CYPRESS CY22395

CY22393, CY223931, CY22394, CY22395
Three-PLL Serial-Programmable
Flash-Programmable Clock Generator
Features
Benefits
■
Three integrated phase-locked loops (PLLs)
■
■
Ultra wide divide counters (8-bit Q, 11-bit P, and 7-bit post
divide)
Generates up to three unique frequencies on up to six
outputs from an external source.
■
Allows for 0 ppm frequency generation and frequency
conversion in the most demanding applications.
■
Improves frequency accuracy over temperature, age,
process, and initial ppm offset.
■
Nonvolatile programming enables easy customization,
ultra-fast turnaround, performance tweaking, design timing
margin testing, inventory control, lower part count, and more
secure product supply. In addition, any part in the family can
be programmed multiple times, which reduces programming
errors and provides an easy upgrade path for existing
designs.
■
In-house programming of samples and prototype quantities
is available using the CY3672 FTG Development Kit.
Production quantities are available through Cypress
Semiconductor’s value-added distribution partners or by
using third-party programmers from BP Microsystems, HiLo
Systems, and others.
■
Performance suitable for high-end multimedia, communications, industrial, A/D converters, and consumer applications.
■
Supports numerous low power application schemes and
reduces electromagnetic interference (EMI) by allowing
unused outputs to be turned off.
■
Adjust crystal drive strength for compatibility with virtually all
crystals.
■
3-bit external frequency select options for PLL1, CLKA, and
CLKB.
■
Industry standard packaging saves on board space.
■
Easy to use software support for design entry.
■
2-wire serial interface allows in-system programming into
volatile configuration memory. All frequency settings can be
changed, providing literally millions of frequency options.
■
Adjust output buffer strength to lower EMI or improve timing
margin.
■
Fine tune crystal oscillator frequency by changing load
capacitance.
■
Differential output up to 400 MHz.
■
Provides interfacing option for low voltage parts.
■
Improved linear crystal load capacitors
■
Flash programmability with external programmer
■
Field-programmable
■
Low jitter, high accuracy outputs
■
Power management options (Shutdown, OE, Suspend)
■
Configurable crystal drive strength
■
Frequency select through three external LVTTL inputs
■
3.3V operation
■
16-pin TSSOP package
■
CyClocksRT™ software support
Advanced Features
■
2-wire serial interface for in-system configurability
■
Configurable output buffer
■
Digital VCXO
■
High frequency LVPECL output (CY22394 only)
■
3.3/2.5V outputs (CY22395 only)
■
NiPdAu lead finish (CY223931)
Cypress Semiconductor Corporation
Document #: 38-07186 Rev. *E
•
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised January 9, 2009
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Selector Guide
Part Number
Outputs
Input Frequency Range
Output Frequency Range
Specifics
CY22393_C
6 CMOS
8 MHz–30 MHz (external crystal) Up to 200 MHz
1 MHz–166 MHz (reference clock)
Commercial Temperature
CY22393_I
6 CMOS
8 MHz–30 MHz (external crystal) Up to 166 MHz
1 MHz–166 MHz (reference clock)
Industrial Temperature
CY223931_I
6 CMOS
8 MHz–30 MHz (external crystal) Up to 166 MHz
1 MHz–166 MHz (reference clock)
Industrial Temperature
CY22394_C
1 PECL/
4 CMOS
8 MHz–30 MHz (external crystal) 100 MHz–400 MHz (PECL)
1 MHz–166 MHz (reference clock) Up to 200 MHz (CMOS)
Commercial Temperature
CY22394_I
1 PECL/
4 CMOS
8 MHz–30 MHz (external crystal) 125 MHz–375 MHz (PECL)
1 MHz–150 MHz (reference clock) Up to 166 MHz (CMOS)
Industrial Temperature
CY22395_C
4 LVCMOS/ 8 MHz–30 MHz (external crystal) Up to 200 MHz (3.3V)
1 CMOS
1 MHz–166 MHz (reference clock) Up to 133 MHz (2.5V)
Commercial Temperature
CY22395_I
4 LVCMOS/ 8 MHz–30 MHz (external crystal) Up to 166 MHz (3.3V)
1 CMOS
1 MHz–150 MHz (reference clock) Up to 133 MHz (2.5V)
Industrial Temperature
Logic Block Diagram - CY22393 and CY223931
XTALIN
XBUF
OSC.
XTALOUT
CONFIGURATION
FLASH
PLL1
11-Bit P
8-Bit Q
Divider
/2, /3, or /4
CLKE
Divider
7-Bit
CLKD
Divider
7-Bit
CLKC
Divider
7-Bit
CLKB
Divider
7-Bit
CLKA
SHUTDOWN/OE
SCLK
SDAT
PLL2
11-Bit P
8-Bit Q
S2/SUSPEND
PLL3
4x4
Crosspoint
Switch
11-Bit P
8-Bit Q
Document #: 38-07186 Rev. *E
Page 2 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Logic Block Diagram - CY22394
XTALIN
XBUF
OSC.
XTALOUT
CONFIGURATION
FLASH
PLL1
11-Bit P
8-Bit Q
0º
PECL
OUTPUT
180º
P+CLK
P-CLK
SHUTDOWN/OE
SCLK
PLL2
SDAT
11-Bit P
8-Bit Q
S2/SUSPEND
4x4
Crosspoint
Switch
PLL3
Divider
7-Bit
CLKC
Divider
7-Bit
CLKB
Divider
7-Bit
CLKA
11-Bit P
8-Bit Q
Logic Block Diagram - CY22395
XTALIN
XTALOUT
OSC.
CONFIGURATION
FLASH
Divider
/2, /3, or /4
LCLKE
PLL1
11-Bit P
8-Bit Q
SHUTDOWN/OE
Divider
7-Bit
LCLKD
Divider
7-Bit
CLKC
Divider
7-Bit
LCLKB
Divider
7-Bit
LCLKA
SCLK
4x4
Crosspoint
Switch
SDAT
S2/SUSPEND
PLL2
11-Bit P
8-Bit Q
PLL3
11-Bit P
8-Bit Q
LCLKA, LCLKB, LCLKD, LCLKE referenced to LVDD
Document #: 38-07186 Rev. *E
Page 3 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Pinouts
Figure 1. Pin diagram - 16-Pin TSSOP CY22393/CY223931/CY22394/CY22394
CY22393
CY223931
CY22393
CL KC
1
VDD
2
3
SH UTDOWN /OE
16
15
14
S2 /SU SPEND
5
13
12
SC LK (S1)
SD AT (S0)
XBUF
6
11
GND
CLKD
7
10
C LKE
8
9
C LKA
C LKB
AGND
XTALIN
XTALOUT
4
CY22395
CY22394
AVDD
CLKC
1
VDD
2
AGN D
3
4
16
15
14
13
5
12
6
11
SCL K (S1)
SDAT (S0)
GND
7
8
10
9
XTAL IN
XTALOUT
XBU F
P–C LK
P+ C LK
SHU TD OWN /OE
S2 /SUSPEN D
AVD D
C LKC
1
VDD
AGND
2
3
SHUTDOWN/OE
16
15
14
AV DD
5
13
12
SCLK (S1)
SDAT (S0 )
S2/SUSPEND
XTALIN
XTALOUT
LVDD
4
6
11
GN D/LGND
CL KA
LCL KD
7
10
CL KB
LCL KE
8
9
LCL KA
LCL KB
Pin Definitions
Name
Pin Number Pin Number Pin Number
CY22393
CY22394
CY22395
CY223931
Description
CLKC
1
1
1
Configurable clock output C
VDD
2
2
2
Power supply
AGND
3
3
3
Analog Ground
XTALIN
4
4
4
Reference crystal input or external reference clock input
XTALOUT
5
5
5
Reference crystal feedback
XBUF
6
6
N/A
LVDD
N/A
N/A
6
Low voltage clock output power supply
7
N/A
7
Configurable clock output D; LCLKD referenced to LVDD
N/A
7
N/A
8
N/A
8
N/A
8
N/A
CLKD or LCLKD
P– CLK
CLKE or LCLKE
P+ CLK
Buffered reference clock output
LV PECL output[1]
Configurable clock output E; LCLKE referenced to LVDD
LV PECL output[1]
CLKB or LCLKB
9
9
9
Configurable clock output B; LCLKB referenced to LVDD
CLKA or LCLKA
10
10
10
Configurable clock output A; LCLKA referenced to LVDD
GND/LGND
11
11
11
Ground
SDAT (S0)
12
12
12
Serial Port Data. S0 value latched during start up
SCLK (S1)
13
13
13
Serial Port Clock. S1 value latched during start up
AVDD
14
14
14
Analog Power Supply
S2/
SUSPEND
15
15
15
General purpose input for frequency control; bit 2. Optionally,
Suspend mode control input
SHUTDOWN/
OE
16
16
16
Places outputs in tri-state condition and shuts down chip when
LOW. Optionally, only places outputs in tri-state condition and
does not shut down chip when LOW
Note
1. LVPECL outputs require an external termination network.
Document #: 38-07186 Rev. *E
Page 4 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Operation
The CY22393, CY22394, and CY22395 are a family of parts
designed as upgrades to the existing CY22392 device. These
parts have similar performance to the CY22392, but provide
advanced features to meet the needs of more demanding
applications.
The clock family has three PLLs which, when combined with the
reference, allow up to four independent frequencies to be output
on up to six pins. These three PLLs are completely
programmable.
The CY223931 is the CY22393 with NiPdAu lead finish.
Configurable PLLs
PLL1 generates a frequency that is equal to the reference
divided by an 8-bit divider (Q) and multiplied by an 11-bit divider
in the PLL feedback loop (P). The output of PLL1 is sent to two
locations: the cross point switch and the PECL output
(CY22394). The output of PLL1 is also sent to a /2, /3, or /4
synchronous post-divider that is output through CLKE. The
frequency of PLL1 can be changed using serial programming or
by external CMOS inputs, S0, S1, and S2. See the following
section on General Purpose Inputs for more detail.
PLL2 generates a frequency that is equal to the reference
divided by an 8-bit divider (Q) and multiplied by an 11-bit divider
in the PLL feedback loop (P). The output of PLL2 is sent to the
cross point switch. The frequency of PLL2 is changed using
serial programming.
PLL3 generates a frequency that is equal to the reference
divided by an 8-bit divider (Q) and multiplied by an 11-bit divider
in the PLL feedback loop (P). The output of PLL3 is sent to the
cross point switch. The frequency of PLL3 is changed using
serial programming.
General Purpose Inputs
S2 is a general purpose input that is programmed to allow for two
different frequency settings. Options that switches with this
general purpose input are as follows: the frequency of PLL1, the
output divider of CLKB, and the output divider of CLKA.
The two frequency settings are contained within an eight-row
frequency table. The values of SCLK (S1) and SDAT (S0) pins
are latched during start up and used as the other two indexes
into this array.
CLKA and CLKB have seven-bit dividers that point to one of the
two programmable settings (register 0 and register 1). Both
clocks share a single register control and both must be set to
register 0, or both must be set to register 1.
For example, the part may be programmed to use S0, S1, and
S2 (0,0,0 to 1,1,1) to control eight different values of P and Q on
PLL1. For each PLL1 P and Q setting, one of the two CLKA and
CLKB divider registers can be chosen. Any divider change as a
result of switching S0, S1, or S2 is guaranteed to be glitch free.
Crystal Input
The input crystal oscillator is an important feature of this family
of parts because of its flexibility and performance features.
The oscillator inverter has programmable drive strength. This
allows for maximum compatibility with crystals from various
manufacturers, process, performance, and quality.
The input load capacitors are placed on-die to reduce external
component cost. These capacitors are true parallel-plate
capacitors for ultra-linear performance. These were chosen to
reduce the frequency shift that occurs when nonlinear load
capacitance interacts with load, bias, supply, and temperature
changes. Nonlinear (FET gate) crystal load capacitors must not
be used for MPEG, POTS dial tone, communications, or other
applications that are sensitive to absolute frequency
requirements.
The value of the load capacitors is determined by six bits in a
programmable register. The load capacitance can be set with a
resolution of 0.375pF for a total crystal load range of 6pF to 30pF.
For driven clock inputs, the input load capacitors can be
completely bypassed. This allows the clock chip to accept driven
frequency inputs up to 166 MHz. If the application requires a
driven input, leave XTALOUT floating.
Digital VCXO
The serial programming interface is used to dynamically change
the capacitor load value on the crystal. A change in crystal load
capacitance corresponds with a change in the reference
frequency.
For special pullable crystals specified by Cypress, the
capacitance pull range is +150 ppm to –150 ppm from midrange.
Be aware that adjusting the frequency of the reference affects all
frequencies on all PLLs in a similar manner since all frequencies
are derived from the single reference.
Output Configuration
Under normal operation there are four internal frequency
sources that are routed through a programmable cross point
switch to any of the four programmable 7-bit output dividers. The
four sources are: reference, PLL1, PLL2, and PLL3. The
following is a description of each output.
CLKA’s output originates from the cross point switch and goes
through a programmable 7-bit post divider. The 7-bit post divider
derives its value from one of the two programmable registers.
See the section on “General Purpose Inputs” on page 5 for more
information.
CLKB’s output originates from the cross point switch and goes
through a programmable 7-bit post divider. The 7-bit post divider
derives its value from one of the two programmable registers.
See the section on “General Purpose Inputs” on page 5 for more
information.
CLKC’s output originates from the cross point switch and goes
through a programmable 7-bit post divider. The 7-bit post divider
derives its value from one programmable register.
CLKD’s output originates from the cross point switch and goes
through a programmable 7-bit post divider. The 7-bit post divider
derives its value from one programmable register. For the
CY22394, CLKD is brought out as the complimentary version of
Document #: 38-07186 Rev. *E
Page 5 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
a LV PECL Clock referenced to CLKE, bypassing both the cross
point switch and 7-bit post divider.
CLKE’s output originates from PLL1 and goes through a post
divider that may be programmed to /2, /3, or /4. For the CY22394,
CLKE is brought out as a low voltage PECL Clock, bypassing the
post divider.
XBUF is the buffered reference.
CyClocksRT is used to generate P, Q, and divider values used
in serial programming. There are many internal frequency rules
that are not documented in this data sheet, but are required for
proper operation of the device. Check these rules by using the
latest version of CyClocksRT.
Junction Temperature Limitations
The Clock outputs have been designed to drive a single point
load with a total lumped load capacitance of 15 pF. While driving
multiple loads is possible with the proper termination it is
generally not recommended.
It is possible to program this family such that the maximum
Junction Temperature rating is exceeded. The package θJA is
115 °C/W. Use the CyClocksRT power estimation feature to
verify that the programmed configuration meets the Junction
Temperature and Package Power Dissipation maximum ratings.
Power-Saving Features
Dynamic Updates
The SHUTDOWN/OE input tri-states the outputs when pulled
LOW. If system shutdown is enabled, a LOW on this pin also
shuts off the PLLs, counters, reference oscillator, and all other
active components. The resulting current on the VDD pins is less
than 5 mA (typical). Relock the PLLs after leaving shutdown
mode.
The output divider registers are not synchronized with the output
clocks. Changing the divider value of an active output is likely
cause a glitch on that output.
The S2/SUSPEND input is configured to shut down a
customizable set of outputs and/or PLLs, when LOW. All PLLs
and any of the outputs are shut off in nearly any combination.
The only limitation is that if a PLL is shut off, all outputs derived
from it must also be shut off. Suspending a PLL shuts off all
associated logic, while suspending an output simply forces a
tri-state condition.
With the serial interface, each PLL and/or output is individually
disabled. This provides total control over the power savings.
Improving Jitter
Jitter Optimization Control is useful for mitigating problems
related to similar clocks switching at the same moment, causing
excess jitter. If one PLL is driving more than one output, the
negative phase of the PLL can be selected for one of the outputs
(CLKA–CLKD). This prevents the output edges from aligning,
allowing superior jitter performance.
Power Supply Sequencing
For parts with multiple VDD pins, there are no power supply
sequencing requirements. The part is not fully operational until
all VDD pins have been brought up to the voltages specified in
the Operating Conditions Table on page 13.
All grounds must be connected to the same ground plane.
CyClocksRT Software
CyClocksRT is our second generation software application that
allows users to configure this family of devices. The easy-to-use
interface offers complete control of the many features of this
family including, but not limited to, input frequency, PLL and
output frequencies, and different functional options. It checks
data sheet frequency range limitations and automatically applies
performance tuning. CyClocksRT also has a power estimation
feature that allows the user to see the power consumption of a
specific configuration. You can download a free copy of
CyberClocks that includes CyClocksRT for free on Cypress’s
web site at www.cypress.com.
Document #: 38-07186 Rev. *E
PLL P and Q data is spread between three bytes. Each byte
becomes active on the acknowledge for that byte, so changing
P and Q data for an active PLL is likely cause the PLL to try to
lock on an out-of-bounds condition. For this reason, turn off the
PLL being programmed during the update. Do this by setting the
PLL*_En bit LOW.
PLL1, CLKA, and CLKB each have multiple registers supplying
data. To program these resources safely, always program an
inactive register, and then transition to that register. This allows
these resources to stay active during programming.
The serial interface is active even with the SHUTDOWN/OE pin
LOW as the serial interface logic uses static components and is
completely self timed. The part does not meet the IDDS current
limit with transitioning inputs.
Memory Bitmap Definitions
Clk{A–D}_Div[6:0]
Each of the four main output clocks (CLKA–CLKD) features a
7-bit linear output divider. Any divider setting between 1 and 127
may be used by programming the value of the desired divider
into this register. Odd divide values are automatically duty cycle
corrected. Setting a divide value of zero powers down the divider
and forces the output to a tri-state condition.
CLKA and CLKB have two divider registers, selected by the
DivSel bit (which in turn is selected by S2, S1, and S0). This
allows the output divider value to change dynamically. For the
CY22394 device, ClkD_Div = 000001.
ClkE_Div[1:0]
CLKE has a simpler divider (see Table 1). For the CY22394, set
ClkE_Div = 01.
Table 1. ClkE Divider
ClkE_Div[1:0]
ClkE Output
00
Off
01
PLL1 0° Phase/4
10
PLL1 0° Phase/2
11
PLL1 0° Phase/3
Page 6 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Clk*_FS[2:0]
PLL*_Q[7:0]
Each of the four main output clocks (CLKA–CLKD) has a
three-bit code that determines the clock sources for the output
divider. The available clock sources are: Reference, PLL1, PLL2,
and PLL3. Each PLL provides both positive and negative phased
outputs, for a total of seven clock sources (see Table 2). Note
that the phase is a relative measure of the PLL output phases.
No absolute phase relation exists at the outputs.
PLL*_P[9:0]
Table 2. Clock Source
Clk*_FS[2:0]
Clock Source
PLL*_P0
These are the 8-bit Q value and 11-bit P values that determine
the PLL frequency. The formula is:
PT
F PLL = F REF × ⎛⎝ -------⎞⎠
QT
Equation 1
P T = ( 2 × ( P + 3 ) ) + PO
000
Reference Clock
001
Reserved
010
PLL1 0° Phase
PLL*_LF[2:0]
011
PLL1 180° Phase
100
PLL2 0° Phase
101
PLL2 180° Phase
110
PLL3 0° Phase
These bits adjust the loop filter to optimize the stability of the PLL.
Table 4 can be used to guarantee stability. However,
CyClocksRT uses a more complicated algorithm to set the loop
filter for enhanced jitter performance. Use the Print Preview
function in CyClocksRT to determine the charge pump settings
for optimal jitter performance.
111
PLL3 180° Phase
QT = Q + 2
Table 4. Loop Filter Settings
Xbuf_OE
PLL*_LF[2:0]
PT Min
PT Max
000
16
231
001
232
626
010
627
834
011
835
1043
100
1044
1600
This bit enables the XBUF output when HIGH. For the CY22395,
Xbuf_OE = 0.
PdnEn
This bit selects the function of the SHUTDOWN/OE pin. When
this bit is HIGH, the pin is an active LOW shutdown control. When
this bit is LOW, this pin is an active HIGH output enable control.
Clk*_ACAdj[1:0]
PLL*_En
These bits modify the output predrivers, changing the duty cycle
through the pads. These are nominally set to 01, with a higher
value shifting the duty cycle higher. The performance of the
nominal setting is guaranteed.
This bit enables the PLL when HIGH. If PLL2 or PLL3 are not
enabled, then any output selecting the disabled PLL must have
a divider setting of zero (off). Since the PLL1_En bit is dynamic,
internal logic automatically turns off dependent outputs when
PLL1_En goes LOW.
Clk*_DCAdj[1:0]
These bits modify the DC drive of the outputs. The performance
of the nominal setting is guaranteed.
Table 3. Output Drive Strength
Clk*_DCAdj[1:0]
00
Output Drive Strength
–30% of nominal
DivSel
This bit controls which register is used for the CLKA and CLKB
dividers.
OscCap[5:0]
This controls the internal capacitive load of the oscillator. The
approximate effective crystal load capacitance is:
01
Nominal
10
+15% of nominal
C LOAD = 6pF + ( OscCap × 0.375pF )
11
+50% of nominal
Set to zero for external reference clock.
Document #: 38-07186 Rev. *E
Equation 2
Page 7 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
OscDrv[1:0]
For external reference, the use Table 6.
These bits control the crystal oscillator gain setting. These must
always be set according to Table 5. The parameters are the
Crystal Frequency, Internal Crystal Parasitic Resistance
(available from the manufacturer), and the OscCap setting
during crystal start up, which occurs when power is applied, or
after shutdown is released. If in doubt, use the next higher
setting.
Table 6. Osc Drv for External Reference
00H–20H
Crystal Freq\ R 30Ω
20H–30H
1–25
25–50
50–90
90–166
OscDrv[1:0]
00
01
10
11
Reserved
These bits must be programmed LOW for proper operation of the
device.
Table 5. Crystal Oscillator Gain Settings
OscCap
External Freq (MHz)
30H–40H
60Ω
30Ω
60Ω
30Ω
60Ω
8–15 MHz
00
01
01
10
01
10
15–20 MHz
01
10
01
10
10
10
20–25 MHz
01
10
10
10
10
11
25–30 MHz
10
10
10
11
11
NA
Serial Programming Bitmaps — Summary Tables
Addr
DivSel
b7
b6
b5
b4
08H
0
ClkA_FS[0]
ClkA_Div[6:0]
09H
1
ClkA_FS[0]
ClkA_Div[6:0]
0AH
0
ClkB_FS[0]
ClkB_Div[6:0]
0BH
1
ClkB_FS[0]
ClkB_Div[6:0]
0CH
–
ClkC_FS[0]
ClkC_Div[6:0]
0DH
–
ClkD_FS[0]
ClkD_Div[6:0]
0EH
–
ClkD_FS[2:1]
ClkC_FS[2:1]
0FH
–
Clk{C,X}_ACAdj[1:0]
Clk{A,B,D,E}_ACAdj[1:0]
10H
–
ClkX_DCAdj[1]
Clk{D,E}_DCAdj[1]
11H
–
b3
ClkB_FS[2:1]
PdnEn
ClkC_DCAdj[1]
–
13H
–
14H
–
PLL3_Q[7:0]
15H
–
PLL3_P[7:0]
16H
–
17H
–
40H
Reserved
PLL2_En
PLL2_PO
PLL3_LF[2:0]
PLL3_PO
Osc_Cap[5:0]
b7
b6
ClkA_FS[2:1]
ClkE_Div[1:0]
Clk{A,B}_DCAdj[1]
b5
PLL2_P[9:8]
PLL3_P[9:8]
Osc_Drv[1:0]
b4
b3
b2
b1
b0
PLL1_Q[7:0]
PLL1_P[7:0]
DivSel
PLL1_En
001
PLL1_LF[2:0]
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_Q[7:0]
44H
PLL1_P[7:0]
45H
DivSel
PLL1_En
010
PLL1_LF[2:0]
PLL1_Q[7:0]
47H
48H
PLL2_LF[2:0]
PLL3_En
000
42H
46H
b0
PLL2_P[7:0]
Reserved
41H
43H
Xbuf_OE
b1
PLL2_Q[7:0]
12H
Addr S2 (1,0)
b2
PLL1_P[7:0]
DivSel
Document #: 38-07186 Rev. *E
PLL1_En
PLL1_LF[2:0]
Page 8 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Addr S2 (1,0)
49H
b7
b6
b5
b4
011
DivSel
PLL1_En
PLL1_LF[2:0]
100
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_PO
PLL1_P[9:8]
PLL1_P[7:0]
4EH
DivSel
PLL1_En
PLL1_LF[2:0]
101
PLL1_Q[7:0]
50H
PLL1_P[7:0]
51H
DivSel
PLL1_En
PLL1_LF[2:0]
110
PLL1_Q[7:0]
53H
PLL1_P[7:0]
54H
55H
b0
PLL1_Q[7:0]
4DH
52H
b1
PLL1_P[7:0]
4BH
4FH
b2
PLL1_Q[7:0]
4AH
4CH
b3
DivSel
PLL1_En
PLL1_LF[2:0]
111
PLL1_Q[7:0]
56H
57H
PLL1_P[7:0]
DivSel
PLL1_En
PLL1_LF[2:0]
Serial Bus Programming Protocol and Timing
The CY22393, CY22394 and CY22395 have a 2-wire serial
interface for in-system programming. They use the SDAT and
SCLK pins, and operate up to 400 kbit/s in Read or Write mode.
Except for the data hold time, it is compliant with the I2C bus
standard. The basic Write serial format is as follows:
Start Bit; 7-bit Device Address (DA); R/W Bit; Slave Clock
Acknowledge (ACK); 8-bit Memory Address (MA); ACK; 8-bit
Data; ACK; 8-bit Data in MA+1 if desired; ACK; 8-bit Data in
MA+2; ACK; etc. until STOP Bit. The basic serial format is illustrated in Figure 3 on page 11.
Default Startup Condition for the CY22393/931/94/95
Data Valid
Data is valid when the clock is HIGH, and can only be transitioned when the clock is LOW as illustrated in Figure 4 on page
11.
Data Frame
Every new data frame is indicated by a start and stop sequence,
as illustrated in Figure 5 on page 11.
Start Sequence - Start Frame is indicated by SDAT going LOW
when SCLK is HIGH. Every time a start signal is given, the next
8-bit data must be the device address (seven bits) and a R/W bit,
followed by register address (eight bits) and register data (eight
bits).
The default (programmed) condition of each device is generally
set by the distributor, who programs the device using a customer
specified JEDEC file produced by CyClocksRT, Cypress’s proprietary development software. Parts shipped by the factory are
blank and unprogrammed. In this condition, all bits are set to 0,
all outputs are tri-stated, and the crystal oscillator circuit is active.
Stop Sequence - Stop Frame is indicated by SDAT going HIGH
when SCLK is HIGH. A Stop Frame frees the bus for writing to
another part on the same bus or writing to another random
register address.
While users can develop their own subroutine to program any or
all of the individual registers as described in the following pages,
it may be easier to simply use CyClocksRT to produce the
required register setting file.
During Write Mode the CY22393, CY22394, and CY22395
respond with an Acknowledge pulse after every eight bits. To do
this, they pull the SDAT line LOW during the N*9th clock cycle,
as illustrated in Figure 6 on page 12. (N = the number of bytes
transmitted). During Read Mode, the master generates the
acknowledge pulse after the data packet is read.
Device Address
Acknowledge Pulse
The device address is a 7-bit value that is configured during Field
Programming. By programming different device addresses, two
or more parts are connected to the serial interface and can be
independently controlled. The device address is combined with
a read/write bit as the LSB and is sent after each start bit.
The default serial interface address is 69H, but must there be a
conflict with any other devices in your system, this can also be
changed using CyClocksRT.
Document #: 38-07186 Rev. *E
Page 9 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Write Operations
Random Read
Writing Individual Bytes
A valid write operation must have a full 8-bit register address
after the device address word from the master, which is followed
by an acknowledge bit from the slave (ack = 0/LOW). The next
eight bits must contain the data word intended for storage. After
the data word is received, the slave responds with another
acknowledge bit (ack = 0/LOW), and the master must end the
write sequence with a STOP condition.
Writing Multiple Bytes
To write multiple bytes at a time, the master must not end the
write sequence with a STOP condition. Instead, the master
sends multiple contiguous bytes of data to be stored. After each
byte, the slave responds with an acknowledge bit, the same as
after the first byte, and accepts data until the STOP condition
responds to the acknowledge bit. When receiving multiple bytes,
the CY22393, CY223931, CY22394, and CY22395 internally
increment the register address.
Read Operations
Read operations are initiated the same way as Write operations
except that the R/W bit of the slave address is set to ‘1’ (HIGH).
There are three basic read operations: current address read,
random read, and sequential read.
Current Address Read
Through random read operations, the master may access any
memory location. To perform this type of read operation, first set
the word address. Do this by sending the address to the
CY22393, CY22394 and CY22395 as part of a write operation.
After the word address is sent, the master generates a START
condition following the acknowledge. This terminates the write
operation before any data is stored in the address, but not before
setting the internal address pointer. Next, the master reissues
the control byte with the R/W byte set to ‘1’. The CY22393,
CY22394 and CY22395 then issue an acknowledge and transmit
the 8-bit word. The master device does not acknowledge the
transfer, but generates a STOP condition which causes the
CY22393, CY22394 and CY22395 to stop transmission.
Sequential Read
Sequential read operations follow the same process as random
reads except that the master issues an acknowledge instead of
a STOP condition after transmitting the first 8-bit data word. This
action increments the internal address pointer, and subsequently
outputs the next 8-bit data word. By continuing to issue acknowledges instead of STOP conditions, the master serially reads the
entire contents of the slave device memory. Note that register
addresses outside of 08H to 1BH and 40H to 57H can be read
from but are not real registers and do not contain configuration
information. When the internal address pointer points to the FFH
register, after the next increment, the pointer points to the 00H
register.
The CY22393, CY22394 and CY22395 have an onboard
address counter that retains “1” more than the address of the last
word access. If the last word written or read was word ‘n’, then a
current address read operation returns the value stored in
location ‘n+1’. When the CY22393, CY22394 and CY22395
receive the slave address with the R/W bit set to a ‘1’, they issue
an acknowledge and transmit the 8-bit word. The master device
does not acknowledge the transfer, but generates a STOP
condition, which causes the CY22393, CY22394 and CY22395
to stop transmission.
Figure 2. Data Transfer Sequence on the Serial Bus
SCLK
SDAT
START
Condition
Document #: 38-07186 Rev. *E
Address or
Acknowledge
Valid
Data may
be changed
STOP
Condition
Page 10 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Figure 3. Data Frame Architecture
SDAT Write
Multiple
Contiguous
Registers
1 Bit
1 Bit Slave
R/W = 0 ACK
7-bit
Device
Address
1 Bit
Slave
ACK
8-bit
Register
Address
(XXH)
1 Bit
Slave
ACK
8-bit
Register
Data
(XXH)
1 Bit
Slave
ACK
8-bit
Register
Data
(XXH+1)
1 Bit
Slave
ACK
8-bit
Register
Data
(XXH+2)
1 Bit
Slave
ACK
8-bit
Register
Data
(FFH)
1 Bit
Slave
ACK
1 Bit
Slave
ACK
8-bit
Register
Data
(00H)
Stop Signal
Start Signal
SDAT Read
Current
Address
Read Start Signal
SDAT Read
Multiple
Contiguous
Registers
1 Bit
1 Bit Slave
R/W = 1 ACK
7-bit
Device
Address
1 Bit
Slave
ACK
1 Bit
Master
ACK
8-bit
Register
Data
Stop Signal
1 Bit
1 Bit Slave
R/W = 0 ACK
7-bit
Device
Address
1 Bit
Slave
ACK
8-bit
Register
Address
(XXH)
1 Bit
Master
ACK
7-bit
Device
Address
+R/W=1
1 Bit
Master
ACK
8-bit
Register
Data
(XXH)
1 Bit
Master
ACK
8-bit
Register
Data
(XXH+1)
8-bit
Register
Data
(FFH)
1 Bit
Master
ACK
1 Bit
Master
ACK
1 Bit
Master
ACK
8-bit
Register
Data
(00H)
Stop Signal
Start Signal
Repeated
Start bit
Figure 4. Data Valid and Data Transition Periods
Data Valid
Transition
to next Bit
SDAT
tDH
tSU
CLKHIGH
VIH
SCLK
CLKLOW
VIL
Serial Programming Interface Timing
Figure 5. Start and Stop Frame
SDAT
START
Document #: 38-07186 Rev. *E
Transition
to next Bit
SCLK
STOP
Page 11 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Figure 6. Frame Format (Device Address, R/W, Register Address, Register Data)
SDAT
+
START
SCLK
DA6
DA5 DA0
+
R/W
ACK
RA7
RA6 RA1
+
RA0
D7
ACK
+
+
D6
D1
D0
ACK
STOP
+
Serial Programming Interface Timing Specifications
Parameter
fSCLK
Description
Frequency of SCLK
Min
Max
Unit
–
400
kHz
Start mode time from SDA LOW to SCL LOW
0.6
–
μs
CLKLOW
SCLK LOW period
1.3
–
μs
CLKHIGH
SCLK HIGH period
0.6
–
μs
tSU
Data transition to SCLK HIGH
100
–
ns
tDH
Data hold (SCLK LOW to data transition)
100
–
ns
–
300
ns
Rise time of SCLK and SDAT
Fall time of SCLK and SDAT
–
300
ns
Stop mode time from SCLK HIGH to SDAT HIGH
0.6
–
μs
Stop mode to Start mode
1.3
–
μs
Document #: 38-07186 Rev. *E
Page 12 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Absolute Maximum Conditions
Static Discharge Voltage
(per MIL-STD-883, Method 3015) ........................... > 2000V
Supply Voltage................................................–0.5V to +7.0V
DC Input Voltage ........................... –0.5V to + (AVDD + 0.5V)
Storage Temperature .................................. –65°C to +125°C
Latch up (per JEDEC 17) .................................... > ±200 mA
Junction Temperature .................................................. 125°C
Stresses exceeding Absolute Maximum Conditions may cause
permanent damage to the device. These conditions are stress
ratings only. Functional operation of the device at these or any
other conditions beyond those indicated in the operation
sections of this data sheet is not implied. Extended exposure to
Absolute Maximum Conditions may affect reliability.
Data Retention at Tj=125×C..................................> 10 years
Maximum Programming Cycles....................................... 100
Package Power Dissipation ...................................... 350 mW
Operating Conditions
Parameter
Description
Part Numbers
Min
Typ
Max
Unit
VDD/AVDD/LVDD Supply Voltage
All
3.135
3.3
3.465
V
LVDD
2.5V Output Supply Voltage
CY22395
2.375
2.5
2.625
V
TA
Commercial Operating Temperature, Ambient All
0
–
+70
°C
Industrial Operating Temperature, Ambient
All
–40
–
+85
°C
CLOAD_OUT
Maximum Load Capacitance
All
–
–
15
pF
fREF
External Reference Crystal
All
8
–
30
MHz
External Reference Clock,[3] Commercial
All
1
–
166
MHz
External Reference Clock,[3] Industrial
All
1
–
150
MHz
3.3V Electrical Characteristics
Parameter
Conditions[2]
Min
Typ
Max
Unit
Output High
Current[4]
VOH = (L)VDD – 0.5, (L)VDD = 3.3V
12
24
–
mA
IOL
Output Low
Current[4]
VOL = 0.5, (L)VDD = 3.3V
12
24
–
mA
CXTAL_MIN
Crystal Load Capacitance[4]
Capload at minimum setting
–
6
–
pF
CXTAL_MAX
Crystal Load
Capacitance[3]
Capload at maximum setting
–
30
–
pF
CIN
Input Pin Capacitance[4]
Except crystal pins
–
7
–
pF
–
–
AVDD
30%
AVDD
IOH
Description
VIH
HIGH-Level Input Voltage
CMOS levels,% of AVDD
70%
VIL
LOW-Level Input Voltage
CMOS levels,% of AVDD
–
IIH
Input HIGH Current
VIN = AVDD – 0.3 V
–
<1
10
μA
IIL
Input LOW Current
VIN = +0.3 V
–
<1
10
μA
IOZ
Output Leakage Current
Three-state outputs
–
10
μA
IDD
Total Power Supply Current
3.3V Power Supply;
2 outputs at 20 MHz; 4 outputs at 40 MHz
–
50
–
mA
3.3V Power Supply;
2 outputs at 166 MHz; 4 outputs at 83 MHz
–
100
–
mA
–
5
20
μA
Min
Typ
Max
Unit
IDDS
Total Power Supply Current in Shutdown active
Shutdown Mode
2.5V Electrical Characteristics (CY22395 only)[5]
Parameter
Description
Current[4]
IOH_2.5
Output High
IOL_2.5
Output Low Current[4]
Conditions
VOH = LVDD – 0.5, LVDD = 2.5 V
8
16
–
mA
VOL = 0.5, LVDD = 2.5 V
8
16
–
mA
Notes
2. Unless otherwise noted, Electrical and Switching Characteristics are guaranteed across these operating conditions.
3. External input reference clock must have a duty cycle between 40% and 60%, measured at VDD/2.
4. Guaranteed by design, not 100% tested.
5. VDDL is only specified and characterized at 3.3V ± 5% and 2.5V ± 5%. VDDL may be powered at any value between 3.465 and 2.375.
Document #: 38-07186 Rev. *E
Page 13 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
3.3V Switching Characteristics
Parameter
1/t1
Description
Output Frequency[4, 6]
Conditions
Clock output limit, CMOS, Commercial
Clock output limit, CMOS, Industrial
Output Duty Cycle[4, 7]
t2
Min
Typ
Max
Unit
–
–
200
MHz
–
–
166
MHz
Clock output limit, PECL, Commercial
(CY22394 only)
100
–
400
MHz
Clock output limit, PECL, Industrial
(CY22394 only)
125
–
375
MHz
Duty cycle for outputs, defined as t2 ÷ t1,
Fout < 100 MHz, divider >= 2,
measured at VDD/2
45%
50%
55%
Duty cycle for outputs, defined as t2 ÷ t1,
Fout > 100 MHz or divider = 1,
measured at VDD/2
40%
50%
60%
Output clock rise time, 20% to 80% of VDD
0.75
1.4
t3
Rising Edge Slew Rate[4]
t4
Falling Edge Slew
Rate[4]
Output clock fall time, 20% to 80% of VDD
0.75
1.4
t5
Output three-state Timing[4]
Time for output to enter or leave three-state
mode after SHUTDOWN/OE switches
–
150
t6
Clock Jitter[4, 8]
Peak-to-peak period jitter, CLK outputs
measured at VDD/2
–
400
v7
P+/P– Crossing Point[4]
Crossing point referenced to Vdd/2,
balanced resistor network (CY22394 only)
–0.2
0
t8
P+/P– Jitter[4, 8]
Peak-to-peak period jitter, P+/P– outputs
measured at crossing point (CY22394 only)
–
200
t9
Lock Time[4]
PLL Lock Time from Power up
–
1.0
3
Min
Typ
Max
Unit
133
MHz
V/ns
V/ns
300
ns
ps
0.2
V
ps
ms
2.5V Switching Characteristics (CY22395 only)[5]
Parameter
Description
Conditions
1/t1_2.5
Output Frequency[4, 6]
Clock output limit, LVCMOS
t2_2.5
Output Duty Cycle[4, 7]
Duty cycle for outputs, defined as t2 ÷ t1
measured at LVDD/2
t3_2.5
Rising Edge Slew Rate[4]
t4_2.5
Falling Edge Slew Rate[4]
40%
50%
60%
Output clock rise time, 20% to 80% of LVDD
0.5
1.0
V/ns
Output clock fall time, 20% to 80% of LVDD
0.5
1.0
V/ns
Notes
6. Guaranteed to meet 20%–80% output thresholds, duty cycle, and crossing point specifications.
7. Reference Output duty cycle depends on XTALIN duty cycle.
8. Jitter varies significantly with configuration. Reference Output jitter depends on XTALIN jitter and edge rate.
Document #: 38-07186 Rev. *E
Page 14 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Switching Waveforms
Figure 7. All Outputs, Duty Cycle and Rise and Fall Time
t1
t2
OUTPUT
t3
t4
Figure 8. Output Tri-state Timing
OE
t5
t5
ALL
TRI-STATE
OUTPUTS
Figure 9. CLK Output Jitter
t6
CLK
OUTPUT
Figure 10. P+/P– Crossing Point and Jitter
t8
P–
v7
VDD/2
P+
Figure 11. CPU Frequency Change
SELECT
OLD SELECT
Fold
NEW SELECT STABLE
t9
Fnew
CPU
Document #: 38-07186 Rev. *E
Page 15 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Test Circuit
Figure 12. Test Circuit
AV DD
CLK out
C LOAD
0.1 μF
(L)V
V DD
P+/P- out
DD
0.1 μF
GND
Document #: 38-07186 Rev. *E
Page 16 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Ordering Information
Ordering Code
Package Type
Product Flow
CY22393ZC-xxx[9]
16-pin TSSOP
CY22393ZC-xxxT[9]
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22393FC[9]
16-pin TSSOP
Commercial, 0 to 70°C
CY22393FCT[9]
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22394FC[9]
16-pin TSSOP
Commercial, 0 to 70°C
CY22394FCT[9]
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22395FC[9]
16-pin TSSOP
Commercial, 0 to 70°C
CY3672-USB
FTG Programmer
CY3698
CY22392F, CY22393F, CY22394F, and
CY22395F Adapter for CY3672-USB
Commercial, 0 to 70°C
Pb-Free
CY22393ZXC-xxx
16-pin TSSOP
Commercial, 0 to 70°C
CY22393ZXC-xxxT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22393ZXI-xxx
16-pin TSSOP
Industrial, –40 to 85°C
CY22393ZXI-xxxT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
CY22393FXC
16-pin TSSOP
Commercial, 0 to 70°C
CY22393FXCT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22393FXI
16-pin TSSOP
Industrial, –40 to 85°C
CY22393FXIT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
CY223931FXI
16-pin TSSOP with NiPdAu lead finish
Industrial, –40 to 85°C
CY22394ZXC-xxx
16-pin TSSOP
Commercial, 0 to 70°C
CY22394ZXC-xxxT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22394ZXI-xxx
16-pin TSSOP
Industrial, –40 to 85°C
CY22394ZXI-xxxT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
CY22394FXC
16-pin TSSOP
Commercial, 0 to 70°C
CY22394FXCT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22394FXI
16-pin TSSOP
Industrial, –40 to 85°C
CY22394FXIT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
CY22395ZXC-xxx
16-pin TSSOP
Commercial, 0 to 70°C
CY22395ZXC-xxxT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22395ZXI-xxx
16-pin TSSOP
Industrial, –40 to 85°C
CY22395ZXI-xxxT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
CY22395FXC
16-pin TSSOP
Commercial, 0 to 70°C
CY22395FXCT
16-pin TSSOP - Tape and Reel
Commercial, 0 to 70°C
CY22395FXI
16-pin TSSOP
Industrial, –40 to 85°C
CY22395FXIT
16-pin TSSOP - Tape and Reel
Industrial, –40 to 85°C
Note
9. Not recommended for new designs.
Document #: 38-07186 Rev. *E
Page 17 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Package Diagram
Figure 13. 16-Pin TSSOP 4.40 MM Body Z16.173
PIN 1 ID
DIMENSIONS IN MM[INCHES] MIN.
MAX.
1
REFERENCE JEDEC MO-153
6.25[0.246]
6.50[0.256]
PACKAGE WEIGHT 0.05 gms
PART #
4.30[0.169]
4.50[0.177]
Z16.173
STANDARD PKG.
ZZ16.173 LEAD FREE PKG.
16
0.65[0.025]
BSC.
0.19[0.007]
0.30[0.012]
1.10[0.043] MAX.
0.25[0.010]
BSC
GAUGE
PLANE
0°-8°
0.076[0.003]
0.85[0.033]
0.95[0.037]
4.90[0.193]
5.10[0.200]
Document #: 38-07186 Rev. *E
0.05[0.002]
0.15[0.006]
SEATING
PLANE
0.50[0.020]
0.70[0.027]
0.09[[0.003]
0.20[0.008]
51-85091-*A
Page 18 of 19
[+] Feedback
CY22393, CY223931, CY22394, CY22395
Document History Page
Document Title: CY22393, CY223931, CY22394, CY22395 Three-PLL Serial-Programmable Flash-Programmable Clock
Generator
Document Number: 38-07186
REV.
ECN
Orig. of
Change
Submission
Date
**
111984
DSG
12/09/01
Description of Change
Change from Spec number: 38-01144 to 38-07186
*A
129388
RGL
10/13/03
Added timing information
*B
237755
RGL
See ECN
Added Lead-Free Devices
*C
848580
RGL
See ECN
Added references to I2C; removed all references to SPI
*D
2584052
AESA/KVM
10/10/08
Updated template. Added Note “Not recommended for new designs.”
Added part number CY22393FC, and CY22393FCT in Ordering
Information table. Removed part number CY22393FI, CY22393FIT,
CY22393ZI-XXX, CY22393ZI-XXXT, CY22393FC, CY22393FCT,
CY22392FI, CY22392FIT, CY22394ZC-XXX, CY22394ZC-XXXT,
CY22394ZI-XXX, CY22394ZI-XXXT, CY22394FI, CY22394FIT,
CY22395ZC-XXX, CY22395ZC-XXXT, CY22395ZI-XXX,
CY22395ZI-XXXT, CY22395FC, CY22395FCT, and CY22395FI in
Ordering Information table. Changed Lead-Free to Pb-Free.
Changed serial interface hold time (TDH) from 0ns to 100ns.
Replaced I2C references with “2-wire serial interface”
*E
2634202
KVM/AESA
01/09/09
Changed title to include CY223931. Added CY223931 to page 1 features
list. Added part number CY223931FXI. Added CY22393_I to the Selector
Guide (p.2), and changed the format of the part numbers. Added overbar
to SUSPEND in Pin Definitions table
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office
closest to you, visit us at cypress.com/sales.
Products
PSoC
Clocks & Buffers
PSoC Solutions
psoc.cypress.com
clocks.cypress.com
General
Low Power/Low Voltage
psoc.cypress.com/solutions
psoc.cypress.com/low-power
Wireless
wireless.cypress.com
Precision Analog
Memories
memory.cypress.com
LCD Drive
psoc.cypress.com/lcd-drive
image.cypress.com
CAN 2.0b
psoc.cypress.com/can
USB
psoc.cypress.com/usb
Image Sensors
psoc.cypress.com/precision-analog
© Cypress Semiconductor Corporation, 2001-2009. 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 implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Any Source Code (software and/or firmware) is owned by Cypress Semiconductor Corporation (Cypress) and is protected by and subject to worldwide patent protection (United States and foreign),
United States copyright laws and international treaty provisions. Cypress hereby grants to licensee a personal, non-exclusive, non-transferable license to copy, use, modify, create derivative works of,
and compile the Cypress Source Code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a Cypress
integrated circuit as specified in the applicable agreement. Any reproduction, modification, translation, compilation, or representation of this Source Code except as specified above is prohibited without
the express written permission of Cypress.
Disclaimer: CYPRESS MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS MATERIAL, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. Cypress reserves the right to make changes without further notice to the materials described herein. Cypress does not
assume any liability arising out of the application or use of any product or circuit described herein. 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’ product in a life-support systems application implies that the manufacturer
assumes all risk of such use and in doing so indemnifies Cypress against all charges.
Use may be limited by and subject to the applicable Cypress software license agreement.
Document #: 38-07186 Rev. *E
Revised January 9, 2009
Page 19 of 19
CyClocksRT is a trademark of Cypress Semiconductor. All product and company names mentioned in this document are the trademarks of their respective holders.
[+] Feedback