MAS MAS6283

DA6283.002
11 November, 2010
MAS6283
IC FOR 1.5625 MHz – 40.0000 MHz VCXO
Low Power
Wide Supply Range
CMOS (Square Wave) Output
Very Low Phase Noise
Low Cost
Divider Function
Tri State output
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DESCRIPTION
MAS6283 is an integrated circuit well suited to
build a VCXO for telecommunication and other
applications. To build a VCXO only one additional
component, a crystal, is needed.
FEATURES
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•
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APPLICATIONS
Very small size
Low current consumption
Wide operating temperature range
Phase noise < -130 dBc/Hz at 1 kHz offset
CMOS (Square wave) output
VCXO modules
VCXO for telecommunications systems
VCXO for set-top boxes
VCXO for MPEG decoder
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BLOCK DIAGRAM
PD
VC
1/2
1/2
1/2
1/2
OUT
VDD
MAS6283
1 nF
VSS
XIN
XOUT
Figure 1. Block diagram of MAS6283.
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ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
Supply Voltage
Input Pin Voltage
Power Dissipation (max)
Storage Temperature
Latchup Current Limit
VDD - VSS
Conditions
PMAX
TST
ILUT
Min
Max
Unit
Note
-0.3
VSS -0.3
6.0
VDD + 0.3
100
150
V
V
mW
o
C
mA
1)
-55
±100
Note: Stresses beyond the values listed may cause a permanent damage to the device. The device may not
operate under these conditions, but it will not be destroyed
Note: This is a CMOS device and therefore it should be handled carefully to avoid any damage by static
voltages (ESD).
Note 1: Not valid for pins XIN and XOUT.
RECOMMENDED OPERATION CONDITIONS
Parameter
Supply Voltage
Operating Temperature
Crystal RS
Symbol
VDD
TOP
RS
Conditions
Min
Typ
Max
2.5
-40
3.3
5.5
+85
60
30
Unit
Note
V
C
Ω
1)
o
2)
Note 1: It is recommended to connect a 1 nF SMD capacitor between the VDD and VSS pins. Assure that
rd
capacitor resonance frequency is high enough to filter 3 harmonic.
Note 2: See figure 5 for negative resistance at different frequencies.
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ELECTRICAL CHARACTERISTICS
Parameter
Symbol
Conditions
Min
Typ
Max
Unit
Note
Crystal Frequency Range
fc
25
40
MHz
1)
Output Frequency Range
fo
25
40
MHz
2)
Output Frequency Range
fo
1.5625
20
MHz
3)
Voltage Control Range
VC
0
VDD
V
Voltage Control impedance
ZVC
Supply Current
VDD = 3.3V, fc = 35 MHz
IDD
Supply Current
VDD = 5.0V, fc = 35 MHz
IDD
Supply Current XPD = 0 V
IXPD
1.2
No Load
CLOUT = 10 pF
CLOUT = 30 pF
CLOUT = 50 pF
No Load
CLOUT = 10 pF
CLOUT = 30 pF
CLOUT = 50 pF
VDD = 3.3 V
VDD = 5.0 V
Output Symmetry
Startup Time
Output Buffer
Enabled
Disabled
Crystal Load Capacitance
Pulling Range
0.0V < VC < 5.0V
45
TSTART
0.9
0.9
48-52
MΩ
2.0
9.3
23.8
38.3
3.0
14.0
36.0
58.0
1.5
1.7
55
2
mA
mA
mA
%
ms
XPD
1.6
0
CL
VDD
0.55
V
4)
VC = 1.65 V
8
pF
5)
Crystal S=
30 ppm/pF
285
ppm
6)
Note 1: Crystal frequency can be divided by 2, 4, 8 and 16.
Note 2: Direct output.
Note 3: Depending on chosen output divider.
Note 4: If the XPD pin is floating the output buffer is active. Oscillator is always running. At power down mode
the output is at high impedance.
Note 5: Crystal load capacitance is dependent on a VC voltage. See figure 4 for CL for other VC voltages.
Note 6: For calculating crystal pulling (S), see equation 1 on the page 5.
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PIN DESCRIPTION
Pin Description
Crystal Oscillator Output
Voltage Control Input
Power Supply Ground
Buffer Output
Power Supply Voltage
Output Buffer Power Down Control
Crystal/Varactor Oscillator Input
Symbol
x-coordinate
y-coordinate
XOUT
VC
VSS
OUT
VDD
XPD
XIN
214
885
1080
1106
579
339
153
141
142
141
699
698
698
698
Note: Because the substrate of the die is internally connected to VSS, the die has to be connected to VSS or left
floating. Please make sure that VSS is the first pad to be bonded. Pick-and-place and all component assembly
are recommended to be performed in ESD protected area.
Note: Pad coordinates are measured from the left bottom corner of the chip to the center of the pads. The
coordinates may vary depending on sawing width and location. However, the distances between pads are
accurate.
IC OUTLINES
XIN
XPD
VDD
OUT
840 um
XOUT
VC
MAS6283
VSS
Die Map Reference
1260 um
Figure 2. IC outline of MAS6283.
Note1: Die map reference is the actual left bottom corner of the sawn chip.
Note2: See coordinates in pin description.
Note3: Die dimensions include 80 µm scribes for both sides. The actual dimensions are a bit less due to the saw
width.
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EXTERNAL COMPONENT SELECTION
Quartz Crystal and VCXO Module Information
To ensure the best system performance, the crystal
parameters should be considered carefully. Pulling
is an important parameter which can be calculated
according to an equation 1. Layout guidelines in the
following section should be followed. The frequency
of the crystal is tuned by load capacitors. There are
integrated variable load capacitors on the MAS6283
and they are controlled by an external voltage at the
VC pin. It is recommended to connect a 1 nF
capacitor between VDD and VSS. The external
crystal should be located as close to the chip as
possible. In case of a PCB mounted module, it is
usually advisable to mount a crystal on the same
side with the VCXO IC to minimize stray
capacitance. Often vias between the crystal pins
and the XIN and XOUT pins of the VCXO IC
increase stray capacitance. There should be no
noisy signal traces underneath or close to the
crystal.
Equation 1
Crystal Pulling Sensitivity
S =−
C1
ppm
[values are given in the units described below]
2
2(C 0 + C L ) pF
10 6
Where,
CL = Load capacitance in series with the crystal
C0 = Shunt capacitance of the crystal
C1 = Motional capacitance of the crystal
Example 1
If we choose a crystal with the following values
CL = 8.0 pF,
C0 = 2.0 pF,
C1 = 6.7 fF
the equation 1 yields
S=
− 6.7 × 10 −15
(
2 2.0 × 10 −12 + 8.0 × 10
10 6
)
−12 2
= −33.5
ppm
pF
If a crystal load differs from 8 pF the oscillator will have frequency offset at VC = 1.65 V. Thus if you need to use
1.65 V VC voltage with a crystal which CL is other than 8 pF you have to design the crystal for a specific nominal
frequency. The following guidelines show how to define the crystal’s nominal frequency.
Separate crystal CL as CL_XTAL and MAS IC CL as CL_IC.
To define specific nominal frequency for the crystal first calculate load difference ∆CL [pF] as in an equation 2.
Equation 2
∆C L = C L _ IC − C L _ XTAL
Calculate frequency difference ∆f [ppm] as in an equation 3. Pulling S comes from the equation 1.
Equation 3
∆f = ∆C L × S
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The crystal nominal frequency fNOM_XTAL is calculated, as shown in an equation 4.
Equation 4
f NOM _ XTAL = f NOM
∆f 

× 1 + 6 
 10 
Where,
fNOM = Desired nominal frequency of the VCXO module
fNOM_XTAL = Crystal nominal frequency (without MAS IC load capacitance)
Crystal nominal frequency optimization is calculated in an example 2.
Example 2
VCXO module target frequency fNOM is 35 MHz. Crystal characteristics are crystal load CL_XTAL = 12.5 pF and
pulling S = 30 ppm/pF.
MAS6283 CL_IC = 8 pF when VC = 1.65 V.
Calculate load difference ∆CL according to the equation 2.
∆C L = C L _ IC − C L _ XTAL = 8 pF − 12.5 pF = −4.5 pF
Calculate frequency difference ∆f according to the equation 3.
∆f = ∆C L × S = −4.5 pF × 30
ppm
= −135 ppm
pF
Now fNOM = 35 MHz.
According to the equation 4
∆f 

 − 135 
f NOM _ XTAL = f NOM × 1 + 6  = 35 × 10 6 × 1 +
 = 34995275 Hz
10 6 
 10 

The specified crystal has to have a nominal frequency of 34.995275 MHz without load capacitance. This offset is
compensated with 8 pF load capacitance though a crystal CL = 12.5 pF.
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VOLTAGE CONTROL (VC)
MAS6283 VC Sensitivity
INL % / pulling
1.5
1
0.5
0
-0.5
0.0
0.5
1.0
1.5
2.0
2.5
3.0
-1
-1.5
-2
-2.5
-3
VC (V)
Figure 3. MAS6283AA VC sensitivity measured as INL % / pulling vs VC (V).
MAS6283 Voltage control sensitivity graph in figure 3 is measured by using 40.0 MHz crystal (CL = 8.5 pF, C1 =
4.9 fF, CL = 1.5 pF). For crystal pulling see equation 1 in a page 5.
MAS6283 CL (pF) vs VC (V)
CL (pF)
14
12
10
8
6
4
2
0
0
1
2
3
4
5
VC (V)
Figure 4. MAS6283 CL vs VC voltage
Figure 4 shows MAS6283 CL over the different VC voltages.
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Negative Resistance
Frequency [Hz]
1,000,000
10,000,000
100,000,000
0
Negative Resistance [ohm]
-500
-1000
-1500
VC 0.0V
VC 1.65V
VC 3.3V
VC 5.5V
-2000
-2500
-3000
Figure 5. MAS6283 negative resistance.
Figure 5 shows MAS6283 negative resistance vs frequency with different VC voltage values measured at a room
temperature. Negative resistance should be at least three times crystal RS to ensure a reliable oscillation.
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SAMPLES IN SB20 DIL PACKAGE
XIN 1
20
2
19
XOUT 3
18 XPD
4
17
MAS6283
YYWW
XXXXX.X
VC 5
6
15
7
14
8
13
VSS 9
12
10
Top marking:
YYWW = Year, Week
XXXXX.X = Lot number
16 VDD
11 OUT
Figure 8. MAS6283 SB20 DIL package.
DEVICE OUTLINE CONFIGURATION
pin 1
XOUT
6283
AX
VSS
YWW
VC
XIN
XPD
Top View
VDD
OUT
A = product version
X = MAS internal code
Y = year
WW= week
MSOP8
Figure 9. MAS6283 MSOP-8 package.
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PACKAGE (MSOP-8) OUTLINE
Gage plane
F
E1 E
Land
Pattern
Recommendation
P
R
A
Q
L
A
R1
N
e
c
D
G
A2
c1
M
b1
(b)
A
A1
Section A - A
b
Symbol
Min
A
A1
A2
b
b1
c
c1
D
E
E1
e
F
G
L
(Terminal length for
soldering)
M
N
P
Q
R
R1
0
0.75
0.22
0.22
0.08
0.08
0.40
Nom
0.85
0.30
3.00 BSC
4.90 BSC
3.00 BSC
0.65 BSC
4.8
0.65
0.60
Max
Unit
1.10
0.15
0.95
0.38
0.33
0.23
0.18
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
0.80
0.41
1.02
0°
mm
mm
8°
0.25 BSC
0.07
0.07
mm
mm
mm
Dimensions do not include mold or interlead flash, protrusions or gate burrs.
All measurement according to JEDEC standard MO-187.
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SOLDERING INFORMATION
◆ For Pb-Free
Maximum Temperature
Maximum Number of Reflow Cycles
Reflow profile
Seating Plane Co-planarity
Lead Finish
Moisture Sensitivity Level (MSL)
260°C
3
Thermal profile parameters stated in JESD22-A113 should not
be exceeded. http://www.jedec.org
max 0.08 mm
Solder plate 7.62 - 25.4 µm, material Matte Tin
1
EMBOSSED TAPE SPECIFICATIONS (MSOP-8)
P1
T
DO
PO
P2
E
W
F
BO
A
AO
KO
D1
Section A-A
User Direction of Feed
Pin 1 Designator
Dimension
Min/Max
Unit
Ao
Bo
Do
D1
E
F
Ko
Po
P1
P2
T
W
5.00 ±0.10
3.20 ±0.10
1.50 +0.1/-0.0
1.50 min
1.75
5.50 ±0.05
1.45 ±0.10
4.0
8.0
±0.10
2.0
±0.05
0.3
±0.05
12.00 +0.30/-0.10
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
mm
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DA6283.002
11 November, 2010
REEL SPECIFICATIONS (MSOP-8)
W2
A
D
C
Tape Slot for Tape Start
N
B
W1
5000 Components on Each Reel
Reel Material: Conductive, Plastic Antistatic or Static Dissipative
Carrier Tape Material: Conductive
Cover Tape Material: Static Dissipative
Carrier Tape
Cover Tape
End
Start
Trailer
Dimension
A
B
C
D
N
W 1 (measured at hub)
W 2 (measured at hub)
Trailer
Leader
Weight
Leader
Components
Min
1.5
12.80
20.2
50
12.4
Max
Unit
330
mm
mm
mm
mm
mm
mm
mm
mm
mm
13.50
14.4
18.4
160
390,
of which minimum 160
mm of empty carrier tape
sealed with cover tape
1500
g
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ORDERING INFORMATION
Product Code
Output
Frequency
Package
MAS6283AATG00
MAS6283AASN06
MAS6283ABTG00
MAS6283ACTG00
MAS6283AETG00
fc
fc
fc / 2
fc / 4
fc / 16
EWS tested wafers 215 µm
MSOP-8, T&R 5000 pcs / r, Pb free RoHS
EWS tested wafers 215 µm
EWS tested wafers 215 µm
EWS tested wafers 215 µm
Contact Micro Analog Systems Oy for divider options.
Contact Micro Analog Systems Oy for other wafer thickness.
◆ The formation of product code
Product name
MAS6283
Design
version
A
Output
frequency
A = fc
B = fc / 2
C = fc / 4
E = fc / 16
Package type
Delivery format
TG = 215 µm thick EWS tested wafer
SN = MSOP Pb free RoHS
00 = tested wafer
06 = tape & reel
LOCAL DISTRIBUTOR
MICRO ANALOG SYSTEMS OY CONTACTS
Micro Analog Systems Oy
Kutomotie 16
FI-00380 Helsinki, FINLAND
Tel. +358 10 835 1100
Fax +358 10 835 1119
http://www.mas-oy.com
NOTICE
Micro Analog Systems Oy reserves the right to make changes to the products contained in this data sheet in order to improve the design or
performance and to supply the best possible products. Micro Analog Systems Oy assumes no responsibility for the use of any circuits
shown in this data sheet, conveys no license under any patent or other rights unless otherwise specified in this data sheet, and makes no
claim that the circuits are free from patent infringement. Applications for any devices shown in this data sheet are for illustration only and
Micro Analog Systems Oy makes no claim or warranty that such applications will be suitable for the use specified without further testing or
modification.
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