FS781/82/84
Low EMI Spectrum Spread Clock
Features
Functional Description
The Cypress FS781/82/84 are Spread Spectrum clock
generator ICs (SSCG) designed for the purpose of reducing
electromagnetic interference (EMI) found in today’s
high-speed digital systems.
• Spread Spectrum clock generator (SSCG) with 1×, 2×,
and 4× outputs
• 6- to 82-MHz operating frequency range
• Modulates external clocks including crystals, crystal
oscillators, or ceramic resonators
The FS781/82/84 SSCG clocks use a Cypress-proprietary
technology to modulate the input clock frequency, XIN, by
modulating the frequency of the digital clock. By modulating
the reference clock the measured EMI at the fundamental and
harmonic frequencies of FSOUT is greatly reduced. This
reduction in radiated energy can significantly reduce the cost
of complying with regulatory requirements without degrading
digital waveforms.
• Programmable modulation with simple R-C external
loop filter (LF)
• Center spread modulation
• 3V-5V power supply
• TTL-/CMOS-compatible outputs
• Low short-term jitter
The Cypress FS781/82/84 clocks are very simple and
versatile devices to use. By programming the two range select
lines, S0 and S1, any frequency from 6- to 82-MHz operating
range can be selected. The FS781/2/4 are designed to
operate over a very wide range of input frequencies and
provides 1×, 2×, and 4× modulated clock outputs.
• Low-power Dissipation
— 3.3 VDC = 37 mW – typical
— 5.0 VDC = 115 mW – typical
• Available in 8-pin SOIC and TSSOP packages
The FS78x devices have a simple frequency selection table
that allows operation from 6 MHz to 82 MHz in four separate
ranges. The bandwidth of the frequency spread at FSOUT is
determined by the values of the loop filter components. The
modulation rate is determined internally by the input frequency
and the selected input frequency range.
Applications
• Desktop/notebook computers
• Printers, copiers, and MFP
• Scanners and fax
The Bandwidth of these products can be programmed from as
little as 1.0% up to as much as 4.0% by selecting the proper
loop filter value. Refer to the Loop Filter Selection chart in
Table 2 and Table 3 for the recommended values. Due to a
wide range of application requirements, an external loop filter
(LF) is used on the FS78x products. The user can select the
exact amount of frequency modulation suitable for the appli-
cation. Using a fixed internal loop filter would severely limit
the use of a wide range of modulation bandwidths (Spread %)
to a few discrete values. Refer to FS791/2/4 products for appli-
cations requiring 80- to 140-MHz frequency range.
• LCD displays and monitors
• CD-ROM, VCD, and DVD
• Automotive and embedded systems
• Networking, LAN/WAN
• Digital cameras and camcorders
• Modems
Benefits
• Programmable EMI reduction
• Fast time to market
• Lower cost of compliance
• No degradation in rise/fall times
• Lower component and PCB layer count
Cypress Semiconductor Corporation
Document #: 38-07029 Rev. *F
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised January 2, 2005
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FS781/82/84
[1, 2, 3, 4]
Table 2. FS781/82/84 Recommended Loop Filter Values C7 (pF) @ +3.3 VDC ±5% (R6 = 3.3K)
[3]
[3]
[3]
[3]
[3]
[3]
[3]
Input MHz S1 S0 BW = 1.0%
BW = 1.5% BW = 2.0% BW = 2.5% BW = 3.0% BW = 3.5% BW = 4.0%
6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
10,000/1000
10,000/330
1040
830
1550
990
680
420
230
980
750
730
640
400
300
230
180
170
860
820
690
600
620
680
580
440
360
325
270
250
210
185
220
860
850
760
750
740
780
770
720
670
620
540
910
820
460
300
200
760
580
470
410
250
220
180
140
120
640
620
520
420
380
400
270
260
250
220
200
185
165
150
150
560
540
560
500
470
470
470
440
270
260
250
780
640
360
220
160
580
470
390
270
210
180
150
120
100
520
470
410
340
275
250
220
210
190
185
170
150
130
120
120
410
400
350
320
370
300
280
240
210
210
210
700
520
300
200
140
470
415
320
230
180
150
130
100
82
640
450
240
190
100
410
370
220
200
160
140
100
80
560
400
210
170
80
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
62
64
65
66
68
70
72
74
76
78
80
82
580
10000
1200
1000
960
385
300
190
180
150
120
70
920
660
470
470
60
330
68
47
10000
2200
1500
960
430
400
340
280
230
210
190
180
170
155
140
120
100
100
100
340
330
260
260
300
250
230
210
190
190
190
380
330
290
220
210
190
180
160
150
135
130
85
330
290
240
160
180
170
165
140
140
120
100
47
940
950
900
790
660
470
470
445
430
65
33
295
90
82
270
82
68
1180
1180
1180
1180
1120
1160
1110
1000
910
290
280
220
230
240
220
210
190
170
170
170
230
220
210
210
170
190
190
170
160
156
150
900
900
Notes:
1. If the value selected from the above chart is not a standard, use the next available larger value.
2. All bandwidths indicated above are total peak-to-peak spread. 1% = +0.5% to –0.5%. 4% = +2.0% to –2.0%.
3. If C8 is not listed in the chart for a particular bandwidth and frequency, it is not used in the loop filter.
4. Contact Cypress for LF values less than 1.0% bandwidth.
Document #: 38-07029 Rev. *F
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FS781/82/84
[1, 2, 3, 4]
Table 3. FS781/82/84 Recommended Loop Filter Values C7 (pF) @ +5.0 VDC ±5% (R6 = 3.3K)
[3]
[3]
[3]
[3]
[3]
[3]
[3]
Input MHz S1 S0 BW = 1.0%
BW = 1.5% BW = 2.0% BW = 2.5% BW = 3.0% BW = 3.5% BW = 4.0%
6
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1140
1170
1030
760
1030
970
660
340
240
970
870
680
560
360
270
230
200
1000
990
970
880
800
680
560
420
280
330
340
280
210
220
240
800
720
630
690
650
575
500
550
600
570
540
930
740
430
230
180
730
650
480
330
250
210
180
150
740
710
670
560
460
360
260
280
200
200
205
180
160
250
120
580
490
400
365
330
340
355
330
290
240
250
830
570
350
200
140
590
510
370
260
200
170
150
110
570
520
480
380
290
260
220
210
190
180
170
140
120
110
90
710
460
280
180
100
480
430
280
230
180
150
110
100
470
420
380
310
240
220
200
180
170
160
140
110
100
90
610
400
210
160
70
510
280
130
130
50
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
62
64
66
68
70
72
74
76
78
80
82
450
2490
2490
1360
990
430
370
190
200
160
110
100
90
370
310
250
190
150
90
820
530
430
90
250
80
Note 4
Note 4
Note 4
Note 4
Note 4
1030
790
410
360
310
270
230
200
190
170
140
130
120
110
90
370
300
230
220
220
190
170
140
120
110
90
1110
1110
830
560
510
90
470
90
450
80
80
430
80
80
70
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
Note 4
430
375
320
285
250
250
245
230
220
210
200
330
285
240
225
210
210
205
200
190
185
180
250
200
150
170
190
190
180
175
170
165
160
180
140
100
140
180
170
165
160
155
150
140
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FS781/82/84
Table 4. Modulation Rate Divider Ratios
S1
0
S0
0
Input Frequency Range (MHz)
Modulation Divider Number
6 to 16
16 to 32
32 to 66
66 to 82
120
240
480
720
0
1
1
0
1
1
quently, higher energy peaks. Regulatory agencies test
electronic equipment by the amount of peak energy radiated
from the equipment. By reducing the peak energy at the funda-
mental and harmonic frequencies, the equipment under test is
able to satisfy agency requirements for EMI. Conventional
methods of reducing EMI have been to use shielding, filtering,
multi-layer PCBs, etc. These FS781/2 and 4 reduce the peak
energy in the clock by increasing the clock bandwidth and
lowering the Q of the clock.
SSCG Modulation Profile
The digital control inputs S0 and S1 determine the modulation
frequency of FS781/2/4 products. The input frequency is
divided by a fixed number, depending on the operating range
that is selected. The modulation frequency of the FS78x can
be determined from Table 4. To compute the modulation
frequency, determine the values of S0 and S1, and find the
modulation divider number in Table 4.
SSCG
Theory of Operation
The FS781/82/84 products use a unique method of modulating
the clock over a very narrow bandwidth and controlled rate of
change, both peak to peak and cycle to cycle. The FS78x
products take a narrow band digital reference clock in the
range of 6–82 MHz and produce a clock that sweeps between
a controlled start and stop frequency and precise rate of
change. To understand what happens to an SSCG clock,
consider that we have a 20-MHz clock with a 50% duty cycle.
From a 20-MHz clock we know the following:
The FS781/82/84 devices are phase-locked loop-(PLL)-type
clock generators using Direct Digital Synthesis (DDS). ‘By
precisely controlling the bandwidth of the output clock, the
FS781/2/4 products become a low-EMI clock generator. The
theory and detailed operation of these products will be
discussed in the following sections.
EMI
All clocks generate unwanted energy in their harmonics.
Conventional digital clocks are square waves with a duty cycle
that is very close to 50%. Because of the 50/50 duty cycle,
digital clocks generate most of their harmonic energy in the
odd harmonics (e.g., third, fifth, seventh). It is possible to
reduce the amount of energy contained in the fundamental
and harmonics by increasing the bandwidth of the funda-
mental clock frequency. Conventional digital clocks have a
very high Q factor, which means that all of the energy at that
frequency is concentrated in a very narrow bandwidth, conse-
Clock Frequency = Fc = 20 MHz.
Clock Period = Tc = 1/20 MHz = 50 ns.
Consider that this 20-MHz clock is applied to the X input of
IN
the FS78x as either an externally driven clock or the result of
a parallel resonant crystal connected to pins 1 and 2 of the
FS78x. Also consider that the products are operating from a
5V DC power supply and the loop filter is set for a total
bandwidth spread of 2%. Refer to Figure 2.
+ .5%
1.0%Xin
Total
- .5%
TIME (microseconds)
[5]
Figure 1. Frequency Profile in Time Domain
Note:
5. With the correct loop filter connected to Pin 4, the following profile will provide the best EMI reduction. This profile can be seen on a Time Domain Analyzer.
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FS781/82/84
50%
50%
Tc = 50 ns.
Figure 2. 20-MHz Unmodulated Clock
From the above parameters, the output clock at FSOUT will be
sweeping symmetrically around a center frequency of 20 MHz.
Tc =49.50 ns.
Tc = 50.50 n
The minimum and maximum extremes of this clock will be
+200 kHz and –200 kHz. So we have a clock that is sweeping
from 19.8 MHz to 20.2 MHz and back again. If we were to look
at this clock on a spectrum analyzer we would see the picture
in Figure 3. Keep in mind that this is a drawing of a perfect
clock with no noise.
Figure 4. Period Comparison Chart
Looking at Figure 3, you will note that the peak amplitude of
the 20-MHz non-modulated clock is higher than the wideband
modulated clock. This difference in peak amplitudes between
modulated and unmodulated clocks is the reason why SSCG
clocks are so effective in digital systems. This figure refers to
the fundamental frequency of a clock. A very important charac-
teristic of the SSCG clock is that the bandwidth of the funda-
mental frequency is multiplied by the harmonic number. In
other words, if the bandwidth of a 20-MHz clock is 200 kHz,
the bandwidth of the third harmonic will be 3 × 200, or 600 kHz.
The amount of bandwidth is relative to the amount of energy
in the clock. Consequently, the wider the bandwidth, the
greater the energy reduction of the clock.
Fc = 20 MHz
Fmin =
Fmax =
19.8 MHz
20.2 MHz
Most applications will not have a problem meeting agency
specifications at the fundamental frequency. It is the higher
harmonics that usually cause the most problems. With an
SSCG clock, the bandwidth and peak energy reduction
increases with the harmonic number. Consider that the
eleventh harmonic of a 20-MHz clock is 220 MHz. With a total
spread of 200 kHz at 20 MHz, the spread at the eleventh
harmonic would be 2.20 MHz, which greatly reduces the peak
energy content. It is typical to see as much as 12- to 18-dB
reduction at the higher harmonics, due to a modulated clock.
Figure 3. Spectrum Analysis of 19.8–20.2 MHz Clock
We see that the original 20-MHz reference clock is at the
center frequency (Cf), and the min. and max. extremes are
positioned symmetrically about the center frequency. This type
of modulation is called Center-Spread. Figure 4 shows a
20-MHz clock as it would be seen on an oscilloscope. The top
trace is the non-modulated reference clock. The bottom trace
is the modulated clock at pin 6. From this comparison chart
you can see that the frequency is decreasing and the period
of each successive clock is increasing. The Tc measurements
on the left and right of the bottom trace indicate the max. and
min. extremes of the clock. Intermediate clock changes are
small and accumulate to achieve the total period deviation.
The reverse of this figure would show the clock going from
minimum extreme back to the high extreme.
The difference in the peak energy of the modulated clock and
the non-modulated clock in typical applications will see a
2 – 3 dB reduction at the fundamental and as much as 8 – 10
dB reduction at the intermediate harmonics: third, fifth,
seventh, etc. At the higher harmonics, it is quite possible to
reduce the peak harmonic energy, compared to the unmodu-
lated clock, by as much as 12 to 18 dB.
Application Notes and Schematic
Figure 5 is configured for the following parameters:
Package selected = FS781.
X
= 20-MHz crystal
IN
FSOUT = 20 MHz (S0 = 1 and S1 = 0).
Bandwidth of the FSOUT clock is determined by the values of
the loop filter connected to pin 4.
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FS781/82/84
Crystal is 20 MHz is 1st Order
with 18 pF load capacitance.
C2
1
8
7
VDD
Xin
VDD
S0
C1
20 MHz
Y1
If Crystal load capacitance is
different than 18 pF, C1 and C2
must be re-calculated.
0.1 uF
27 pF
C3
2
Xout
For third overtone crystals, a
parallel or series resonant trap
is required.
FS781
(SOIC)
27 pF
3
4
6
5
FSOUT
S1
LF
FSOUT
VSS
Mount loop filter components as
close to LF pin as possible.
R6
C7
C8
**
** Occasionally, C8 is used to
create a second pole for this loop
filter. Refer to Loop Filter Selection
table.
.
Figure 5. FS781 Schematic
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FS781/82/84
Absolute Maximum Ratings[6]
This device contains circuitry to protect the input against
damage due to high static voltages or electric fields; however,
precautions should be taken to avoid application of any
voltage higher than the absolute maximum rated voltages to
this circuit. For proper operation, V and V
should be
IN
OUT
constrained to the range, V < (V or V
) < V . All digital
SS
IN
OUT
DD
inputs are tied high or low internally. Refers to electrical speci-
fications for operating supply range.
Table 5. Absolute Maximum Ratings
Parameter
Description
Min.
3.0
–0.3
–0.3
0
Max.
Unit
VDC
VDC
VDC
°C
V
Operating Voltage
Input, relative to V
6.0
DD
VIRvss
VORvss
TOP
V
V
+ 0.3
SS
DD
DD
Output, relative to V
+ 0.3
SS
Temperature, Operating
Temperature, Storage
Temperature, Junction
+70
TST
–65
–
+150
+125
°C
T
°C
J
Table 6. DC Electrical Characteristics V = 3.3V and 5.0V ±10%, X = 48 MHz, T = 0°C to 70°C
DD
IN
A
Parameter
Description
Min.
Typ.
Max.
Unit
V
V
I
Input Low Voltage
Input High Voltage
Input Low Current
Input High Current
–
0.3 * V
VDC
VDC
µA
IL
DD
0.7 * V
IH
DD
100
100
0.4
IL
I
µA
IH
V
V
V
V
Output Low Voltage I = 10 mA, V = 5V
VDC
VDC
VDC
VDC
Ω
OL
OH
OL
OH
OL
DD
Output High Voltage I = 10 mA, V = 5V
V
– 1.0
OH
DD
DD
Output Low Voltage I = 6 mA, V = 3.3V
0.4
OL
DD
Output High Voltage I = 5 mA, V = 3.3V
2.4
OH
DD
Rpd
Rpu
Resistor, Pull-down (Pin 7)
60K
60K
125K
125K
8
200K
200K
Resistor, Pull-up (Pin 3)
Input Capacitance (Pin 1)
Output Capacitance (Pin 2)
Ω
C
C
pF
xin
10
38
20
25
0
pF
xout
I
I
5V Dynamic Supply Current (CL = No Load)
3.3V Dynamic Supply Current (CL = No Load)
Short Circuit Current (FSOUT)
mA
mA
mA
%
CC
CC
ISC
BW
BW
[7]
BW% Variations, 3.30V
–20
–30
+20
+30
[7]
BW% Variations, 5.00V
0
%
Table 7. Timing Electrical Characteristics V = 3.3V and 5.0V ±10%, T = 0°C to 70°C, C = 15 pF, X = 48 MHz
DD
A
L
IN
Parameter
tTLH
Description
Min.
1.8
1.5
0.5
0.5
2.1
1.7
0.7
0.6
45
Typ.
Max.
Unit
ns
ns
ns
ns
ns
ns
ns
ns
%
Output Rise Time Measured at 10%–90% @ 5 VDC
Output Fall Time Measured at 10%–90% @ 5 VDC
Output Rise Time Measured at 0.8V–2.0V @ 5 VDC
Output Fall Time Measured at 0.8V–2.0 V @ 5 VDC
Output Rise Time Measured at 10%–90% @ 3.3 VDC
Output Fall Time Measured at 10%–90% @ 3.3 VDC
Output Rise Time Measured at 0.8V–2.0V @ 3.3 VDC
Output Fall Time Measured at 0.8V–2.0 V @ 3.3 VDC
Output Duty Cycle
2.2
2.0
2.7
2.5
0.8
0.8
3.2
2.6
1.2
1.1
55
tTHL
tTLH
0.65
0.65
2.65
2.1
tTHL
tTLH
tTHL
tTLH
0.95
0.85
50
tTHL
TsymF1
Notes:
6. Single Power Supply: The Voltage on any input or /O pin cannot exceed the power pin during power-up.
7. Percentage variations from the bandwidth % values given in Table 2 and Table 3.
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FS781/82/84
Table 7. Timing Electrical Characteristics V = 3.3V and 5.0V ±10%, T = 0°C to 70°C, C = 15 pF, X = 48 MHz (continued)
DD
A
L
IN
Parameter
CCJ
Description
Min.
Typ.
320
310
270
390
Max.
370
360
325
440
Unit
ps
FSOUT, Cycle-to-Cycle Jitter, 48 MHz @ 3.30 VDC (Pin 6)
FSOUT, Cycle-to-Cycle Jitter, 48 MHz @ 5.0 VDC (Pin 6)
FSOUT, Cycle-to-Cycle Jitter, 72 MHz @ 3.30 VDC (Pin 6)
FSOUT, Cycle-to-Cycle Jitter, 72 MHz @ 5.0 VDC (Pin 6)
–
–
–
–
CCJ
ps
CCJ
ps
CCJ
ps
Table 8. Range Selection Table
S1
S0
Fin (MHz)
(pin 2/3)
Modulation
Rate
FS781
FS782
FS784
(pin 3)
(pin 7)
FSOUT (pin 6)
FSOUT (pin 6)
12–32 MHz
32–64 MHz
64–82 MHz
N/A
FSOUT (pin 6)
32–64 MHz
64–82 MHz
N/A
0
0
1
1
0
1
0
1
6–16
16–32
32–66
66–82
Fin/120
Fin/240
Fin/480
Fin/720
6–16 MHz
16–32 MHz
32–66 MHz
66–82 MHz
N/A
Ordering Information[8]
Part Number
IMIFS781BZB
Package Type
Product Flow
8-pin 150-mil SOIC
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
IMIFS781BZBT
IMIFS782BZB
8-pin 150-mil SOIC – Tape and Reel
8-pin 150-mil SOIC
IMIFS782BZBT
IMIFS784BZB
8-pin 150-mil SOIC – Tape and Reel
8-pin 150-mil SOIC
IMIFS784BZBT
IMIFS781BT
8-pin 150-mil SOIC – Tape and Reel
8-pin (4.4 mm body) TSSOP
IMIFS781BTT
8-pin (4.4 mm body) TSSOP – Tape and Reel
8-pin (4.4 mm body) TSSOP
IMIFS784BT
IMIFS784BTT
8-pin (4.4 mm body) TSSOP – Tape and Reel
Lead-free
CYIFS781BSXC
CYIFS781BSXCT
CYIFS782BSXC
CYIFS782BSXCT
CYIFS784BSXC
CYIFS784BSXCT
CYIFS781BZXC
CYIFS781BZXCT
CYIFS782BZXC
CYIFS782BZXCT
CYIFS784BZXC
8-pin 150-mil SOIC
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
Commercial, 0 to 70°C
8-pin 150-mil SOIC – Tape and Reel
8-pin 150-mil SOIC
8-pin 150-mil SOIC – Tape and Reel
8-pin 150-mil SOIC
8-pin 150-mil SOIC – Tape and Reel
8-pin (4.4 mm body) TSSOP
8-pin (4.4 mm body) TSSOP – Tape and Reel
8-pin (4.4 mm body) TSSOP
8-pin (4.4 mm body) TSSOP – Tape and Reel
8-pin (4.4 mm body) TSSOP
CYIFS784BZXCT
8-pin (4.4 mm body) TSSOP – Tape and Reel
Note:
8. The ordering part number differs from the marking on the actual device.
Document #: 38-07029 Rev. *F
Page 9 of 12
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FS781/82/84
Marking Example
Cypress
FS781BS
Cypress
FS781BT
Date Code, Lot #
Date Code, Lot #
FS781 B S
Package
S = SOIC
T = TSSOP
Revision
Cypress Device Driver
Package Drawing and Dimensions
8-lead (150-Mil) SOIC S8
PIN 1 ID
4
1
1. DIMENSIONS IN INCHES[MM] MIN.
MAX.
2. PIN 1 ID IS OPTIONAL,
ROUND ON SINGLE LEADFRAME
RECTANGULAR ON MATRIX LEADFRAME
0.150[3.810]
0.157[3.987]
3. REFERENCE JEDEC MS-012
4. PACKAGE WEIGHT 0.07gms
0.230[5.842]
0.244[6.197]
PART #
S08.15 STANDARD PKG.
SZ08.15 LEAD FREE PKG.
5
8
0.189[4.800]
0.196[4.978]
0.010[0.254]
0.016[0.406]
X 45°
SEATING PLANE
0.061[1.549]
0.068[1.727]
0.004[0.102]
0.050[1.270]
BSC
0.0075[0.190]
0.0098[0.249]
0.004[0.102]
0.0098[0.249]
0°~8°
0.016[0.406]
0.035[0.889]
51-85066-*C
0.0138[0.350]
0.0192[0.487]
Document #: 38-07029 Rev. *F
Page 10 of 12
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FS781/82/84
Package Drawing and Dimensions (continued)
8-Lead Thin Shrunk Small Outline Package (4.40 MM Body) Z8
PIN 1 ID
1
DIMENSIONS IN MM[INCHES] MIN.
MAX.
6.25[0.246]
6.50[0.256]
4.30[0.169]
4.50[0.177]
8
0.65[0.025]
BSC.
0.25[0.010]
BSC
0.19[0.007]
0.30[0.012]
1.10[0.043] MAX.
GAUGE
PLANE
0°-8°
0.076[0.003]
0.85[0.033]
0.95[0.037]
0.50[0.020]
0.70[0.027]
0.05[0.002]
0.15[0.006]
0.09[[0.003]
0.20[0.008]
SEATING
PLANE
2.90[0.114]
3.10[0.122]
51-85093-*A
All product and company names mentioned in this document may be the trademarks of their respective holders.
Document #: 38-07029 Rev. *F
Page 11 of 12
© Cypress Semiconductor Corporation, 2005. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use
of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be
used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its
products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress
products in life-support systems application implDiesotwhantlothaedmfarnoumfacWturwerwa.sSsuommeasnaullarilssk.cofosmuc.hAulsleMaannduinadlsoinSgesaoricnhdeAmnndifieDsoCwypnrelosasda.gainst all charges.
FS781/82/84
Document History Page
Document Title: FS781/82/84 Low EMI Spectrum Spread Clock
Document Number: 38-07029
Orig. of
REV.
**
ECN NO. Issue Date Change
Description of Change
Convert from IMI to Cypress
106948
111654
118355
122679
277189
314274
417662
06/07/01
02/27/02
08/30/02
12/14/02
See ECN
See ECN
See ECN
IKA
IKL
*A
Add new marking suffix for SOIC packages. Converted to FrameMaker.
Swap the location of S0 and S1 in tables 2 and 3 in pages 2,3 and 4.
Add power up requirements to operating conditions information.
Added Lead-free Devices
*B
RGL
RBI
*C
*D
*E
RGL
RGL
RGL
Fixed the Ordering Information to match the DevMaster
Added Maximum Junction Temperature in Absolute Maximum Ratings table
*F
Document #: 38-07029 Rev. *F
Page 12 of 12
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