CYPRESS CY7B994V-5BBC

RoboClock
CY7B993V, CY7B994V
High Speed Multi Phase PLL Clock Buffer
Features
Functional Description
■
500 ps Max Total Timing Budget (TTB™) window
■
12 MHz to 100 MHz (CY7B993V), or 24 MHz to 200 MHz
(CY7B994V) Input/Output Operation
■
Matched Pair Output Skew < 200 ps
■
Zero Input-to-Output Delay
■
18 LVTTL Outputs Driving 50 Terminated Lines
■
16 Outputs at 200 MHz: Commercial Temperature
■
6 Outputs at 200 MHz: Industrial Temperature
■
3.3V LVTTL/LVPECL, Fault-tolerant, and Hot Insertable
Reference Inputs
■
Phase Adjustments in 625 ps/1300 ps Steps Up to ± 10.4 ns
■
Multiply/Divide Ratios of 1–6, 8, 10, 12
■
Individual Output Bank Disable
■
Output High Impedance Option for Testing Purposes
■
Fully Integrated Phase Locked Loop (PLL) with Lock Indicator
■
<50-ps Typical Cycle-to-Cycle Jitter
■
Single 3.3V ± 10% Supply
■
100-pin TQFP Package
■
100-pin BGA Package
Cypress Semiconductor Corporation
Document #: 38-07127 Rev. *J
•
The CY7B993V and CY7B994V High-speed Multi-phase PLL
Clock Buffers offer user selectable control over system clock
functions. This multiple output clock driver provides the system
integrator with functions necessary to optimize the timing of
high-performance computer and communication systems.
These devices feature a guaranteed maximum TTB window
specifying all occurrences of output clocks with respect to the
input reference clock across variations in output frequency,
supply voltage, operating temperature, input edge rate, and
process.
Eighteen configurable outputs each drive terminated
transmission lines with impedances as low as 50 while delivering
minimal and specified output skews at LVTTL levels. The outputs are
arranged in five banks. Banks 1 to 4 of four outputs allow a divide
function of 1 to 12, while simultaneously allowing phase
adjustments in 625 ps to 1300 ps increments up to 10.4 ns. One
of the output banks also includes an independent clock invert
function. The feedback bank consists of two outputs, which
allows divide-by functionality from 1 to 12 and limited phase
adjustments. Any one of these eighteen outputs can be
connected to the feedback input as well as driving other inputs.
Selectable reference input is a fault tolerance feature that allows
smooth change-over to secondary clock source, when the
primary clock source is not in operation. The reference inputs
and feedback inputs are configurable to accommodate both
LVTTL or Differential (LVPECL) inputs. The completely
integrated PLL reduces jitter and simplifies board layout.
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised April 26, 2011
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CY7B993V, CY7B994V
Logic Block Diagram
FBKA+
FBKA–
FBKB+
FBKB–
FBSEL
REFA+
REFA–
REFB+
REFB–
REFSEL
Feedback Bank
Bank 4
Bank 3
Document #: 38-07127 Rev. *J
LOCK
Phase
Freq.
Detector
Filter
FS
OUTPUT_MODE
FBF0
FBDS0
FBDS1
FBDIS
3
3
3
Divide and
Phase
Select
Matrix
4F0
4F1
4DS0
4DS1
DIS4
3
3
3
3
Divide and
Phase
Select
Matrix
3F0
3F1
3DS0
3DS1
DIS3
INV3
3
3
3
3
Divide and
Phase
Select
Matrix
3
3
3
3
3
Divide and
Phase
Select
Matrix
3
3
3
3
Divide and
Phase
Select
Matrix
Bank 2
2F0
2F1
2DS0
2DS1
DIS2
Bank 1
1F0
1F1
1DS0
1DS1
DIS1
Control Logic
Divide and Phase
Generator
VCO
3
3
QFA0
QFA1
4QA0
4QA1
4QB0
4QB1
3QA0
3QA1
3QB0
3QB1
2QA0
2QA1
2QB0
2QB1
1QA0
1QA1
1QB0
1QB1
Page 2 of 18
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CY7B993V, CY7B994V
Contents
Features ............................................................................... 1
Functional Description ....................................................... 1
Logic Block Diagram .......................................................... 2
Contents .............................................................................. 3
Pinouts ................................................................................ 4
Block Diagram Description ................................................ 6
Phase Frequency Detector and Filter............................ 6
VCO, Control Logic, Divider, and Phase Generator...... 6
Time Unit Definition ....................................................... 7
Divide and Phase Select Matrix .................................... 7
Output Disable Description............................................ 8
INV3 Pin Function ......................................................... 9
Lock Detect Output Description..................................... 9
Factory Test Mode Description ..................................... 9
Safe Operating Zone ..................................................... 9
Document #: 38-07127 Rev. *J
Absolute Maximum Conditions ........................................10
Operating Range ................................................................10
Electrical Characteristics...................................................10
Switching Characteristics .................................................11
AC Timing Diagrams ..........................................................13
Ordering Information .........................................................14
Package Diagrams .............................................................15
Document History Page ....................................................17
Sales, Solutions, and Legal Information .........................18
Worldwide Sales and Design Support.......................... 18
Products ....................................................................... 18
PSoC Solutions ............................................................ 18
Page 3 of 18
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CY7B993V, CY7B994V
Pinouts
VCCQ
FBKA+
FBKA–
FBSEL
FBKB–
FBKB+
GND
GND
QFA1
VCCN
QFA0
GND
GND
1QA0
VCCN
1QA1
GND
GND
1QB0
VCCN
1QB1
GND
FBDS0
FBDS1
LOCK
Figure 1. Pin Diagram – 100-Pin TQFP
100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76
GND
1
75
VCCQ
3F1
2
74
REFA+
4F1
3
73
REFA –
3F0
4
72
REFSEL
4F0
5
71
REFB–
4DS1
6
70
REFB+
3DS1
7
69
2F0
GND
8
68
FS
4QB1
9
67
GND
VCCN
10
66
2QA0
4QB0
11
65
VCCN
GND
12
64
2QA1
GND
13
63
GND
4QA1
14
62
GND
VCCN
15
61
2QB0
4QA0
16
60
VCCN
GND
17
59
2QB1
2DS1
18
58
GND
1DS1
19
57
FBF0
VCCQ
20
56
1F0
4DS0
21
55
GND
3DS0
22
54
VCCQ
2DS0
23
53
FBDIS
1DS0
24
52
DIS4
GND
25
51
DIS3
CY7B993/4V
Document #: 38-07127 Rev. *J
GND
VCCQ
OUTPUT_MODE
GND
INV3
VCCQ
GND
3QB1
VCCN
3QB0
GND
GND
3QA1
VCCN
3QA0
GND
DIS2
DIS1
1F1
2F1
VCCQ
VCCQ
GND
GND
GND
26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50
Page 4 of 18
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CY7B993V, CY7B994V
Pinouts (continued)
Figure 2. Pin Diagram – 100-Pin BGA
A
B
C
D
E
F
G
H
J
K
1
2
3
4
5
6
7
8
9
10
1QB1
1QB0
1QA1
1QA0
QFA0
QFA1
FBKB+
VCCQ
FBKA–
FBKA+
VCCN
VCCN
VCCN
VCCN
VCCN
VCCN
VCCQ
FBKB–
FBSEL
REFA+
GND
GND
GND
GND
GND
GND
VCCQ
GND
GND
REFA–
LOCK
4F0
3F1
(3_level) (3_level)
GND
FBDS1 FBDS0
2F0
(3_level) (3_level) (3_level)
3F0
4F1
(3_level) (3_level)
4QB1
VCCN
4DS1
(3_level)
GND
4QB0
VCCN
3DS1
(3_level)
GND
GND
4QA1
2DS1
(3_level)
VCCQ
GND
4QA0
1DS1
1DS0
(3_level) (3_level)
4DS0
3DS0
2DS0
(3_level) (3_level) (3_level)
2F1
1F1
(3_level) (3_level)
DIS2
VCCQ
REFSEL REFB–
GND
FS
(3_level)
VCCN
REFB+
GND
GND
FBF0
(3_level)
VCCN
2QA0
GND
GND
GND
VCCQ
1F0
(3_level)
2QA1
VCCQ
GND
GND
VCCQ
DIS1
VCCN
VCCN
VCCN
3QA0
3QA1
OUTPUT
MODE FBDIS
(3_level)
2QB0
GND
INV3
(3_level)
DIS3
2QB1
GND
3QB0
3QB1
DIS4
Table 1. Pin Definition [1]
Pin Name
FBSEL
I/O
Input
FBKA+, FBKA–
FBKB+, FBKB–
Input
REFA+, REFA–
REFB+, REFB–
Input
REFSEL
Input
FS
Input
FBF0
Input
Pin Type
Pin Description
LVTTL
Feedback Input Select. When LOW, FBKA inputs are selected. When HIGH, the FBKB
inputs are selected. This input has an internal pull-down.
LVTTL/ Feedback Inputs. One pair of inputs selected by the FBSEL is used to feedback the clock
LVDIFF output xQn to the phase detector. The PLL operates such that the rising edges of the
reference and feedback signals are aligned in both phase and frequency. These inputs
can operate as differential PECL or single-ended TTL inputs. When operating as a
single-ended LVTTL input, the complementary input must be left open.
LVTTL/ Reference Inputs. These inputs can operate as differential PECL or single-ended TTL
LVDIFF reference inputs to the PLL. When operating as a single-ended LVTTL input, the complementary input must be left open.
LVTTL
Reference Select Input. The REFSEL input controls how the reference input is
configured. When LOW, it uses the REFA pair as the reference input. When HIGH, it uses
the REFB pair as the reference input. This input has an internal pull-down.
3-level
Frequency Select. This input must be set according to the nominal frequency (fNOM) (see
Input
Table 2).
3-level
Feedback Output Phase Function Select. This input determines the phase function of
Input
the Feedback bank’s QFA[0:1] outputs (see Table 4).
Note
1. For all three-state inputs, HIGH indicates a connection to VCC, LOW indicates a connection to GND, and MID indicates an open connection. Internal termination
circuitry holds an unconnected input to VCC/2.
Document #: 38-07127 Rev. *J
Page 5 of 18
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CY7B993V, CY7B994V
Table 1. Pin Definition (continued)[1]
Pin Name
FBDS[0:1]
I/O
Input
Pin Type
Pin Description
3-level
Feedback Divider Function Select. These inputs determine the function of the QFA0
Input
and QFA1 outputs (see Table 5).
FBDIS
Input
LVTTL
Feedback Disable. This input controls the state of QFA[0:1]. When HIGH, the QFA[0:1]
is disabled to the “HOLD-OFF” or “High Z” state; the disable state is determined by
OUTPUT_MODE. When LOW, the QFA[0:1] is enabled (see Table 6). This input has an
internal pull-down.
[1:4]F[0:1]
Input
3-level
Output Phase Function Select. Each pair controls the phase function of the respective
Input
bank of outputs (see Table 4).
[1:4]DS[0:1]
Input
3-level
Output Divider Function Select. Each pair controls the divider function of the respective
Input
bank of outputs (see Table 5).
DIS[1:4]
Input
LVTTL
Output Disable. Each input controls the state of the respective output bank. When HIGH,
the output bank is disabled to the “HOLD-OFF” or “High Z” state; the disable state is
determined by OUTPUT_MODE. When LOW, the [1:4]Q[A:B][0:1] is enabled (see
Table 6). These inputs each have an internal pull-down.
INV3
Input
3-level
Invert Mode. This input only affects Bank 3. When this input is LOW, each matched output
Input
pair becomes complementary (3QA0+, 3QA1–, 3QB0+, 3QB1–). When this input is HIGH,
all four outputs in the same bank are inverted. When this input is MID all four outputs are
non inverting.
LOCK
Output LVTTL
PLL Lock Indicator. When HIGH, this output indicates the internal PLL is locked to the
reference signal. When LOW, the PLL is attempting to acquire lock.
OUTPUT_MODE Input
3-Level Output Mode. This pin determines the clock outputs’ disable state. When this input is
Input
HIGH, the clock outputs disable to high impedance (High Z). When this input is LOW, the
clock outputs disable to “HOLD-OFF” mode. When in MID, the device enters factory test
mode.
QFA[0:1]
Output LVTTL
Clock Feedback Output. This pair of clock outputs is intended to be connected to the
FB input. These outputs have numerous divide options and three choices of phase adjustments. The function is determined by the setting of the FBDS[0:1] pins and FBF0.
[1:4]Q[A:B][0:1]
Output LVTTL
Clock Output. These outputs provide numerous divide and phase select functions determined by the [1:4]DS[0:1] and [1:4]F[0:1] inputs.
VCCN
PWR
Output Buffer Power. Power supply for each output pair.
VCCQ
PWR
Internal Power. Power supply for the internal circuitry.
GND
PWR
Device Ground.
Block Diagram Description
Phase Frequency Detector and Filter
These two blocks accept signals from the REF inputs (REFA+,
REFA–, REFB+, or REFB–) and the FB inputs (FBKA+, FBKA–,
FBKB+, or FBKB–). Correction information is then generated to
control the frequency of the voltage-controlled oscillator (VCO).
These two blocks, along with the VCO, form a PLL that tracks
the incoming REF signal.
The CY7B993V/994V have a flexible REF and FB input scheme.
These inputs allow the use of either differential LVPECL or
single-ended LVTTL inputs. To configure as single-ended LVTTL
inputs, the complementary pin must be left open (internally pulled
to 1.5V). The other input pin can then be used as an LVTTL input.
The REF inputs are also tolerant to hot insertion.
The REF inputs can be changed dynamically. When changing
from one reference input to the other of the same frequency, the
PLL is optimized to ensure that the clock output period is not less
than the calculated system budget (tMIN = tREF (nominal
reference clock period) – tCCJ (cycle-to-cycle jitter) – tPDEV (Max
period deviation)) while reacquiring the lock.
VCO, Control Logic, Divider, and Phase Generator
The VCO accepts analog control inputs from the PLL filter block.
The FS control pin setting determines the nominal operational
frequency range of the divide by one output (fNOM) of the device.
fNOM is directly related to the VCO frequency. There are two
versions: a low-speed device (CY7B993V) where fNOM ranges
from 12 MHz to 100 MHz, and a high-speed device (CY7B994V)
that ranges from 24 MHz to 200 MHz. The FS setting for each
device is shown in Table 2.
The fNOM frequency is seen on “divide-by-one” outputs. For the
CY7B994V, the upper fNOM range extends from 96 MHz to
200 MHz.
Document #: 38-07127 Rev. *J
Page 6 of 18
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CY7B993V, CY7B994V
Table 4. Output Skew Select Function
Table 2. Frequency Range Select
FS[2]
CY7B993V
CY7B994V
fNOM (MHz)
fNOM (MHz)
Min
Max
Min
Max
12
26
24
52
LOW
Function
Selects
[1:4]F1
Output Skew Function
[1:4]F0
and Bank1 Bank2 Bank3 Bank4
FBF0
Feedback
Bank
MID
24
52
48
100
LOW
LOW
–4tU
–4tU
–8tU
–8tU
–4tU
HIGH
48
100
96
200
LOW
MID
–3tU
–3tu
–7tU
–7tU
NA
LOW
HIGH
–2tU
–2tU
–6tU
–6tU
NA
MID
LOW
–1tU
–1tU
BK1[3]
BK1[3]
NA
Time Unit Definition
Selectable skew is in discrete increments of time unit (tU). The
value of a tU is determined by the FS setting and the maximum
nominal output frequency. The equation to be used to determine
the tU value is as follows:
tU = 1/(fNOM*N)
N is a multiplication factor which is determined by the FS setting.
fNOM is nominal frequency of the device. N is defined in Table 3.
MID
MID
0tU
0tU
0tU
0tU
0tu
MID
HIGH
+1tU
+1tU
BK2[3]
BK2[3]
NA
HIGH
LOW
+2tU
+2tU
+6tU
+6tU
NA
HIGH
MID
+3tU
+3tU
+7tU
+7tU
NA
HIGH
HIGH
+4tU
+4tU
+8tU
+8tU
+4tU
Table 5. Output Divider Function
Table 3. N Factor Determination
Function
Selects
CY7B993V
CY7B994V
N
fNOM (MHz) at
which tU =1.0 ns
N
fNOM (MHz) at
which tU =1.0 ns
LOW
64
15.625
32
31.25
MID
32
31.25
16
62.5
LOW
HIGH
16
62.5
8
125
FS
Divide and Phase Select Matrix
The Divide and Phase Select Matrix is comprised of five
independent banks: four banks of clock outputs and one bank for
feedback. Each clock output bank has two pairs of low-skew,
high-fanout output buffers ([1:4]Q[A:B][0:1]), two phase function
select inputs ([1:4]F[0:1]), two divider function selects
([1:4]DS[0:1]), and one output disable (DIS[1:4]).
The feedback bank has one pair of low-skew, high-fanout output
buffers (QFA[0:1]). One of these outputs may connect to the
selected feedback input (FBK[A:B]±). This feedback bank also
has one phase function select input (FBF0), two divider function
selects FSDS[0:1], and one output disable (FBDIS).
The phase capabilities that are chosen by the phase function
select pins are shown in Table 4. The divide capabilities for each
bank are shown in Table 5.
Output Divider Function
[1:4]DS1 [1:4]DS0
Feedand
and
Bank1 Bank2 Bank3 Bank4 back
FBDS1 FBDS0
Bank
LOW
/1
/1
/1
/1
/1
LOW
MID
/2
/2
/2
/2
/2
LOW
HIGH
/3
/3
/3
/3
/3
MID
LOW
/4
/4
/4
/4
/4
MID
MID
/5
/5
/5
/5
/5
MID
HIGH
/6
/6
/6
/6
/6
HIGH
LOW
/8
/8
/8
/8
/8
HIGH
MID
/10
/10
/10
/10
/10
HIGH
HIGH
/12
/12
/12
/12
/12
Figure 3 illustrates the timing relationship of programmable skew
outputs. All times are measured with respect to REF with the
output used for feedback programmed with 0tU skew. The PLL
naturally aligns the rising edge of the FB input and REF input. If
the output used for feedback is programmed to another skew
position, then the whole tU matrix shifts with respect to REF. For
example, if the output used for feedback is programmed to shift
–8tU, then the whole matrix is shifted forward in time by 8tU. Thus
an output programmed with 8tU of skew is effectively skewed
16tU with respect to REF.
Notes
2. The level to be set on FS is determined by the “nominal” operating frequency (fNOM) of the VCO and Phase Generator. fNOM always appears on an output when
the output is operating in the undivided mode. The REF and FB are at fNOM when the output connected to FB is undivided.
3. BK1, BK2 denotes following the skew setting of Bank1 and Bank2, respectively.
Document #: 38-07127 Rev. *J
Page 7 of 18
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CY7B993V, CY7B994V
U
U
U
t 0 +5t
t 0 +6t
t 0 +7t
U
U
t 0 +4t
t 0 +8t
U
U
t 0 +2t
t 0 +3t
U
t 0 +1t
t0
t 0 – 1t U
t 0 – 2t U
t 0 – 3t U
t 0 – 4t U
t 0 – 5t U
t 0 – 6t U
t 0 – 7t U
t 0 – 8t U
Figure 3. Typical Outputs with FB Connected to a Zero-Skew Output[]
FBInput
REFInput
1F[1:0]
2F[1:0]
3F[1:0]
4F[1:0]
(N/A)
LL
–8tU
(N/A)
LM
–7tU
(N/A)
LH
–6tU
LL
(N/A)
–4tU
LM
(N/A)
–3tU
LH
(N/A)
–2tU
ML
(N/A)
–1tU
MM
MM
0t U
MH
(N/A)
+1t U
HL
(N/A)
+2t U
HM
(N/A)
+3t U
HH
(N/A)
+4t U
(N/A)
HL
+6t U
(N/A)
HM
+7t U
(N/A)
HH
+8t U
Output Disable Description
The feedback Divide and Phase Select Matrix Bank has two
outputs, and each of the four Divide and Phase Select Matrix
Banks have four outputs. The outputs of each bank can be
independently put into a HOLD-OFF or high impedance state.
The combination of the OUTPUT_MODE and DIS[1:4]/FBDIS
inputs determines the clock outputs’ state for each bank. When
the DIS[1:4]/FBDIS is LOW, the outputs of the corresponding
bank is enabled. When the DIS[1:4]/FBDIS is HIGH, the outputs
for that bank is disabled to a high impedance (High Z) or
HOLD-OFF state depending on the OUTPUT_MODE input.
Table 6 defines the disabled output functions.
state, non-inverting outputs are driven to a logic LOW state on
its falling edge. Inverting outputs are driven to a logic HIGH state
on its rising edge. This ensures the output clocks are stopped
without glitch. When a bank of outputs is disabled to High Z state,
the respective bank of outputs go High Z immediately.
Table 6. DIS[1:4]/FBDIS Pin Functionality
OUTPUT_MODE
DIS[1:4]/FBDIS
Output Mode
HIGH/LOW
LOW
ENABLED
HIGH
HIGH
HIGH Z
LOW
HIGH
HOLD-OFF
MID
X
FACTORY TEST
The HOLD-OFF state is intended to be a power saving feature.
An output bank is disabled to the HOLD-OFF state in a maximum
of six output clock cycles from the time when the disable input
(DIS[1:4]/FBDIS) is HIGH. When disabled to the HOLD-OFF
Note
4. FB connected to an output selected for “Zero” skew (i.e., FBF0 = MID or XF[1:0] = MID).
Document #: 38-07127 Rev. *J
Page 8 of 18
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CY7B993V, CY7B994V
INV3 Pin Function
Bank3 has signal invert capability. The four outputs of Bank3 act
as two pairs of complementary outputs when the INV3 pin is
driven LOW. In complementary output mode, 3QA0 and 3QB0
are non-inverting; 3QA1and 3QB1 are inverting outputs. All four
outputs are inverted when the INV3 pin is driven HIGH. When
the INV3 pin is left in MID, the outputs do not invert. Inversion of
the outputs are independent of the skew and divide functions.
Therefore, clock outputs of Bank3 can be inverted, divided, and
skewed at the same time.
Lock Detect Output Description
The LOCK detect output indicates the lock condition of the
integrated PLL. Lock detection is accomplished by comparing
the phase difference between the reference and feedback
inputs. Phase error is declared when the phase difference
between the two inputs is greater than the specified device
propagation delay limit (tPD).
When in the locked state, after four or more consecutive
feedback clock cycles with phase-errors, the LOCK output is
forced LOW to indicate out-of-lock state.
When in the out-of-lock state, 32 consecutive phase-errorless
feedback clock cycles are required to allow the LOCK output to
indicate lock condition (LOCK = HIGH).
If the feedback clock is removed after LOCK has gone HIGH, a
“Watchdog” circuit is implemented to indicate the out-of-lock
condition after a time-out period by deasserting LOCK LOW. This
time out period is based upon a divided down reference clock.
HIGH. When the DIS4 input is driven HIGH in factory test mode,
all clock outputs go to High Z; after the selected reference clock
pin has five positive transitions, all the internal finite state
machines (FSM) are set to a deterministic state. The deterministic state of the state machines depend on the configurations of
the divide selects, skew selects, and frequency select input. All
clock outputs stay in high impedance mode and all FSMs stay in
the deterministic state until DIS4 is deasserted. When DIS4 is
deasserted (with OUTPUT_MODE still at MID), the device
re-enters factory test mode.
Safe Operating Zone
Figure 4 illustrates the operating condition at which the device
does not exceed its allowable maximum junction temperature of
150 °C. Figure 4 shows the maximum number of outputs that can
operate at 185 MHz (with 25 pF load and no air flow) or 200 MHz
(with 10 pF load and no air flow) at various ambient temperatures. At the limit line, all other outputs are configured to
divide-by-two (i.e., operating at 92.5 MHz) or lower frequencies.
The device operates below maximum allowable junction temperature of 150 °C when its configuration (with the specified
constraints) falls within the shaded region (safe operating zone).
Figure 4 shows that at 85 °C, the maximum number of outputs
that can operate at 200 MHz is 6; and at 70 °C, the maximum
number of outputs that can operate at 185 MHz is 16 (with 25 pF
load and 0-m/s air flow).
Figure 4. Typical Safe Operating Zone
Typical Safe Operating Zone
(25-pF Load, 0-m /s air flow )
This assumes that there is activity on the selected REF input. If
there is no activity on the selected REF input then the LOCK
detect pin may not accurately reflect the state of the internal PLL.
The device enters factory test mode when the OUTPUT_MODE
is driven to MID. In factory test mode, the device operates with
its internal PLL disconnected; input level supplied to the
reference input is used in place of the PLL output. In TEST mode
the selected FB input(s) must be tied LOW. All functions of the
device are still operational in factory test mode except the
internal PLL and output bank disables. The OUTPUT_MODE
input is designed to be a static input. Dynamically toggling this
input from LOW to HIGH may temporarily cause the device to go
into factory test mode (when passing through the MID state).
Factory Test Reset
Ambient Temperature (C)
Factory Test Mode Description
100
95
90
85
80
75
70
Safe Operating Zone
65
60
55
50
2
4
6
8
10
12
14
16
18
Num ber of Outputs at 185 MHz
When in factory test mode (OUTPUT_MODE = MID), the device
can be reset to a deterministic state by driving the DIS4 input
Document #: 38-07127 Rev. *J
Page 9 of 18
[+] Feedback
RoboClock
CY7B993V, CY7B994V
Absolute Maximum Conditions
Exceeding maximum ratings may shorten the useful life of the
device. User guidelines are not tested.[5]
Storage Temperature ................................. –50C to +125C
Ambient Temperature with
Power Applied ............................................ –40C to +125C
Supply Voltage to Ground Potential................–0.5V to +4.6V
DC Input Voltage ..................................... –0.3V to VCC+0.5V
Output Current into Outputs (LOW)............................. 40 mA
Static Discharge Voltage........................................... > 1100V
(per MIL-STD-883, Method 3015)
Latch up Current................................................... > ±200 mA
Operating Range
Range
Commercial
Industrial
Ambient Temperature
VCC
0C to +70C
3.3V 10%
–40C to +85C
3.3V 10%
Electrical Characteristics Over the Operating Range
Parameter
Description
Test Conditions
Min
LVTTL Compatible Output Pins (QFA[0:1], [1:4]Q[A:B][0:1], LOCK)
LVTTL HIGH Voltage QFA[0:1], [1:4]Q[A:B][0:1]
VCC = Min, IOH = –30 mA
2.4
VOH
LOCK
IOH = –2 mA, VCC = Min
2.4
LVTTL LOW Voltage QFA[0:1], [1:4]Q[A:B][0:1]
VCC = Min, IOL= 30 mA
–
VOL
–
LOCK
IOL= 2 mA, VCC = Min
IOZ
High impedance State Leakage Current
–100
LVTTL Compatible Input Pins (FBKA±, FBKB±, REFA±, REFB±, FBSEL, REFSEL, FBDIS, DIS[1:4])
LVTTL Input HIGH
FBK[A:B]±, REF[A:B]±
Min < VCC < Max
2.0
VIH
REFSEL, FBSEL, FBDIS,
2.0
DIS[1:4]
VIL
LVTTL Input LOW
FBK[A:B]±, REF[A:B]±
Min < VCC < Max
–0.3
REFSEL, FBSEL, FBDIS, DIS[1:4]
–0.3
LVTTL VIN >VCC
FBK[A:B]±, REF[A:B]±
VCC = GND, VIN = 3.63V
–
II
LVTTL Input HIGH
FBK[A:B]±, REF[A:B]±
VCC = Max, VIN = VCC
–
IlH
Current
REFSEL, FBSEL, FBDIS, DIS[1:4] VIN = VCC
–
LVTTL Input LOW
FBK[A:B]±, REF[A:B]±
VCC = Max, VIN = GND
–500
IlL
Current
REFSEL, FBSEL, FBDIS, DIS[1:4]
–500
Three-level Input Pins (FBF0, FBDS[0:1], [1:4]F[0:1], [1:4]DS[0:1], FS, OUTPUT_MODE(TEST))
Three-level Input HIGH[6]
Min < VCC < Max
0.87*VCC
VIHH
Three-level Input MID[6]
Min < VCC < Max
0.47*VCC
VIMM
[6]
Three-level Input LOW
Min < VCC < Max
–
VILL
Three-level Input
Three-level input pins excl. FBF0 VIN = VCC
–
IIHH
HIGH Current
FBF0
–
Three-level Input
Three-level input pins excl. FBF0 VIN = VCC/2
–50
IIMM
MID Current
FBF0
–100
Three-level Input
Three-level input pins excl. FBF0 VIN = GND
–200
IILL
LOW Current
FBF0
–400
LVDIFF Input Pins (FBK[A:B]±, REF[A:B]±)
Input Differential Voltage
400
VDIFF
Highest Input HIGH Voltage
1.0
VIHHP
Lowest Input LOW Voltage
GND
VILLP
Common Mode Range (crossing voltage)
0.8
VCOM
Max
Unit
–
–
0.5
0.5
100
V
V
V
V
A
VCC + 0.3
VCC + 0.3
V
V
0.8
0.8
100
500
500
–
–
V
V
A
A
A
A
A
–
0.53*VCC
0.13*VCC
200
400
50
100
–
–
V
V
V
A
A
A
A
A
A
VCC
VCC
VCC – 0.4
VCC
mV
V
V
V
Notes
5. Multiple Supplies: The voltage on any input or I/O pin cannot exceed the power pin during power up. Power supply sequencing is NOT required.
6. These inputs are normally wired to VCC, GND, or left unconnected (actual threshold voltages vary as a percentage of VCC). Internal termination resistors hold
the unconnected inputs at VCC/2. If these inputs are switched, the function and timing of the outputs may glitch and the PLL may require an additional tLOCK time
before all data sheet limits are achieved.
Document #: 38-07127 Rev. *J
Page 10 of 18
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RoboClock
CY7B993V, CY7B994V
Electrical Characteristics Over the Operating Range
Parameter
Description
Operating Current
Internal Operating
ICCI
Current
ICCN
Output Current
Dissipation/Pair[8]
(continued)
Test Conditions
VCC = Max, fMAX[7]
CY7B993V
CY7B994V
CY7B993V
CY7B994V
VCC = Max,
CLOAD = 25 pF,
RLOAD = 50 at VCC/2,
fMAX
Min
Max
Unit
–
–
–
–
250
250
40
50
mA
mA
mA
mA
Capacitance
Parameter
CIN
Description
Test Conditions
TA = 25C, f = 1 MHz, VCC = 3.3V
Input Capacitance
Min
Max
Unit
–
5
pF
Switching Characteristics Over the Operating Range[9, 10, 11, 12, 13]
Parameter
CY7B993/4V-2
Description
fIN
Clock Input Frequency
fOUT
Clock Output Frequency
tSKEWPR
Matched-Pair Skew[14, 15]
CY7B993/4V-5
Unit
Min
Typ
Max
Min
Typ
Max
CY7B993V
12
–
100
12
–
100
MHz
CY7B994V
24
–
200
24
–
200
MHz
CY7B993V
12
–
100
12
–
100
MHz
CY7B994V
24
–
200
24
–
200
MHz
–
–
200
–
–
200
ps
Skew[14, 15]
tSKEWBNK
Intrabank
–
–
200
–
–
250
ps
tSKEW0
Output-Output Skew (same frequency and phase, rise to
rise, fall to fall)[14, 15]
–
–
250
–
–
550
ps
tSKEW1
Output-Output Skew (same frequency and phase, other
banks at different frequency, rise to rise, fall to fall)[14, 15]
–
–
250
–
–
650
ps
tSKEW2
Output-Output Skew (invert to nominal of different banks,
compared banks at same frequency, rising edge to falling
edge aligned, other banks at same frequency)[14, 15]
–
–
250
–
–
700
ps
tSKEW3
Output-Output Skew (all output configurations outside of
tSKEW1and tSKEW2)[14, 15]
–
–
500
–
–
800
ps
tSKEWCPR
Complementary Outputs Skew (crossing to crossing,
complementary outputs of the same bank)[14, 15, 16, 17]
–
–
200
–
–
300
ps
tCCJ1-3
Cycle-to-Cycle Jitter (divide by 1 output frequency,
FB = divide by 1, 2, 3)
–
50
150
–
50
150
ps Peak
tCCJ4-12
Cycle-to-Cycle Jitter (divide by 1 output frequency,
FB = divide by 4, 5, 6, 8, 10, 12)
–
50
100
–
50
100
ps Peak
tPD
Propagation Delay, REF to FB Rise
–250
–
250
–500
–
500
ps
Notes
7. ICCI measurement is performed with Bank1 and FB Bank configured to run at maximum frequency (fNOM = 100 MHz for CY7B993V, fNOM = 200 MHz for
CY7B994V), and all other clock output banks to run at half the maximum frequency. FS and OUTPUT_MODE are asserted to the HIGH state.
8. This is dependent upon frequency and number of outputs of a bank being loaded. The value indicates maximum ICCN at maximum frequency and maximum
load of 25 pF terminated to 50 at VCC/2.
9. This is for non-three level inputs.
10. Assumes 25 pF Max load capacitance up to 185 MHz. At 200 MHz the Max load is 10 pF.
11. Both outputs of pair must be terminated, even if only one is being used.
12. Each package must be properly decoupled.
13. AC parameters are measured at 1.5V unless otherwise indicated.
14. Test Load CL= 25 pF, terminated to VCC/2 with 50up to185 MHz and 10 pF load to 200 MHz.
15. SKEW is defined as the time between the earliest and the latest output transition among all outputs for which the same phase delay has been selected when
all outputs are loaded with 25 pF and properly terminated up to 185 MHz. At 200 MHz the max load is 10 pF.
16. Complementary output skews are measured at complementary signal pair intersections.
17. Guaranteed by statistical correlation. Tested initially and after any design or process changes that may affect these parameters.
Document #: 38-07127 Rev. *J
Page 11 of 18
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CY7B993V, CY7B994V
Switching Characteristics Over the Operating Range[9, 10, 11, 12, 13] (continued)
Parameter
TTB
CY7B993/4V-2
Description
Total Timing Budget window (same frequency and phase)[17,
18]
tPDDELTA
Propagation Delay difference between two devices[17]
tREFpwh
REF input (Pulse Width HIGH)[19]
tREFpwl
CY7B993/4V-5
Min
Typ
Max
Min
Typ
Max
–
–
500
–
–
700
Unit
ps
–
–
200
–
–
200
ps
2.0
–
–
2.0
–
–
ns
REF input (Pulse Width LOW)[19]
2.0
–
–
2.0
–
–
ns
tr/tf
Output Rise/Fall Time[20]
0.15
–
2.0
0.15
–
2.0
ns
–
–
tLOCK
PLL Lock Time from Power up
–
10
–
10
ms
tRELOCK1
PLL Relock Time (from same frequency, different phase)
with Stable Power Supply
–
500
–
500
s
tRELOCK2
PLL Relock Time (from different frequency, different phase)
with Stable Power Supply[21]
–
1000
–
1000
s
tODCV
Output duty cycle deviation from 50%[13]
–1.0
1.0
–1.0
1.0
ns
tPWH
Output HIGH time deviation from
50%[22]
–
1.5
–
1.5
ns
tPWL
Output LOW time deviation from 50%[22]
–
2.0
–
2.0
ns
tPDEV
Period deviation when changing from reference to
reference[23]
–
0.025
–
0.025
UI
tOAZ
DIS[1:4]/FBDIS HIGH to output high impedance from
ACTIVE[14, 24]
1.0
10
1.0
10
ns
tOAZ
DIS[1:4]/FBDIS LOW to output ACTIVE from output high
impedance [24, 25]
0.5
14
0.5
14
ns
Figure 5. AC Test Loads and Waveform[26]
3.3V
OUTPUT
For all other outputs
R1 = 100
CL
R2 = 100
CL < 25 pF to 185 MHz
or 10 pF at 200 MHz
(Includes fixture and
probe capacitance)
For LOCK output only
R1 = 910
R2 = 910
CL < 30 pF
R1
R2
(a) LVTTL AC Test Load
3.3V
2.0V
0.8V
GND
< 1 ns
2.0V
0.8V
< 1 ns
(b) TTL Input Test Waveform
Notes
18. TTB is the window between the earliest and the latest output clocks with respect to the input reference clock across variations in output frequency, supply voltage,
operating temperature, input clock edge rate, and process. The measurements are taken with the AC test load specified and include output-output skew, cycle-cycle
jitter, and dynamic phase error. TTB is equal to or smaller than the maximum specified value at a given frequency.
19. Tested initially and after any design or process changes that may affect these parameters.
20. Rise and fall times are measured between 2.0V and 0.8V.
21. fNOM must be within the frequency range defined by the same FS state.
22. tPWH is measured at 2.0V. tPWL is measured at 0.8V.
23. UI = Unit Interval. Examples: 1 UI is a full period. 0.1UI is 10% of period.
24. Measured at 0.5V deviation from starting voltage.
25. For tOZA minimum, CL = 0 pF. For tOZA maximum, CL= 25 pF to 185 MHz or 10 pF to 200 MHz.
26. These figures are for illustrations only. The actual ATE loads may vary.
Document #: 38-07127 Rev. *J
Page 12 of 18
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RoboClock
CY7B993V, CY7B994V
AC Timing Diagrams[13]
tREFpwl
QFA0 or
[1:4]Q[A:B]0
tREFpwh
REF
t SKEWPR
t SKEWPR
t PWH
tPD
t PWL
2.0V
FB
QFA1 or
[1:4]Q[A:B]1
0.8V
tCCJ1-3,4-12
Q
[1:4]QA[0:1]
t SKEWBNK
t SKEWBNK
[1:4]QB[0:1]
REF TO DEVICE 1 and 2
tODCV
tPD
tODCV
Q
FB DEVICE1
tPDELTA
tPDELTA
t SKEW0,1
t SKEW0,1
Other Q
FB DEVICE2
tSKEWCPR
COMPLEMENTARY A
Q
tSKEW2
tSKEW2
COMPLEMENTARY B
crossing
crossing
INVERTED Q
Document #: 38-07127 Rev. *J
Page 13 of 18
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RoboClock
CY7B993V, CY7B994V
Ordering Information
Propagation
Delay (ps)
Max Speed
(MHz)
250
200
CY7B994V-2BBI
100-Ball Thin Ball Grid Array
Industrial, –40 °C to 85 °C
250
200
CY7B994V-2BBIT
100-Ball Thin Ball Grid Array -Tape and Reel
Industrial, –40 °C to 85 °C
500
200
CY7B994V-5BBC
100-Ball Thin Ball Grid Array
Commercial, 0 °C to 70 °C
500
200
CY7B994V-5BBCT
100-Ball Thin Ball Grid Array - Tape and Reel
Commercial, 0 °C to 70 °C
100
CY7B993V-2AXC
100-Pin Thin Quad Flat Pack
Commercial, 0 °C to 70 °C
Ordering Code
Package Type
Operating Range
Pb-free
250
250
100
CY7B993V-2AXCT
100-Pin Thin Quad Flat Pack - Tape and Reel
Commercial, 0 °C to 70 °C
250
100
CY7B993V-2AXI
100-Pin Thin Quad Flat Pack
Industrial, –40 °C to 85 °C
250
200
CY7B994V-2AXC
100-Pin Thin Quad Flat Pack
Commercial, 0 °C to 70 °C
250
200
CY7B994V-2AXCT
100-Pin Thin Quad Flat Pack - Tape and Reel
Commercial, 0 °C to 70 °C
250
200
CY7B994V-2BBXC
100-Ball Thin Ball Grid Array
Commercial, 0 °C to 70 °C
250
200
CY7B994V-2BBXCT
100-Ball Thin Ball Grid Array - Tape and Reel
Commercial, 0 °C to 70 °C
250
200
CY7B994V-2AXI
100-Pin Thin Quad Flat Pack
Industrial, –40 °C to 85 °C
250
200
CY7B994V-2AXIT
100-Pin Thin Quad Flat Pack - Tape and Reel
Industrial, –40 °C to 85 °C
250
200
CY7B994V-2BBXI
100-Ball Thin Ball Grid Array
Industrial, –40 °C to 85 °C
250
200
CY7B994V-2BBXIT
100-Ball Thin Ball Grid Array -Tape and Reel
Industrial, –40 °C to 85 °C
500
100
CY7B993V-5AXC
100-Pin Thin Quad Flat Pack
Commercial, 0 °C to 70 °C
500
100
CY7B993V-5AXCT
100-Pin Thin Quad Flat Pack - Tape and Reel
Commercial, 0 °C to 70 °C
500
100
CY7B993V-5AXI
100-Pin Thin Quad Flat Pack
Industrial, –40 °C to 85 °C
500
100
CY7B993V-5AXIT
100-Pin Thin Quad Flat Pack - Tape and Reel
Industrial, –40 °C to 85 °C
500
200
CY7B994V-5AXC
100-Pin Thin Quad Flat Pack
Commercial, 0 °C to 70 °C
500
200
CY7B994V-5AXCT
100-Pin Thin Quad Flat Pack - Tape and Reel
Commercial, 0 °C to 70 °C
500
200
CY7B994V-5BBXI
100-Ball Thin Ball Grid Array
Industrial, –40 °C to 85 °C
500
200
CY7B994V-5BBXIT
100-Ball Thin all Grid Array - Tape and Reel
Industrial, –40 °C to 85 °C
500
200
CY7B994V-5AXI
100-Pin Thin Quad Flat Pack
Industrial, –40 °C to 85 °C
500
200
CY7B994V-5AXIT
100-Pin Thin Quad Flat Pack - Tape and Reel
Industrial, –40 °C to 85 °C
Ordering Code Definitions
CY 7B99XV - X
XX
X
X
T
T = Tape and Reel, Blank = Standard
Temperature Range
C = Commercial = 0 °C to 70 °C
I = Industrial = –40 °C to 85 °C
X = Pb-free indicator (blank = leaded)
Package Type: A = Thin Quad Flat Pack; BB = Thin Ball Grid Array
Propagation delay: 2 = 250 ps max; 5 = 500 ps max
Base part number
Company ID: CY = Cypress
Document #: 38-07127 Rev. *J
Page 14 of 18
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RoboClock
CY7B993V, CY7B994V
Package Diagrams
Figure 6. 100-Pin Thin Plastic Quad Flat Pack (TQFP) A100
51-85048 *E
Document #: 38-07127 Rev. *J
Page 15 of 18
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RoboClock
CY7B993V, CY7B994V
Package Diagrams (continued)
Figure 7. 100-Ball Thin Ball Grid Array (11 x 11 x 1.4 mm) BB100
51-85107 *C
Document #: 38-07127 Rev. *J
Page 16 of 18
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RoboClock
CY7B993V, CY7B994V
Document History Page
Document Title: RoboClock CY7B993V/CY7B994V High speed Multi Phase PLL Clock Buffer
Document Number: 38-07127
Orig. of
Change
Submission
Date
109957
SZV
12/16/01
Changed from Spec number: 38-00747 to 38-07127
114376
CTK
05/06/02
Added three industrial packages
Revision
ECN
**
*A
Description of Change
*B
116570
HWT
09/04/02
Added TTB Features
*C
122794
RBI
12/14/02
Power up requirements to operating conditions information
*D
123694
RGL
03/04/03
Added Min Fout value of 12 MHz for CY7B993V and 24 MHz for CY7B994V to
switching characteristics table
Corrected prop delay limit parameter from (tPDSL,M,H) to tPD in the Lock Detect
Output Description paragraph
*E
128462
RGL
07/29/03
Added clock input frequency (fin) specifications in the switching characteristics
table
*F
391560
RGL
See ECN
Added Lead-free devices
Added typical values for jitter
*G
2896548
KVM
03/19/10
Changed “Lead-Free” to “Pb-Free” in Ordering Information table.
Removed obsolete part numbers: CY7B993V-2AC, CY7B993V-2ACT,
CY7B993V-2AI, CY7B993V-2AIT, CY7B994V-2AC, CY7B994V-2ACT,
CY7B994V-2BBCT, CY7B994V-2AI, CY7B994V-2AIT, CY7B993V-5AC,
CY7B993V-5ACT, CY7B993V-5AI, CY7B993V-5AIT, CY7B994V-5AC,
CY7B994V-5ACT, CY7B994V-5BBI, CY7B994V-5BBIT, CY7B994V-5AI,
CY7B994V-5AIT and CY7B993V-2AXIT
Added numerical temperature ranges to Ordering Information table
*H
3055192
CXQ
10/11/2010
*I
3076912
CXQ
11/02/2010
Updated Ordering Code Definitions.
*J
3240908
CXQ
04/26/2011
Updated minimum Storage Temperature and 100-pin TQFP package diagram
Document #: 38-07127 Rev. *J
Removed Part number CY7B994V-5BBXC and CY7B994V-5BBXCT.
Added Ordering Code Definitions.
Page 17 of 18
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RoboClock
CY7B993V, CY7B994V
Sales, Solutions, and Legal Information
Worldwide Sales and Design Support
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closest to you, visit us at Cypress Locations.
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© Cypress Semiconductor Corporation, 2001-2011. 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.
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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 #: 38-07127 Rev. *J
®
Revised April 26, 2011
Page 18 of 18
®
TTB™ is a trademark and RoboClock and PSoC are the registered trademarks of Cypress Semiconductor Corp. All other trademarks or registered trademarks referenced herein are property of the
respective corporations.
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