(1)
Where:
C = capacitance
εr = dielectric value of insulator
A = area that plates overlap
d = distance between plates
Area changes the most from package to package. The distances lead to lead and die pad to
ground plane vary somewhat, while the dielectric value of the insulators (εr) remains relatively
constant.
The unique construction of QFN packages reduces inductance. The exposed die pad of the
QFN package is at board level, following assembly, which minimizes inductance. Tables 6
through 8 and Figures 20 through 22 compare modeled package parasitics of the QFN
packages with other packaging options using the same die.
Table 6.
Modeled 20-Pin QFN Package-Parasitics Comparison
SOIC-20
(DW)
SSOP-20
(DB)
TSSOP-20
(PW)
TVSOP-20
(DGV)
QFN-20
(RGY)
Average R, Ω
0.038
0.040
0.050
0.044
0.050
Average L, nH
5.012
3.495
2.802
2.561
1.119
Average C, pF
0.717
0.420
0.317
0.342
0.352
Table 7.
Modeled 16-Pin QFN Package-Parasitics Comparison
SOIC-16
(D)
SSOP-16
(DB)
TSSOP-16
(PW)
TVSOP-16
(DGV)
QFN-16
(RGY)
Average R, Ω
0.039
0.048
0.045
0.039
0.039
Average L, nH
3.453
3.536
2.593
2.543
0.886
Average C, pF
0.521
0.376
0.281
0.386
0.327
Quad Flatpack No-Lead Logic Packages
21
SCBA017D
Table 8.
Modeled 14-Pin QFN Package-Parasitics Comparison
SOIC-14
(D)
SSOP-14
(DB)
TSSOP-14
(PW)
TVSOP-14
(DGV)
QFN-14
(RGY)
Average R, Ω
0.031
0.044
0.032
0.035
0.033
Average L, nH
3.109
3.551
2.378
2.499
0.738
Average C, pF
0.473
0.402
0.314
0.361
0.316
6
5
4
R
L
C
3
2
1
0
TVSOP-20
TSSOP-20
SSOP-20
SOIC-20
QFN-20
Figure 20. Modeled 20-Pin Package-Parasitics Comparison
22
Quad Flatpack No-Lead Logic Packages
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4
3.5
3
2.5
R
L
2
C
1.5
1
0.5
0
TVSOP-16
TSSOP-16
SSOP-16
SOIC-16
QFN-16
Figure 21. Modeled 16-Pin Package-Parasitics Comparison
4
3.5
3
2.5
R
L
2
C
1.5
1
0.5
0
TVSOP-14
TSSOP-14
SSOP-14
SOIC-14
QFN-14
Figure 22. Modeled 14-Pin Package-Parasitics Comparison
Quad Flatpack No-Lead Logic Packages
23
SCBA017D
2.6
Board-Level Reliability
When soldered, the QFN exposed-pad design acts as a package anchor, significantly
increasing the board-level reliability over that of an LCC or other leadless packages. The
exposed pad must be soldered to provide the structural integrity expected by industry, as well
as optimal thermal performance.
The 14- and 20-pin QFN packages have passed 1000 thermal cycles from –40°C to 125°C,
2 cycles per hour, on a 1.5-mm-thick FR-4 PWB. Pad finishes were NiAu for the SnPb paste
and pure Sn for the Pb-free paste. The pastes used were SnPb (63/37) and the Senju Pb-free
96.5Sn/3.0Ag/0.5Cu. The temperature cycling tests continue and will end when data collection
is complete.
Board-level package shear also was measured for both packages and pastes. Table 9
summarizes the results.
Table 9.
Board-Level Package Shear Values for QFN Packages (n = 19)
20-Pin RGY
Average, kg
24
14-Pin RGY
Pb Free
SnPb
Pb Free
SnPb
29.378
31.360
24.580
25.405
Maximum, kg
31.392
34.775
30.34
28.845
Minimum, kg
27.314
27.285
21.131
20.217
Standard
Deviation
1.087
2.073
2.167
2.614
Quad Flatpack No-Lead Logic Packages
SCBA017D
3
Board-Level Assembly
3.1
PCB Design Guidelines
One of the key efforts in implementing the QFN package is the design of the land pattern. The
QFN has rectangular metal terminals exposed on the bottom peripheral surface of the package
body. Electrical and mechanical connections between the component and the PCB are made by
screen-printing solder paste on the PCB and reflowing the paste after placement. To ensure
reliable solder joints, properly designing the land pattern to the QFN terminal pattern is essential.
IPC-SM-782 is used as the standard for the PCB land-pad designs.
There are two basic designs for PCB land pads for the QFN package: non-solder-mask-defined
(NSMD) and the solder-mask-defined (SMD) styles. The industry has debated the merits of both
styles of land pads and, although we recommend the NSMD pad, both styles are acceptable for
use with the QFN package. NSMD pads are recommended over SMD pads because of the
tighter tolerance on copper etching than on solder masking. NSDM, by definition, also provides a
larger copper-pad area and allows the solder to anchor to the edges of the copper pads, thus
providing improved solder-joint reliability.
Figure 23 illustrates the critical dimensions of a generic QFN land pattern.
Symbol
Description
Zmin
Terminal land pad – outside dimension
Gmin
Terminal land pad – inside dimension
X
Terminal land width
Y
Terminal land length
CLL†
Minimum distance between two perpendicular lands in any corner
CPL†
Minimum distance between die paddle and inside edge of terminal pad
† CLL and C PL are clearance dimensions defined to prevent solder bridging.
Figure 23. Critical Dimensions of 14-Pin QFN Package Land Pad
Quad Flatpack No-Lead Logic Packages
25
SCBA017D
3.2
PCB Land-Pattern Design
As a general rule, for good solder filleting, the PWB terminal pads should be 0.2 mm to 0.5 mm
longer (away from package center) than the package terminal length and also should be
extended 0.05 mm toward the centerline of the package (see Figure 24). To minimize solder
bridging, the pad width should be the maximum width of the component terminal for lead pitches
below 0.65 mm. These pad designs are wide enough to allow for via-in-pad routing techniques
to be employed on an economical basis. Single-layer routing or standard vias outside the
package outline also is feasible because of flow-through design.
PCB Pad
PCB PAD
0.050.05mm
MM
Y2
Y2
0.20 mm
0.20 MM
Y1
Y1
Figure 24. Cross Section of QFN Terminal-Land-Pad Geometry
Zmin should accommodate the maximum package length or width (D or E), the profile
tolerances of the package body (aaa = 0.15 mm for these packages), plus the recommended
extensions (Y1) for fillets on both ends of the package (0.2 mm × 2). In other words:
Zmin = D bsc + aaa + 2(Y1) = D + 0.15 mm + 0.4 mm
(2)
Zmin = E bsc + aaa + 2(Y1) = E + 0.15 mm + 0.4 mm
(3)
Gmin should be designed so that the worst case of maximum terminal length is accommodated.
In this case, Gmin is calculated as follows:
Gmin = D bsc – 2(Lmax) – 2(Y2) = D – 2(0.50) – 2(0.05)
(4)
Gmin = E bsc – 2(Lmax) – 2(Y2) = E – 2(0.50) – 2(0.05)
(5)
The construction of the exposed-pad QFN package provides enhanced thermal and board-level
reliability characteristics. To take full advantage of this feature, the pad must be physically
connected to the PCB substrate with solder.
The thermal pad (see D2th in Figure 23) should be greater than D2 (exposed pad width) of the
package whenever possible. However, adequate clearance (CPL > 0.15 mm) must be met to
prevent solder bridging.
26
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In other words:
D2th > D2 only if D2th < Gmin – (2 x CPL)
(6)
E2th > E2 only if E2th < Gmin – (2 x CPL)
(7)
D2th max = Gmin – 2 (CPL) = Gmin – 2 (0.20)
(8)
E2th max = Gmin – 2 (CPL) = Gmin – 2 (0.20)
(9)
An example of this design is illustrated in Figure 25 for the 20-pin QFN package. Refer to the
package drawing. See Figure 4 for package dimensions and Figure 25 for the land-pad design.
Figures 26 and 27 use the same criteria and show the land-pad design recommendations for
16- and 14-pin QFN packages. All dimensions are in millimeters.
Zmin = D bsc + aaa + 2 (Y1) = 4.5 + 0.15 + 2(0.2) = 5.05
Zmin = E bsc + aaa + 2 (Y1) = 3.5 + 0.15 + 2(0.2) = 4.05
Gmin = D bsc – 2 (Lmax ) – 2(Y2) = 4.5 – 2(0.50) – 2(.05) = 3.4
Gmin = E bsc – 2 (Lmax) – 2(Y2) = 3.5 – 2(0.50) – 2(.05) = 2.4
D2th max = Gmin – 2 (CPL) = 3.4 – 2(0.20) = 3.0
E2th max = Gmin – 2 (CPL) = 2.4 – 2(0.20) = 2.0
NOTE A. All dimensions are in mm.
Figure 25. Recommended PCB Land-Pad Design for 20-Pin QFN Package
Quad Flatpack No-Lead Logic Packages
27
SCBA017D
NOTE A. All dimensions are in mm.
Figure 26. Recommended PCB Land-Pad Design for 16-Pin QFN Package
NOTE A. All dimensions are in mm.
Figure 27. Recommended PCB Land-Pad Design for 14-Pin QFN Package
28
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3.3
Stencil Design
The difference in size between the large exposed pad and small terminal leads of the QFN
presents a challenge in producing an even solder-line thickness. Because of this, careful
consideration must be given to stencil design. Stencil thickness, as well as the etched-pattern
geometry, determines the volume of solder paste deposited on the land pattern. Stencil
alignment accuracy and consistent solder-volume transfer is critical for uniform results in the
solder-reflow process. Usually, stencils are made of polymer or stainless steel, with stainless
steel being more durable and providing less deformation in the squeegee step. Apertures
should be trapezoidal in cross section to ensure uniform release of the solder paste and to
reduce smearing. The solder-joint thickness for QFN terminal leads should be 50 µm to 75 µm.
Stencil thickness usually is in the 100-µm to 150-µm (0.004 in. to 0.006 in.) range, assuming
proper area ratio requirements are satisfied (see IPC-7525).[9] If a step-down stencil design is
not used, the SMT device(s) that are the limiting factor on the PCB determine the actual
thickness of the stencil.
A squeegee with a durometer measurement of 95, or harder, should be used. The blade angle
and speed must be optimized to ensure even paste transfer. Characterization of the stencil
output is recommended before placing parts.
As a guide, a stencil thickness of 0.1016 mm to 0.125 mm (4 mils to 5 mils) for these QFN
packages is recommended. Figures 28 through 30 detail the stencil recommendations for the
14-, 16-, and 20-pin QFN packages. All designs below have area ratios >0.66 and
paste-transfer efficiencies of 73% for terminal pads and 100% for thermal pads at a stencil
thickness of 0.127 mm (5 mils). At a stencil thickness of 0.1016 mm (4 mils), the area ratio is
0.86, terminal-pad paste-transfer efficiency is 89% and 100% for the thermal pad. The
slotted-thermal-pad stencil design is recommended to prevent the QFN package from floating
during reflow and causing opens between the terminal leads and pads. This feature also allows
adequate room for outgassing of paste during the reflow operation, thus minimizing voids.
A low-residue, no-clean Type 3 or Type 4 solder paste is recommended.
Stencil design advice and parameters are provided courtesy of Cookson Electronics, Assembly
Materials Group, at http://www.cooksongroup.co.uk/
Quad Flatpack No-Lead Logic Packages
29
SCBA017D
NOTE A. All dimensions are in mm.
Figure 28. Stencil-Design Recommendation for 20-Pin QFN Package
NOTE A. All dimensions are in mm.
Figure 29. Stencil-Design Recommendation for 16-Pin QFN Package
30
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SCBA017D
NOTE A. All dimensions are in mm.
Figure 30. Stencil-Design Recommendation for 14-Pin QFN Package
3.4
Component Placement and Reflow
The accuracy of the pick-and-place equipment governs the package placement and rotational
(theta) alignment. Slightly misaligned parts (less than 50% off the terminal-pad center)
automatically self-align during reflow. Grossly misaligned packages (greater than 50% off
terminal-pad center) should be removed prior to reflow because they may develop electrical
shorts from solder bridges.
There are two popular methods for package alignment using machine vision:
• Package silhouette—The vision system locates the package outline.
• Lead-frame recognition—Some vision systems can locate directly on the lead-frame
pin-1 ID feature (chamfer on exposed pad).
Both methods are acceptable for QFN package placement, but both have advantages and
disadvantages. Pad-recognition alignment tends to be more accurate, but is slower because
more complex vision processing is required of the pick-and-place machine. The package
silhouette method allows the pick-and-place system to run faster, but generally, is less accurate.
Both methods are acceptable and have been demonstrated successfully by major
pick-and-place equipment vendors and contract assembly houses.
Quad Flatpack No-Lead Logic Packages
31
SCBA017D
There are no special requirements when reflowing QFN packages. As with all components, it is
important that reflow profiles be checked on all new board designs at different locations on the
board because component temperatures may vary because of surrounding thermal sinks,
location of the device on the board, and package densities.
Maximum reflow temperature, soak times, and ramp rates specified for a specific solder paste
should not be exceeded. Please consult your paste manufacturer for specifics regarding your
particular paste because target temperatures and their associated times can vary widely,
depending upon metallurgy and flux composition. In general, SnPb peak temperatures are
approximately 235°C and Pb-free paste is 250°C to 260°C. The matte tin finish used for these
QFN packages has proven interchangeability with either paste type.
Generic Pb-free-paste and SnPb eutectic reflow profiles with time/temperature targets are
shown in Figures 31 and 32. Figure 32 shows a generic SnPb profile.
Recommended Temperature Profile
Sn-Ag-Cu(#7100, M705, M31)
Image courtesy of Senju
Figure 31. Pb-Free-Paste Reflow Profile
32
Quad Flatpack No-Lead Logic Packages
SCBA017D
Recommended Temperature Profile
Sn-Pb Eutectic, AT-Alloy and S2062
Image courtesy of Senju
Time
Figure 32. Generic SnPb Reflow Profile
Quad Flatpack No-Lead Logic Packages
33
SCBA017D
3.5
Rework
QFN-rework processes are an adaptation (and in some cases a simplification) of ball grid array
package-rework processes. The basic elements of this process are:
•
•
•
•
•
•
•
Board preheat
Reflow of component solder
Vacuum removal of component
Cleaning and preparation of PWB lands
Screening of solder paste
Placement and reflow of new component
Inspection of solder joints
Several automated rework systems exist in the market and address the previous steps in a
variety of ways. A system worth noting is by Air-Vac Engineering (http://www.air-vac-eng.com).
The rework steps above (except inspection) can be accomplished with high precision on a
single machine under either computer or manual control.
Another example of a well-established rework system is the Metcal APR-5000. This system
contains the essential hardware and automated software features necessary for reworking QFN
and other packages. This system takes up less than 6 ft2 of manufacturing floor space. Both
systems offer closed-loop, computer-controlled time, temperature, and airflow parameters to
help ensure process control and repeatability. The system software manages the reflow profile:
preheat, soak, ramp, reflow, and cooling. In addition, board temperature can be monitored using
integrated thermocouples, and real-time adjustments can be made to all parameters while the
profile is running.
A variety of off-the-shelf vacuum collets and solder screens are available from Metcal. Please
reference http://www.metcal.com for open tools and for custom tooling requirements.
34
Quad Flatpack No-Lead Logic Packages
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4
Tape-and-Reel Packing
4.1
Material Specifications
TI offers tape-and-reel packing for 14-, 16-, and 20-pin logic QFN packages in standard packing
quantities (SPQ) of 1000 units/reel. The units are shipped in embossed carrier tape, sealed with
heat-activated or pressure-sensitive cover tape, wound on plastic reels. All of the tape-and-reel
materials comply with EIA-481 B, and EIA-541.[5,6] The EIA specifications are shown in
Table 10 and Figures 33 through 35. The carrier tape is made of conductive polystyrene and
has a surface resistivity that falls within the static-dissipative range (1×105 to 1×1011 Ω/square).
Heat-activated or pressure-sensitive, antistatic, clear polyester film is used for the cover tape.
The dimensions of most interest to the end user are tape width (W), cavity pitch (P), and cavity
size (A0, B0, K0), as shown in Figure 33.
The units are placed in the carrier-tape cavity, with pin 1 located as specified in EIA-481B. The
longest axis of the package is perpendicular to the tape sprocket holes, and pin 1 is closest to
the round sprocket holes. Thus, for rectangular or square packages, pin 1 is located in
quadrant 1 (see Figure 35). The 3.5-mm × 4.5-mm 20-pin QFN package is shown in Figure 36.
All dimensions are in millimeters.
Quad Flatpack No-Lead Logic Packages
35
SCBA017D
Table 10.
Package
Carrier-Tape
Width
Carrier-Tape Dimensions
Cavity Pitch
Cavity Width
(P)
(A0)
(W)
Cavity
Length
(B0)
Cavity Depth
(K0)
Device
Quantity
Per Reel
(SPQ)
14-Pin
QFN
12.0 ± 0.30
8.0 ± 0.10
3.80 ± 0.10
3.80 ± 0.10
1.20 ± 0.10
1000
16-Pin
QFN
12.0 ± 0.30
8.0 ± 0.10
3.80 ± 0.10
4.30 ± 0.10
1.20 ± 0.10
1000
20-Pin
QFN
12.0 ± 0.30
8.0 ± 0.10
3.80 ± 0.10
4.80 ± 0.10
1.20 ± 0.10
1000
D0
1.5 + 0.1/ – 0.0
D1
Min
1.5
E1
P0
P2
R Ref
1.75 ± 0.1
4.0 ± 0.1
2.0 ± 0.05
30
S1
T
T1
Min
Max
Max
0.6
0.6
0.1
NOTE A. All dimensions are in mm.
[Ten pitches cumulative
tolerance on tape ±0.2 mm]
ØD0
B1 is for tape
B0
feeder reference
only, including
draft concentric
about B 0
Centerlines of Cavity
User Direction of Unreeling
Figure 33. Carrier-Tape Dimensions
36
Quad Flatpack No-Lead Logic Packages
Embossment
(see Table 10)
SCBA017D
(Hub diameter
See Note 2,
(Hub
diameter)
Tables
1, 2,
and 3
B
(See Note)
NOTE A. Drive spokes optional; if used, dimensions B and D shall apply.
Reel
Diameter
(A)
Reel
Width
(W1)
Hub
Diameter Max
(N)
Reel
Thickness
(W2)
Arbor-Hole
Diameter
(C)
Quantity/Reel
180 ± 0.60
12.4 + 2.0/–0.0
60 ± 0.50
13.65 ± 1.95
13.0 + .5/–0.2
1000
14/16/20 Pins
NOTE B. All dimensions are in mm.
Figure 34. Reel Specifications
Quadrant
1
3
2
4
1
2
3
4
Square
Package
Rectangular
Package
Figure 35. Carrier-Tape Cavity Quadrant Location for Pin 1, Per EIA-481B
Quad Flatpack No-Lead Logic Packages
37
SCBA017D
Figure 36. Pin-1 Orientation of QFN Packages in Carrier Tape
4.2
Labels
All reels have an ESD label or symbol on the hub or flange and have a bar-code label on the
same side of the reel and on the side opposite the carrier-tape round sprocket holes, as shown
in Figure 37.
Figure 37. Reel Labeling
38
Quad Flatpack No-Lead Logic Packages
SCBA017D
Intermediate container orientation and labeling specification for reels is shown in Figures 38, 39,
and 40.
Figure 38. Regular Shipping-Box Label Placement
Figure 39. Label Placement On Shipping Box with Flap
Figure 40. Child-Lot Label Placement on Shipping-Box Label Flap
The moisture-sensitivity caution (MSID) label can appear on any surface of the box, except
areas that will be occupied by other labels, but not on the bottom of the box.
Quad Flatpack No-Lead Logic Packages
39
SCBA017D
4.3
Dry-Pack Requirements for Moisture-Sensitive Material
Moisture-sensitive material, as classified by JEDEC standard J-STD-020, must be dry packed
(see Table 11).[7] Dry packing limits the exposure of the package to moisture so that it can be
reflowed without “popcorning”. Dry packing consists of desiccant material and a
humidity-indicator card (HIC) sealed with the populated reel inside a moisture-barrier bag (MBB)
(see Figures 40 and 41, respectively).
Table 11.
Dry-Pack Requirements for MSL Level 1 and Level 2 Packages
Level
Dry Before Bag
MBB
Desiccant
MSID Label
Moisture-Sensitivity
Caution Label
1
Optional
Optional
Optional
Not Required
Not Required
2
Optional
Required
Required
Required
Required
Figure 41. Humidity Indicator Card
40
Quad Flatpack No-Lead Logic Packages
SCBA017D
Labels will be placed on moisture-barrier bags as shown in Figure 42.
Figure 42. Label Placement on Tape-and-Reel Moisture-Barrier Bag
The required dry-pack labels are the moisture-sensitivity identification (MSID) label and the
moisture-sensitivity caution label as specified in J-STD-033.[8] The MSID label is affixed to the
lowest-level shipping container that contains the MBB. The caution label is affixed to the outside
surface of the MBB.
The calculated shelf life for dry-packed components is a minimum of 12 months from the MBB
seal date, when stored in a noncondensing atmospheric environment of <40°C and 90% relative
humidity (see Table 12).
Table 12.
Floor Life Under Conditions Other Than 30°C and 60% Relative Humidity
Level
Floor Life (out of bag) at Factory Ambient Environment
of 30°C and 60% Relative Humidity, or as Stated
1
Unlimited at 30°C and 85% Relative Humidity
2
1 year
2a
4 weeks
3
168 hours
4
72 hours
5
48 hours
5a
24 hours
6
Mandatory baking before use
After baking, must be reflowed within the time limit specified on the label
Quad Flatpack No-Lead Logic Packages
41
SCBA017D
4.3.1 Symbols and Labels
The symbol shown in Figure 43 indicates that devices are moisture sensitive at level 2, or lower,
and must appear on all moisture-sensitivity caution labels.
Figure 43. Moisture-Sensitivity Symbol
The label shown in Figure 44 is affixed to the lowest-level shipping container to indicate that
moisture-sensitive devices are in the container. It is recommended that this label be a minimum
of 20 mm in diameter.
Figure 44. MSID Label
42
Quad Flatpack No-Lead Logic Packages
SCBA017D
The moisture-sensitivity caution label (see Figure 45), is used for levels 2, 2a, 3, 4, 5, and 5a as
defined by J-STD-020. This label is required on the MBB and provides the information as shown
in Figure 45.
Figure 45. Moisture-Sensitivity Caution Label for Levels 2–5a
Quad Flatpack No-Lead Logic Packages
43
SCBA017D
5
Symbolization
The top of the package is laser marked with device name, corporate ID, date code,
assembly-site code, assembly-lot trace code, and pin-1 location. Table 13 shows the
device-marking symbolization guidelines for 14-pin, 16-pin, and 20-pin QFN packages.
Table 13.
Device-Marking Guidelines
QFN Symbolization Guidelines
Maximum
Pins
Package
Namerule
and Format
Characters per Row
Maximum
Rows
Symbol Format
14
QFN
C2
6
3
AB245B
16
QFN
C2
6
3
20
QFN
C2
7
3
TI YMS
LLLL
O
The symbol-format column entry in Table 13 has the following meaning:
AB245B
TI
Y
M
S
LLLL
O
= Short name for SN74ABT245BRGYR
= Texas Instruments
= Year
= Month
= Site code
= Lot trace code
= Pin-1 quadrant identifier (data sheet specifies exact pin-1 location)
For specific marking on any device, please see the device data sheet at www.ti.com.
6
Test Sockets
Test sockets for the 14-, 16-, and 20-pin QFN devices can be obtained from:
Plastronics
2601 Texas Drive
Irving, Texas 75062
Phone: 972-258-2580
Fax: 972-258-6771
Socket part numbers:
20 Pin: 20QN50T14535
16 Pin: 16QN50T23030
14 Pin: 14QN50T23535
44
Quad Flatpack No-Lead Logic Packages
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7
Features and Benefits
In summary, key features and corresponding advantages for logic products in the QFN package
are:
8
•
Superior package parasitics, compared to traditional dual in-line package solutions.
Inductance ranges from 50% to 79% lower than alternative packages, and capacitance
ranges from 12% to 50% over SSOP and SOIC packages.
•
Superior thermal performance and board-level reliability, compared to alternative
package solutions. QFN junction-to-ambient thermal impedance ranges from 67% to
75% lower than TVSOP, 64% to 73% lower than TSSOP, 57% to 67% less than SSOP,
and 48% to 63% lower than SOIC. Mechanical integrity of the mounted package is
greatly enhanced by the soldered exposed die pad.
•
Conventional one-to-one pinout, resembling dual-in-line packages. Keeps ground, VCC,
and signal pin numbers consistent with previous dual-in-line packages.
•
Pb-free packages with backward-compatible solderability that can be soldered with
either SnPb or Pb-free pastes.
•
Significant area savings over traditional dual-in-line packages. QFN packages are 56%
to 62% smaller than equivalent-pin TSSOP counterparts.
•
Provides flow-through layout like conventional dual-in-line packages.
Conclusion
Texas Instruments 14-, 16-, and 20-pin QFN package offerings are leadframe-based leadless
packages, with improved thermal performance, electrical performance, and reduced package
volume over similar TSSOP, TVSOP, SSOP, and SOIC packages. Additionally, the QFN
packages meet the industry’s lead-free demands, have reliable solderability using either Pb or
Pb-free solder pastes, and can be reworked and manufactured using conventional equipment.
The packages allow for product miniaturization and comply with dimensional specifications of
JEDEC standard MO-241.
9
Acknowledgments
The authors thank Ray Purdom for helping with package development, Muhammad Khan for
providing electrical models, Bernhard Lange for board-assembly analysis, Cookson Electronics
for stencil design, Senju Solder for solder information, Ron Eller and Terrill Sallee for QA
support, and Dr. Sreenivasan Koduri for his guidance.
Quad Flatpack No-Lead Logic Packages
45
SCBA017D
10
References
References 1 through 4 are available at:
http://www.jedec.org/download/default.cfm
1. JEDEC Standard MO-241, Dual In-line Compatible, Thermally Enhanced, Plastic Very
Thin Fine Pitch, QFN Packages.
2. JESD 51-5, Extension of Thermal Test Board Standards for Packages with Direct
Thermal Attachment Mechanisms.
3. JESD 51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount
Packages.
4. JESD 51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount
Packages.
5. EIA-481 B, Taping of Surface Mount Components for Automatic Placement.
6. EIA-541, Packing Material Standards for ESD Sensitive Items.
7. J-STD-202, Moisture/Reflow Classification for Non-Hermetic Solid State Surface Mount
Devices.
8. J-STD-033, Standard for Handling and Shipping of Moisture/Reflow Sensitive Surface
Mount Devices.
9. IPC-7525, Stencil Design Guidelines, May 2000.
46
Quad Flatpack No-Lead Logic Packages
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