IDT IDT5T2110_2

IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
IDT5T2110
2.5V ZERO DELAY PLL
DIFFERENTIAL CLOCK
DRIVER TERACLOCK™
FEATURES:
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DESCRIPTION:
2.5 VDD
6 differential outputs
Low skew: 100ps all outputs
Selectable positive or negative edge synchronization
Tolerant of spread spectrum input clock
Synchronous output enable
Selectable inputs
Input frequency: 4.17MHz to 250MHz
Output frequency: 12.5MHz to 250MHz
1.8V / 2.5V LVTTL: up to 250MHz
HSTL / eHSTL: up to 250MHz
Hot insertable and over-voltage tolerant inputs
3-level inputs for selectable interface
3-level inputs for feedback divide selection with multiply ratios
of(1-6, 8, 10, 12)
Selectable HSTL, eHSTL, 1.8V/2.5V LVTTL, or LVEPECL input
interface
Selectable differential or single-ended inputs and six differential outputs
PLL bypass for DC testing
External differential feedback, internal loop filter
Low Jitter: <75ps cycle-to-cycle
Power-down mode
Lock indicator
Available in BGA and VFQFPN package
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The IDT5T2110 is a 2.5V PLL differential clock driver intended for high
performance computing and data-communications applications. The
IDT5T2110 has six differential outputs in six banks, including a dedicated
differential feedback. The redundant input capability allows for a smooth
change over to a secondary clock source when the primary clock source
is absent.
The feedback bank allows divide-by-functionality from 1 to 12 through
the use of the DS[1:0] inputs. This provides the user with frequency
multiplication 1 to 12 without using divided outputs for feedback. Each output
bank also allows for a divide-by functionality of 2 or 4.
The 5T2110 features a user-selectable, single-ended or differential input to
six differential outputs. The differential clock driver also acts as a translator from
a differential HSTL, eHSTL, 1.8V/2.5V LVTTL, LVEPECL, or single-ended
1.8V/2.5V LVTTL input to HSTL, eHSTL, or 1.8V/2.5V LVTTL outputs.
Selectable interface is controlled by 3-level input signals that may be hard-wired
to appropriate high-mid-low levels. The differential outputs can be synchronously enabled/disabled.
Furthermore, when PE is held high, all the outputs are synchronized with
the positive edge of the REF clock input. When PE is held low, all the outputs
are synchronized with the negative edge of REF.
FUNCTIONAL BLOCK DIAGRAM
TxS
1sOE
1Q
Divide
Select
OMODE
1Q
1F2:1
PD
PE
FS
LOCK
2sOE
2Q
Divide
Select
PLL_EN
FB
3
FB/
VREF2
2F2:1
3
DS1:0
3sOE
3Q
Divide
Select
PLL
3Q
0
REF0
REF0/
VREF0
2Q
/N
3F2:1
4sOE
0
1
RxS
4Q
Divide
Select
4Q
1
4F2:1
REF1
REF1/
VREF1
REF_SEL
Divide
Select
5sOE
5Q
5Q
5F2:1
Divide
Select
QFB
QFB
The IDT logo is a registered trademark of Integrated Device Technology, Inc.
INDUSTRIAL TEMPERATURE RANGE
FBF2:1
NOVEMBER 2004
1
c
2004
Integrated Device Technology, Inc.
DSC 5982/29
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
PIN CONFIGURATION
1
2
3
4
5
6
7
8
9
10
11
12
A
VDD
1F2
1sOE
1Q
1Q
GND
GND
2Q
2Q
2sOE
2F2
VDDQ
A
B
VDD
VDD
VDD
NC
1F1
GND
GND
2F1
NC
VDDQ
VDDQ
3F2
B
OMODE VDD
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
3sOE
C
C
D
REF_
SEL
GND
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
NC
3Q
D
E
REF1
REF1
/VREF1
NC
VDD
GND
GND
GND
GND
VDDQ
VDDQ
3F1
3Q
E
F
REF0
REF0
/VREF0
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
VDDQ
F
G
FB
FB
/VREF2
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
VDDQ
G
H
PD
PLL_
EN
PE
VDD
GND
GND
GND
GND
VDDQ
VDDQ
4F1
4Q
H
J
RxS
TxS
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
NC
4Q
J
K
LOCK
VDD
VDD
VDD
GND
GND
GND
GND
VDDQ
VDDQ
VDDQ
4sOE
K
L
VDD
VDD
FS
NC
FBF1
GND
GND
5F1
NC
VDDQ
VDDQ
4F2
L
M
DS1
DS0
FBF2
QFB
QFB
GND
GND
5Q
5Q
5sOE
5F2
VDDQ
M
1
2
3
4
5
6
7
8
9
10
11
12
BGA
TOP VIEW
2
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
VDDQ
2sOE
2F 2
53
52
VDD
59
54
1F 1
60
VDDQ
1Q
61
55
1Q
62
2Q
VDDQ
63
56
VDDQ
64
2Q
1sOE
65
57
1F 2
66
2F 1
VDD
67
58
OMODE
68
PIN CONFIGURATION
REF_SEL
1
51
VDD
VDD
2
50
3F 2
REF1
3
49
3sOE
REF1/VREF1
4
48
VDDQ
REF0
5
47
VDDQ
REF0/VREF0
6
46
3Q
FB
7
45
3Q
FB/VREF2
8
44
3F 1
VDD
9
43
VDD
PE
10
42
4F 1
PD
11
41
4Q
PLL_EN
12
40
4Q
VDD
13
39
VDDQ
RxS
14
38
VDDQ
TxS
15
37
4sOE
LOCK
16
36
4F 2
VDD
17
35
VDD
30
31
32
33
34
5Q
VDDQ
VDDQ
5sOE
5F 2
QFB
29
25
QFB
5Q
24
28
23
VDDQ
5F 1
22
VDDQ
27
21
FBF2
VDD
20
FS
FBF1
19
DS0
26
18
DS1
GND
VFQFPN
TOP VIEW
3
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
ABSOLUTE MAXIMUM RATINGS(1)
Symbol
Description
INDUSTRIAL TEMPERATURE RANGE
CAPACITANCE(TA = +25°C, f = 1MHz, VIN = 0V)
Max
Unit
VDDQ, VDD Power Supply Voltage(2)
–0.5 to +3.6
V
VI
Input Voltage
–0.5 to +3.6
V
VO
Output Voltage
–0.5 to VDDQ +0.5
V
VREF
Reference Voltage(3)
–0.5 to +3.6
V
TJ
Junction Temperature
150
°C
TSTG
Storage Temperature
–65 to +165
°C
Parameter
Description
Min.
Typ.
Max.
Unit
CIN
Input Capacitance
COUT
Output Capacitance
2.5
3
3.5
pF
—
6.3
7
pF
NOTE:
1. Capacitance applies to all inputs except RxS, TxS, nF[2:1], FBF[2:1],and DS[1:0].
NOTES:
1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause
permanent damage to the device. This is a stress rating only and functional operation
of the device at these or any other conditions above those indicated in the operational
sections of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect reliability.
2. VDDQ and VDD internally operate independently. No power sequencing requirements
need to be met.
3. Not to exceed 3.6V.
RECOMMENDED OPERATING RANGE
Symbol
TA
VDD(1)
Description
Ambient Operating Temperature
Internal Power Supply Voltage
HSTL Output Power Supply Voltage
Extended HSTL and 1.8V LVTTL Output Power Supply Voltage
2.5V LVTTL Output Power Supply Voltage
Termination Voltage
VDDQ(1)
VT
Min.
–40
2.3
1.4
1.65
Typ.
+25
2.5
1.5
1.8
VDD
VDDQ / 2
Max.
+85
2.7
1.6
1.95
Unit
°C
V
V
V
V
V
NOTE:
1. All power supplies should operate in tandem. If VDD or VDDQ is at maximum, then VDDQ or VDD (respectively) should be at maximum, and vice-versa.
PIN DESCRIPTION
Symbol
REF[1:0]
REF[1:0]/
VREF[1:0]
I/O
I
I
Type
Adjustable(1)
Adjustable(1)
FB
I
Adjustable(1)
FB/VREF2
I
Adjustable(1)
Description
Clock input. REF[1:0] is the "true" side of the differential clock input. If operating in single-ended mode, REF[1:0] is the clock input.
Complementary clock input. REF[1:0]/VREF[1:0] is the "complementary" side of REF[1:0] if the input is in differential mode. If operating
in single-ended mode, REF[1:0]/VREF[1:0] is left floating. For single-ended operation in differential mode, REF[1:0]/VREF[1:0] should be set
to the desired toggle voltage for REF[1:0]:
2.5V LVTTL
VREF = 1250mV (SSTL2 compatible)
1.8V LVTTL, eHSTL
VREF = 900mV
HSTL
VREF = 750mV
LVEPECL
VREF = 1082mV
Clock input. FB is the "true" side of the differential feedback clock input. If operating in single-ended mode, FB is the differential feedback
clock input.
Complementary feedback clock input. FB/VREF2 is the "complementary" side of FB if the input is in differential mode. If operating in singleended mode, FB/VREF2 is left floating. For single-ended operation in differential mode, FB/VREF2 should be set to the desired toggle voltage
for FB:
2.5V LVTTL
VREF = 1250mV (SSTL2 compatible)
1.8V LVTTL, eHSTL
VREF = 900mV
HSTL
VREF = 750mV
LVEPECL
VREF = 1082mV
NOTE:
1. Inputs are capable of translating the following interface standards. User can select between:
Single-ended 2.5V LVTTL levels
Single-ended 1.8V LVTTL levels
or
Differential 2.5V/1.8V LVTTL levels
Differential HSTL and eHSTL levels
Differential LVEPECL levels
4
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
PIN DESCRIPTION, CONTINUED
Symbol
REF_SEL
nsOE
I/O
I
I
Type
LVTTL(1)
LVTTL(1)
QFB
QFB
nQ
nQ
RxS
TxS
O
O
O
O
I
I
Adjustable(2)
Adjustable(2)
Adjustable(2)
Adjustable(2)
3-Level(3)
3-Level(3)
PE
I
LVTTL(1)
nF[2:1]
I
LVTTL(1)
Description
Reference clock select. When LOW, selects REF0 and REF0/VREF0. When HIGH, selects REF1 and REF1/VREF1.
Synchronous output enable. When nsOE is HIGH, nQ and nQ are synchronously stopped. OMODE selects whether the outputs are
gated LOW/HIGH or tri-stated. When OMODE is HIGH, PE determines the level at which the outputs stop. When PE is LOW/HIGH,
the nQ is stopped in a HIGH/LOW state, while the nQ is stopped at a LOW/HIGH state. When OMODE is LOW, the outputs are tristated. Set nsOE LOW for normal operation.
Feedback clock output
Complementary feedback clock output
Clock outputs
Complementary clock outputs
Selects single-ended 2.5V LVTTL (HIGH), 1.8V LVTTL (MID) REF clock input or differential (LOW) REF clock input
Sets the drive strength of the output drivers and feedback inputs to be 2.5V LVTTL (HIGH), 1.8V LVTTL (MID) or eHSTL/HSTL (LOW)
compatible. Used in conjuction with VDDQ to set the interface levels.
Selectable positive or negative edge control. When LOW/HIGH the outputs are synchronized with the negative/positive edge of the reference
clock (has internal pull-up).
Function select inputs for divide-by-2, divide-by-4, zero delay, or invert on each bank. (See Control Summary table.)
FBF[2:1]
I
LVTTL(1)
Function select inputs for divide-by-2, divide-by-4, zero delay, or invert on the feedback bank (See Control Summary table)
FS
I
LVTTL(1)
Selects appropriate oscillator circuit based on anticipated frequency range (See VCO Frequency Range Select table)
DS[1:0]
I
3-Level(3)
3-level inputs for feedback input divider selection (See Divide Selection table)
I
LVTTL(1)
PLL enable/disable control. Set LOW for normal operation. When PLL_EN is HIGH, the PLL is disabled and REF[1:0] goes to all outputs.
PD
I
LVTTL(1)
LOCK
O
LVTTL
OMODE
I
LVTTL(1)
Power down control. When PD is LOW, the inputs are disabled and internal switching is stopped. OMODE selects whether the outputs
are gated LOW/HIGH or tri-stated. When OMODE is HIGH, PE determines the level at which the outputs stop. When PE is LOW/
HIGH, the nQ and QFB are stopped in a HIGH/LOW state, while the nQ and QFB are stopped in a LOW/HIGH state. When OMODE
is LOW, the outputs are tri-stated. Set PD HIGH for normal operation.
PLL lock indication signal. HIGH indicates lock. LOW indicates that the PLL is not locked and outputs may not be synchronized to the
inputs. The output will be 2.5V LVTTL. (For more information on application specific use of the LOCK pin, please see AN237.)
Output disable control. Determines the outputs' disable state. Used in conjunction with nsOE and PD. (See Output Enable/Disable and
Powerdown tables.)
PLL_EN
VDDQ
PWR
Power supply for output buffers. When using 2.5V LVTTL, VDDQ should be connected to VDD.
VDD
GND
PWR
PWR
Power supply for phase locked loop, lock output, inputs, and other internal circuitry
Ground
NOTES:
1. Pins listed as LVTTL inputs will accept 2.5V signals under all conditions. If the output is operating at 1.8V or 1.5V, the LVTTL inputs will accept 1.8V LVTTL signals as well.
2. Outputs are user selectable to drive 2.5V, 1.8V LVTTL, eHSTL, or HSTL interface levels when used with the appropriate VDDQ voltage.
3. 3-level inputs are static inputs and must be tied to VDD or GND or left floating. These inputs are not hot-insertable or over voltage tolerant.
OUTPUT ENABLE/DISABLE
nsOE
OMODE
Output
L
X
Normal Operation
VCO FREQUENCY RANGE SELECT
FS(1)
Min.
Max.
Unit
H
L
Tri-State
LOW
50
125
MHz
H
H
Gated(1)
HIGH
100
250
MHz
NOTE:
1. The level to be set on FS is determined by the nominal operating frequency of the
VCO. The VCO frequency (FNOM) always appears at nQ and nQ outputs when they
are operated in their undivided modes. The frequency appearing at the REF[1:0] and
REF[1:0] /VREF[1:0] and FB and FB/VREF2 inputs will be FNOM when the QFB and QFB
are undivided and DS[1:0] = MM. The frequency of REF[1:0] and REF[1:0] /VREF[1:0]
and FB and FB/VREF2 inputs will be FNOM/2 or FNOM/4 when the part is configured for
frequency multiplication by using a divided QFB and QFB and setting DS[1:0] = MM.
Using the DS[1:0] inputs allows a different method for frequency multiplication (see
Divide Selection table).
NOTE:
1. PE determines the level at which the outputs stop. When PE is LOW/HIGH, the nQ
is stopped in a HIGH/LOW state while the nQ is stopped at a LOW/HIGH state.
POWERDOWN
PD
OMODE
Output
H
X
Normal Operation
L
L
Tri-State
L
H
Gated(1)
NOTE:
1. PE determines the level at which the outputs stop. When PE is LOW/HIGH, the nQ
and QFB are stopped in a HIGH/LOW state, while the nQ and QFB are stopped in a
LOW/HIGH state.
5
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
EXTERNAL DIFFERENTIAL FEEDBACK
By providing a dedicated external differential feedback, the IDT5T2110
gives users flexibility with regard to divide selection. The FB and FB/
VREF2 signals are compared with the input REF[1:0] and REF[1:0]/VREF[1:0]
signals at the phase detector in order to drive the VCO. Phase differences cause the VCO of the PLL to adjust upwards or downwards
accordingly.
An internal loop filter moderates the response of the VCO to the
phase detector. The loop filter transfer function has been chosen to
provide minimal jitter (or frequency variation) while still providing accurate responses to input frequency changes.
DIVIDE SELECTION TABLE
DS [1:0]
Divide-by-n
Permitted Output Divide-by-n connected to FB and FB/VREF2(1)
LL
2
1, 2
LM
3
1
LH
4
1, 2
ML
5
1, 2
MM
1
1, 2, 4
MH
6
1, 2
HL
8
1
HM
10
1
HH
12
1
NOTE:
1. Permissible output division ratios connected to FB and FB/VREF2. The frequencies of the REF[1:0] and REF[1:0]/VREF[1:0] inputs will be FNOM/N when the parts are configured for
frequency multiplication by using an undivided output for FB and FB/VREF2 and setting DS[1:0] to N (N = 1-6, 8, 10, 12).
CONTROL SUMMARY TABLE FOR ALL
OUTPUTS
nF2/FBF2
nF1/FBF1
Output Skew
L
L
Divide by 2
L
H
Zero Delay
H
L
Inverted
H
H
Divide by 4
6
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
INPUT/OUTPUT SELECTION(1)
Input
Output
Input
Output
2.5V LVTTL SE
1.8V LVTTL SE
2.5V LVTTL
2.5V LVTTL SE
1.8V LVTTL SE
eHSTL
2.5V LVTTL DSE
1.8V LVTTL DSE
2.5V LVTTL DSE
1.8V LVTTL DSE
LVEPECL DSE
eHSTL DSE
LVEPECL DSE
eHSTL DSE
HSTL DSE
2.5V LVTTL DIF
HSTL DSE
2.5V LVTTL DIF
1.8V LVTTL DIF
LVEPECL DIF
1.8V LVTTL DIF
LVEPECL DIF
eHSTL DIF
HSTL DIF
eHSTL DIF
HSTL DIF
2.5V LVTTL SE
1.8V LVTTL SE
2.5V LVTTL SE
1.8V LVTTL SE
1.8V LVTTL
2.5V LVTTL DSE
1.8V LVTTL DSE
2.5V LVTTL DSE
1.8V LVTTL DSE
LVEPECL DSE
eHSTL DSE
LVEPECL DSE
eHSTL DSE
HSTL DSE
2.5V LVTTL DIF
HSTL DSE
2.5V LVTTL DIF
1.8V LVTTL DIF
LVEPECL DIF
eHSTL DIF
1.8V LVTTL DIF
LVEPECL DIF
HSTL
eHSTL DIF
HSTL DIF
HSTL DIF
NOTE:
1. The INPUT/OUTPUT SELECTION Table describes the total possible combinations of input and output interfaces. Single-Ended (SE) inputs in a single-ended mode require the
REF[1:0]/VREF[1:0] and FB/VREF2 pins to be left floating. Differential Single-Ended (DSE) is for single-ended operation in differential mode, requiring VREF[1:0] and VREF2. Differential
(DIF) inputs are used only in differential mode.
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE
Symbol
VIHH
VIMM
VILL
Parameter
Input HIGH Voltage Level(1)
Input MID Voltage Level(1)
Input LOW Voltage Level(1)
I3
3-Level Input DC Current
(RxS, TxS, DS[1:0])
Input Pull-Up Current (PE)
IPU
Test Conditions
3-Level Inputs Only
3-Level Inputs Only
3-Level Inputs Only
HIGH Level
VIN = VDD
VIN = VDD/2
MID Level
VIN = GND
LOW Level
VDD = Max., VIN = GND
Min.
VDD – 0.4
VDD/2 – 0.2
—
—
–50
–200
–100
Max
—
VDD/2 + 0.2
0.4
200
+50
—
—
Unit
V
V
V
µA
µA
NOTE:
1. These inputs are normally wired to VDD, GND, or left floating. Internal termination resistors bias unconnected inputs to VDD/2. If these inputs are switched dynamically after powerup,
the function and timing of the outputs may be glitched, and the PLL may require additional tLOCK time before all datasheet limits are achieved.
7
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE FOR HSTL(1)
Symbol
Parameter
Input Characteristics
IIH
Input HIGH Current
IIL
Input LOW Current
VIK
Clamp Diode Voltage
VIN
DC Input Voltage
VDIF
DC Differential Voltage(2,8)
VCM
DC Common Mode Input Voltage(3,8)
VIH
DC Input HIGH(4,5,8)
VIL
DC Input LOW(4,6,8)
Single-Ended Reference Voltage(4,8)
VREF
Output Characteristics
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
VOX
Qn/Qn and FB/FB Output Crossing Point
Test Conditions
VDD = 2.7V
VI = VDDQ/GND
VDD = 2.7V
VI = GND/VDDQ
VDD = 2.3V, IIN = -18mA
IOH = -8mA
IOH = -100µA
IOL = 8mA
IOL = 100µA
Min.
Typ.(7)
Max
Unit
—
—
—
- 0.3
0.2
680
VREF + 100
—
—
—
—
- 0.7
µA
750
±5
±5
- 1.2
+3.6
—
900
—
VREF - 100
—
VDDQ/2
—
—
0.4
0.1
VDDQ/2 + 150
VDDQ - 0.4
VDDQ - 0.1
—
—
VDDQ/2 - 150
750
V
V
V
mV
mV
mV
mV
V
V
mV
NOTES:
1. See RECOMMENDED OPERATING RANGE table.
2. VDIF specifies the minimum input differential voltage (VTR - VCP) required for switching where VTR is the "true" input level and VCP is the "complement" input level. Differential mode
only. The DC differential voltage must be maintained to guarantee retaining the existing HIGH or LOW input. The AC differential voltage must be achieved to guarantee switching
to a new state.
3. VCM specifies the maximum allowable range of (VTR + VCP) /2. Differential mode only.
4. For single-ended operation, in differential mode, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0].
5. Voltage required to maintain a logic HIGH, single-ended operation in differential mode.
6. Voltage required to maintain a logic LOW, single-ended operation in differential mode.
7. Typical values are at VDD = 2.5V, VDDQ = 1.5V, +25°C ambient.
8. The reference clock input is capable of HSTL, eHSTL, LVEPECL, 1.8V or 2.5V LVTTL operation independent of the device output. (See Input/Output Selection table.)
8
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
POWER SUPPLY CHARACTERISTICS FOR HSTL OUTPUTS(1)
Symbol
IDDQ
Parameter
Quiescent VDD Power Supply Current(3)
IDDQQ
Quiescent VDDQ Power Supply Current(3)
IDDPD
IDDD
ITOT
Power Down Current
Dynamic VDD Power Supply
Current per Output
Dynamic VDDQ Power Supply
Current per Output
Total Power VDD Supply Current(4)
ITOTQ
Total Power VDDQ Supply Current(4)
IDDDQ
Test Conditions(2)
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDD = Max., PD = LOW, nSOE = LOW, PLL_EN = HIGH
VDD = Max., VDDQ = Max., CL = 0pF
Typ.
15
Max
25
Unit
mA
0.7
50
µA
0.8
13
3
20
mA
µA/MHz
VDD = Max., VDDQ = Max., CL = 0pF
16
25
µA/MHz
VDDQ = 1.5V, FVCO = 100MHz, CL = 15pF
VDDQ = 1.5V, FVCO = 250MHz, CL = 15pF
VDDQ = 1.5V, FVCO = 100MHz, CL = 15pF
VDDQ = 1.5V, FVCO = 250MHz, CL = 15pF
35
55
45
80
55
85
70
120
mA
mA
NOTES:
1. These power consumption characteristics are for all the valid input interfaces and cover the worst case input and output interface combinations.
2. The termination resistors are excluded from these measurements.
3. If the differential input interface is used, the true input is held LOW and the complementary input is held HIGH.
4. FS = HIGH.
DIFFERENTIAL INPUT AC TEST CONDITIONS FOR HSTL
Symbol
Parameter
VDIF
Input Signal Swing(1)
VX
Differential Input Signal Crossing Point
VTHI
Input Timing Measurement Reference Level(3)
tR, tF
Input Signal Edge Rate
(2)
(4)
Value
Units
1
V
750
mV
Crossing Point
V
1
V/ns
NOTES:
1. The 1V peak-to-peak input pulse level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VDIF (AC)
specification under actual use conditions.
2. A 750mV crossing point level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VX specification under
actual use conditions.
3. In all cases, input waveform timing is marked at the differential cross-point of the input signals.
4. The input signal edge rate of 1V/ns or greater is to be maintained in the 20% to 80% range of the input waveform.
9
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE FOR eHSTL(1)
Symbol
Parameter
Input Characteristics
IIH
Input HIGH Current
IIL
Input LOW Current
VIK
Clamp Diode Voltage
VIN
DC Input Voltage
VDIF
DC Differential Voltage(2,8)
VCM
DC Common Mode Input Voltage(3,8)
VIH
DC Input HIGH(4,5,8)
VIL
DC Input LOW(4,6,8)
Single-Ended Reference Voltage(4,8)
VREF
Output Characteristics
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
VOX
Qn/Qn and FB/FB Output Crossing Point
Test Conditions
VDD = 2.7V
VI = VDDQ/GND
VDD = 2.7V
VI = GND/VDDQ
VDD = 2.3V, IIN = -18mA
IOH = -8mA
IOH = -100µA
IOL = 8mA
IOL = 100µA
Min.
Typ.(7)
Max
Unit
—
—
—
- 0.3
0.2
800
VREF + 100
—
—
—
—
- 0.7
µA
900
±5
±5
- 1.2
+3.6
—
1000
—
VREF - 100
—
V
V
V
mV
mV
mV
mV
VDDQ/2
—
—
0.4
0.1
VDDQ/2 + 150
V
V
V
V
mV
VDDQ - 0.4
VDDQ - 0.1
—
—
VDDQ/2 - 150
900
NOTES:
1. See RECOMMENDED OPERATING RANGE table.
2. VDIF specifies the minimum input differential voltage (VTR - VCP) required for switching where VTR is the "true" input level and VCP is the "complement" input level. Differential mode
only. The DC differential voltage must be maintained to guarantee retaining the existing HIGH or LOW input. The AC differential voltage must be achieved to guarantee switching
to a new state.
3. VCM specifies the maximum allowable range of (VTR + VCP) /2. Differential mode only.
4. For single-ended operation, in a differential mode, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0].
5. Voltage required to maintain a logic HIGH, single-ended operation in differential mode.
6. Voltage required to maintain a logic LOW, single-ended operation in differential mode.
7. Typical values are at VDD = 2.5V, VDDQ = 1.8V, +25°C ambient.
8. The reference clock input is capable of HSTL, eHSTL, LVEPECL, 1.8V or 2.5V LVTTL operation independent of the device output. (See Input/Output Selection table.)
POWER SUPPLY CHARACTERISTICS FOR eHSTL OUTPUTS(1)
Symbol
IDDQ
Parameter
Quiescent VDD Power Supply Current(3)
IDDQQ
Quiescent VDDQ Power Supply Current(3)
IDDPD
IDDD
ITOT
Power Down Current
Dynamic VDD Power Supply
Current per Output
Dynamic VDDQ Power Supply
Current per Output
Total Power VDD Supply Current(4)
ITOTQ
Total Power VDDQ Supply Current(4)
IDDDQ
Test Conditions(2)
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDD = Max., PD = LOW, nSOE = LOW, PLL_EN = HIGH
VDD = Max., VDDQ = Max., CL = 0pF
Typ.
15
Max
25
Unit
mA
1.7
50
µA
0.8
13
3
20
mA
µA/MHz
VDD = Max., VDDQ = Max., CL = 0pF
20
30
µA/MHz
VDDQ = 1.8V, FVCO = 100MHz, CL = 15pF
VDDQ = 1.8V, FVCO = 250MHz, CL = 15pF
VDDQ = 1.8V, FVCO = 100MHz, CL = 15pF
VDDQ = 1.8V, FVCO = 250MHz, CL = 15pF
35
55
50
115
55
85
75
175
mA
NOTES:
1. These power consumption characteristics are for all the valid input interfaces and cover the worst case input and output interface combinations.
2. The termination resistors are excluded from these measurements.
3. If the differential input interface is used, the true input is held LOW and the complementary input is held HIGH.
4. FS = HIGH
10
mA
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
DIFFERENTIAL INPUT AC TEST CONDITIONS FOR eHSTL
Symbol
Parameter
VDIF
Input Signal Swing(1)
VX
Differential Input Signal Crossing Point
VTHI
Input Timing Measurement Reference Level(3)
tR, tF
Input Signal Edge Rate
(2)
(4)
Value
Units
1
V
900
mV
Crossing Point
V
1
V/ns
NOTES:
1. The 1V peak-to-peak input pulse level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VDIF (AC)
specification under actual use conditions.
2. A 900mV crossing point level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VX specification under
actual use conditions.
3. In all cases, input waveform timing is marked at the differential cross-point of the input signals.
4. The input signal edge rate of 1V/ns or greater is to be maintained in the 20% to 80% range of the input waveform.
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE FOR
LVEPECL(1)
Symbol
Parameter
Input Characteristics
IIH
Input HIGH Current
IIL
Input LOW Current
VIK
Clamp Diode Voltage
VIN
DC Input Voltage
VCM
DC Common Mode Input Voltage(3,5)
VREF
Single-Ended Reference Voltage(4,5)
VIH
DC Input HIGH
VIL
DC Input LOW
Test Conditions
VDD = 2.7V
VI = VDDQ/GND
VDD = 2.7V
VI = GND/VDDQ
VDD = 2.3V, IIN = -18mA
Min.
Typ.(2)
Max
Unit
—
—
—
- 0.3
915
—
1275
555
—
—
- 0.7
—
1082
1082
—
—
±5
±5
- 1.2
3.6
1248
—
1620
875
µA
V
V
mV
mV
mV
mV
NOTES:
1. See RECOMMENDED OPERATING RANGE table.
2. Typical values are at VDD = 2.5V, +25°C ambient.
3. VCM specifies the maximum allowable range of (VTR + VCP) /2. Differential mode only.
4. For single-ended operation while in differential mode, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0].
5. The reference clock input is capable of HSTL, eHSTL, LVEPECL, 1.8V or 2.5V LVTTL operation independent of the device output. (See Input/Output Selection table.)
11
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
DIFFERENTIAL INPUT AC TEST CONDITIONS FOR LVEPECL
Symbol
Parameter
Value
Units
VDIF
Input Signal Swing
(1)
732
mV
VX
Differential Input Signal Crossing Point(2)
1082
mV
VTHI
Input Timing Measurement Reference Level(3)
tR, tF
Input Signal Edge Rate(4)
Crossing Point
V
1
V/ns
NOTES:
1. The 732mV peak-to-peak input pulse level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VDIF (AC)
specification under actual use conditions.
2. A 1082mV crossing point level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VX specification
under actual use conditions.
3. In all cases, input waveform timing is marked at the differential cross-point of the input signals.
4. The input signal edge rate of 1V/ns or greater is to be maintained in the 20% to 80% range of the input waveform.
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE FOR 2.5V
LVTTL(1)
Symbol
Parameter
Input Characteristics
IIH
Input HIGH Current
IIL
Input LOW Current
VIK
Clamp Diode Voltage
DC Input Voltage
VIN
Single-Ended Inputs(2)
VIH
DC Input HIGH
DC Input LOW
VIL
Differential Inputs
VDIF
DC Differential Voltage(3,9)
VCM
DC Common Mode Input Voltage(4,9)
VIH
DC Input HIGH(5,6,9)
VIL
DC Input LOW(5,7,9)
Single-Ended Reference Voltage(5,9)
VREF
Output Characteristics
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
Test Conditions
VDD = 2.7V
VI = VDDQ/GND
VDD = 2.7V
VI = GND/VDDQ
VDD = 2.3V, IIN = -18mA
IOH = -12mA
IOH = -100µA
IOL = 12mA
IOL = 100µA
Min.
Typ.(8)
Max
Unit
—
—
—
- 0.3
—
—
- 0.7
±5
±5
- 1.2
+3.6
µA
1.7
—
—
0.7
V
V
0.2
1150
VREF + 100
—
—
—
1350
—
VREF - 100
—
V
mV
mV
mV
mV
—
—
0.4
0.1
V
V
V
V
VDDQ - 0.4
VDDQ - 0.1
—
—
1250
1250
V
V
NOTES:
1. See RECOMMENDED OPERATING RANGE table.
2. For 2.5V LVTTL single-ended operation, the RxS pin is tied HIGH and REF[1:0]/VREF[1:0] is left floating. If TxS is HIGH, FB/VREF2 should be left floating.
3. VDIF specifies the minimum input differential voltage (VTR - VCP) required for switching where VTR is the "true" input level and VCP is the "complement" input level. Differential mode
only. The DC differential voltage must be maintained to guarantee retaining the existing HIGH or LOW input. The AC differential voltage must be achieved to guarantee switching
to a new state.
4. VCM specifies the maximum allowable range of (VTR + VCP) /2. Differential mode only.
5. For single-ended operation, in differential mode, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0].
6. Voltage required to maintain a logic HIGH, single-ended operation in differential mode.
7. Voltage required to maintain a logic LOW, single-ended operation in differential mode.
8. Typical values are at VDD = 2.5V, VDDQ = VDD, +25°C ambient.
9. The reference clock input is capable of HSTL, eHSTL, LVEPECL, 1.8V or 2.5V LVTTL operation independent of the device output. (See Input/Output Selection table.)
12
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
POWER SUPPLY CHARACTERISTICS FOR 2.5V LVTTL OUTPUTS(1)
Symbol
IDDQ
Parameter
Quiescent VDD Power Supply Current(3)
IDDQQ
Quiescent VDDQ Power Supply Current(3)
IDDPD
IDDD
ITOT
Power Down Current
Dynamic VDD Power Supply
Current per Output
Dynamic VDDQ Power Supply
Current per Output
Total Power VDD Supply Current(4)
ITOTQ
Total Power VDDQ Supply Current(4)
IDDDQ
Test Conditions(2)
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDD = Max., PD = LOW, nSOE = LOW, PLL_EN = HIGH
VDD = Max., VDDQ = Max., CL = 0pF
Typ.
15
Max
25
Unit
mA
12
50
µA
0.5
15
3
25
mA
µA/MHz
VDD = Max., VDDQ = Max., CL = 0pF
30
40
µA/MHz
VDDQ = 2.5V., FVCO = 100MHz, CL = 15pF
VDDQ = 2.5V., FVCO = 250MHz, CL = 15pF
VDDQ = 2.5V., FVCO = 100MHz, CL = 15pF
VDDQ = 2.5V., FVCO = 250MHz, CL = 15pF
40
60
80
200
60
90
120
300
mA
mA
NOTES:
1. These power consumption characteristics are for all the valid input interfaces and cover the worst case input and output interface combinations.
2. The termination resistors are excluded from these measurements.
3. If the differential input interface is used, the true input is held LOW and the complementary input is held HIGH.
4. FS = HIGH.
DIFFERENTIAL INPUT AC TEST CONDITIONS FOR 2.5V LVTTL
Symbol
Parameter
VDIF
Input Signal Swing(1)
VX
Differential Input Signal Crossing Point
VTHI
Input Timing Measurement Reference Level(3)
tR, tF
Input Signal Edge Rate(4)
(2)
Value
Units
VDD
V
VDD/2
V
Crossing Point
V
2.5
V/ns
NOTES:
1. A nominal 2.5V peak-to-peak input pulse level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VDIF
(AC) specification under actual use conditions.
2. A nominal 1.25V crossing point level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VX specification
under actual use conditions.
3. In all cases, input waveform timing is marked at the differential cross-point of the input signals.
4. The input signal edge rate of 2.5V/ns or greater is to be maintained in the 20% to 80% range of the input waveform.
SINGLE-ENDED INPUT AC TEST CONDITIONS FOR 2.5V LVTTL
Symbol
Parameter
Value
Units
VIH
Input HIGH Voltage
VDD
V
VIL
Input LOW Voltage
0
V
VTHI
Input Timing Measurement Reference Level
tR, tF
Input Signal Edge Rate(2)
(1)
VDD/2
V
2
V/ns
NOTES:
1. A nominal 1.25V timing measurement reference level is specified to allow constant, repeatable results in an automatic test equipment (ATE) environment.
2. The input signal edge rate of 2V/ns or greater is to be maintained in the 10% to 90% range of the input waveform.
13
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
DC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE FOR 1.8V
LVTTL(1)
Symbol
Parameter
Input Characteristics
IIH
Input HIGH Current
IIL
Input LOW Current
VIK
Clamp Diode Voltage
DC Input Voltage
VIN
Single-Ended Inputs(2)
VIH
DC Input HIGH
DC Input LOW
VIL
Differential Inputs
VDIF
DC Differential Voltage(3,9)
VCM
DC Common Mode Input Voltage(4,9)
VIH
DC Input HIGH(5,6,9)
VIL
DC Input LOW(5,7,9)
Single-Ended Reference Voltage(5,9)
VREF
Output Characteristics
VOH
Output HIGH Voltage
VOL
Output LOW Voltage
Test Conditions
VDD = 2.7V
VI = VDDQ/GND
VDD = 2.7V
VI = GND/VDDQ
VDD = 2.3V, IIN = -18mA
Min.
Typ.(8)
Max
Unit
—
—
—
- 0.3
—
—
- 0.7
±5
±5
- 1.2
VDDQ + 0.3
µA
—
0.683(11)
V
V
—
975
—
VREF - 100
—
V
mV
mV
mV
mV
—
—
0.4
0.1
V
V
V
V
1.073(10)
—
0.2
825
VREF + 100
—
—
IOH = -6mA
IOH = -100µA
IOL = 6mA
IOL = 100µA
VDDQ - 0.4
VDDQ - 0.1
—
—
900
900
V
V
NOTES:
1. See RECOMMENDED OPERATING RANGE table.
2. For 1.8V LVTTL single-ended operation, the RxS pin is MID and REF[1:0]/VREF[1:0] is left floating. If TxS is MID, FB/VREF2 should be left floating.
3. VDIF specifies the minimum input differential voltage (VTR - VCP) required for switching where VTR is the "true" input level and VCP is the "complement" input level. Differential mode
only. The DC differential voltage must be maintained to guarantee retaining the existing HIGH or LOW input. The AC differential voltage must be achieved to guarantee switching
to a new state.
4. VCM specifies the maximum allowable range of (VTR + VCP) /2. Differential mode only.
5. For single-ended operation in differential mode, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0]. The input is guaranteed to toggle within ±200mV of VREF[1:0] when VREF[1:0]
is constrained within +600mV and VDDI-600mV, where VDDI is the nominal 1.8V power supply of the device driving the REF[1:0] input. To guarantee switching in voltage range
specified in the JEDEC 1.8V LVTTL interface specification, VREF[1:0] must be maintained at 900mV with appropriate tolerances.
6. Voltage required to maintain a logic HIGH, single-ended operation in differential mode.
7. Voltage required to maintain a logic LOW, single-ended operation in differential mode.
8. Typical values are at VDD = 2.5V, VDDQ = 1.8V, +25°C ambient.
9. The reference clock input is capable of HSTL, eHSTL, LVEPECL, 1.8V or 2.5V LVTTL operation independent of the device output. (See Input/Output Selection table.)
10. This value is the worst case minimum VIH over the specification range of the 1.8V power supply. The 1.8V LVTTL specification is VIH = 0.65 * VDD where VDD is 1.8V ± 0.15V.
However, the LVTTL translator is supplied by a 2.5V nominal supply on this part. To ensure compliance with the specification, the translator was designed to accept the calculated
worst case value ( VIH = 0.65 * [1.8 - 0.15V]) rather than reference against a nominal 1.8V supply.
11. This value is the worst case maximum VIL over the specification range of the 1.8V power supply. The 1.8V LVTTL specification is VIL = 0.35 * VDD where VDD is 1.8V ± 0.15V.
However, the LVTTL translator is supplied by a 2.5V nominal supply on this part. To ensure compliance with the specification, the translator was designed to accept the calculated
worst case value ( VIL = 0.35 * [1.8 + 0.15V]) rather than reference against a nominal 1.8V supply.
14
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
POWER SUPPLY CHARACTERISTICS FOR 1.8V LVTTL OUTPUTS(1)
Symbol
IDDQ
Parameter
Quiescent VDD Power Supply Current(3)
IDDQQ
Quiescent VDDQ Power Supply Current(3)
IDDPD
IDDD
ITOT
Power Down Current
Dynamic VDD Power Supply
Current per Output
Dynamic VDDQ Power Supply
Current per Output
Total Power VDD Supply Current(4)
ITOTQ
Total Power VDDQ Supply Current(4)
IDDDQ
Test Conditions(2)
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDDQ = Max., REF = LOW, PD = HIGH, nSOE = LOW,
PLL_EN = HIGH, DS[1:0] = MM, nF[2:1] = LH,
FBF[2:1] = LH, Outputs enabled, All outputs unloaded
VDD = Max., PD = LOW, nSOE = LOW, PLL_EN = HIGH
VDD = Max., VDDQ = Max., CL = 0pF
Typ.
15
Max
25
Unit
mA
1.5
50
µA
0.5
16
3
25
mA
µA/MHz
VDD = Max., VDDQ = Max., CL = 0pF
22
30
µA/MHz
VDDQ = 1.8V., FVCO = 100MHz, CL = 15pF
VDDQ = 1.8V., FVCO = 250MHz, CL = 15pF
VDDQ = 1.8V., FVCO = 100MHz, CL = 15pF
VDDQ = 1.8V., FVCO = 250MHz, CL = 15pF
40
70
55
135
60
105
85
205
mA
mA
NOTES:
1. These power consumption characteristics are for all the valid input interfaces and cover the worst case input and output interface combinations.
2. The termination resistors are excluded from these measurements.
3. If the differential input interface is used, the true input is held LOW and the complementary input is held HIGH.
4. FS = HIGH.
DIFFERENTIAL INPUT AC TEST CONDITIONS FOR 1.8V LVTTL
Symbol
Parameter
Value
Units
VDIF
Input Signal Swing
(1)
VDDI
V
VX
Differential Input Signal Crossing Point(2)
VDDI/2
mV
VTHI
Input Timing Measurement Reference Level(3)
tR, tF
Input Signal Edge Rate(4)
Crossing Point
V
1.8
V/ns
NOTES:
1. VDDI is the nominal 1.8V supply (1.8V ± 0.15V) of the part or source driving the input. A nominal 1.8V peak-to-peak input pulse level is specified to allow consistent, repeatable
results in an automatic test equipment (ATE) environment. This device meets the VDIF (AC) specification under actual use conditions.
2. A nominal 900mV crossing point level is specified to allow consistent, repeatable results in an automatic test equipment (ATE) environment. This device meets the VX specification
under actual use conditions.
3. In all cases, input waveform timing is marked at the differential cross-point of the input signals.
4. The input signal edge rate of 1.8V/ns or greater is to be maintained in the 20% to 80% range of the input waveform.
SINGLE-ENDED INPUT AC TEST CONDITIONS FOR 1.8V LVTTL
Symbol
Parameter
Value
VIH
Input HIGH Voltage
VIL
Input LOW Voltage
VTHI
Input Timing Measurement Reference Level(2)
tR, tF
Input Signal Edge Rate(3)
(1)
VDDI
V
0
V
VDDI/2
mV
2
V/ns
NOTES:
1. VDDI is the nominal 1.8V supply (1.8V ± 0.15V) of the part or source driving the input.
2. A nominal 900mV timing measurement reference level is specified to allow constant, repeatable results in an automatic test equipment (ATE) environment.
3. The input signal edge rate of 2V/ns or greater is to be maintained in the 10% to 90% range of the input waveform.
15
Units
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
AC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE
Symbol
FNOM
tRPW
tFPW
tSK(O)
tSK1(ω)
tSK2(ω)
tSK1(INV)
tSK2(INV)
tSK(PR)
t(φ)
tODCV
tORISE
tOFALL
tL
tL(ω)
tL(PD)
tL(REFSEL1)
tL(REFSEL2)
tJIT(CC)
Parameter
VCO Frequency Range
Reference Clock Pulse Width HIGH or LOW
Feedback Input Pulse Width HIGH or LOW
Output Skew (Rise-Rise, Fall-Fall, Nominal)(1,2)
Multiple Frequency Skew (Rise-Rise, Fall-Fall, Nominal-Divided, Divided-Divided)(1,2,3)
Multiple Frequency Skew (Rise-Fall, Nominal-Divided, Divided-Divided)(1,2,3)
Inverting Skew (Nominal-Inverted)(1,2)
Inverting Skew (Rise-Rise, Fall-Fall, Rise-Fall, Inverted-Divided)(1,2,3)
Process Skew(1,2,4)
REF Input to FB Static Phase Offset(5)
Output Duty Cycle Variation from 50%(11,12) 1.8V LVTTL
2.5V LVTTL
Output Rise Time(6)
HSTL / eHSTL / 1.8V LVTTL
2.5V LVTTL
Output Fall Time(6)
HSTL / eHSTL / 1.8V LVTTL
2.5V LVTTL
Power-up PLL Lock Time(7)
PLL Lock Time After Input Frequency Change(7)
PLL Lock Time After Asserting PD Pin(7)
PLL Lock Time After Change in REF_SEL(7,9)
PLL Lock Time After Change in REF_SEL (REF1 and REF0 are different frequency)(7)
Cycle-to-Cycle Output Jitter (peak-to-peak)(2,8)
Min.
Typ.
Max
Unit
see VCO Frequency Range Select Table
1
—
—
ns
1
—
—
ns
—
—
100
ps
—
—
100
ps
—
—
300
ps
—
—
300
ps
—
—
300
ps
—
—
300
ps
-100
—
100
ps
-375
—
375
ps
-275
—
275
—
—
1.2
ns
—
—
1
—
—
1.2
ns
—
—
1
—
—
1
ms
—
—
1
ms
—
—
1
ms
—
—
100
µs
—
—
1
ms
—
50
75
ps
tJIT(PER)
Period Jitter (peak-to-peak)(2,8)
—
—
75
ps
tJIT(HP)
Half Period Jitter (peak-to-peak)(2,8,10)
—
—
125
ps
—
VDDQ/2 - 150
—
100
VDDQ/2 + 150
ps
mV
tJIT(DUTY)
VOX
Duty Cycle Jitter (peak-to-peak)(2,8)
HSTL and eHSTL Differential True and Complementary Output Crossing Voltage Level
VDDQ/2
NOTES:
1. Skew is the time between the earliest and latest output transition among all outputs when all outputs are loaded with the specified load.
2. For differential LVTTL outputs, the measurement is made at VDDQ/2, where the true outputs are only compared with other true outputs and the complementary outputs are only
compared to other complementary outputs. For differential HSTL/eHSTL outputs, the measurement is made at the crossing point (VOX) of the true and complementary signals.
3. There are three classes of outputs: nominal (zero delay), inverted, and divided (divide-by-2 or divide-by-4 mode).
4. tSK(PR) is the output to corresponding output skew between any two devices operating under the same conditions (VDD and VDDQ, ambient temperature, air flow, etc.).
5. t(φ) is measured with REF and FB the same type of input, the same rise and fall times. For TxS/RxS = MID or HIGH, the measurement is taken from VTHI on REF to VTHI on
FB. For TxS/RxS = LOW, the measurement is taken from the crosspoint of REF/REF to the crosspoint of FB/FB. All outputs are set to zero delay, FB input divider is set to
divide-by-one, and FS = HIGH.
6. Output rise and fall times are measured between 20% to 80% of the actual output voltage swing.
7. tL, tL(ω), tL(REFSEL1), tL(REFSEL2), and tL(PD) are the times that are required before the synchronization is achieved. These specifications are valid only after VDD/VDDQ is stable and
within the normal operating limits. These parameters are measured from the application of a new signal at REF or FB, or after PD is (re)asserted until t(φ) is within specified
limits.
8. The jitter parameters are measured with all outputs selected for zero delay, FB input divider is set to divide-by-one, and FS = HIGH.
9. Both REF inputs must be the same frequency, but up to ±180° out of phase.
10. For HSTL/eHSTL outputs only.
11. For LVTTL outputs only.
12. tODCV is measured with all outputs selected for zero delay.
16
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
AC DIFFERENTIAL INPUT SPECIFICATIONS(1)
Symbol
tW
Parameter
Reference/Feedback Input Clock Pulse Width HIGH or LOW (HSTL/eHSTL outputs)(2)
Reference/Feedback Input Clock Pulse Width HIGH or LOW (2.5V / 1.8V LVTTL outputs)(2)
HSTL/eHSTL/1.8V LVTTL/2.5V LVTTL
VDIF
AC Differential Voltage(3)
VIH
AC Input HIGH
VIL
LVEPECL
(4,5)
AC Input LOW
(4,6)
Min.
1
1
Typ.
—
—
Max
—
—
Unit
ns
400
—
—
mV
Vx + 200
—
—
mV
—
—
Vx - 200
mV
—
mV
VDIF
AC Differential Voltage(3)
400
—
VIH
AC Input HIGH
1275
—
—
mV
VIL
AC Input LOW(4)
—
—
875
mV
(4)
NOTES:
1. For differential input mode, RxS is tied to GND.
2. Both differential input signals should not be driven to the same level simultaneously. The input will not change state until the inputs have crossed and the voltage range defined
by VDIF has been met or exceeded.
3. Differential mode only. VDIF specifies the minimum input voltage (VTR - VCP) required for switching where VTR is the "true" input level and VCP is the "complement" input level.
The AC differential voltage must be achieved to guarantee switching to a new state.
4. For single-ended operation, REF[1:0]/VREF[1:0] is tied to the DC voltage VREF[1:0]. Refer to each input interface's DC specification for the correct VREF[1:0] range.
5. Voltage required to switch to a logic HIGH, single-ended operation only.
6. Voltage required to switch to a logic LOW, single-ended operation only.
17
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
AC TIMING DIAGRAM(1)
tRPWL
REF
tRPWH
REF
tFPWH
tFPWL
FB
FB
tODCV
tODCV
Q
Q
tSK(O)
tSK(O)
OTHER Q
OTHER Q
tSK1(INV)
tSK1(INV)
INVERTED Q
INVERTED Q
tSK2(ω),
tSK2(INV)
tSK2(INV)
tSK2(ω)
Q DIVIDED BY 2
Q DIVIDED BY 2
tSK1(ω),
tSK2(INV)
tSK1(ω)
Q DIVIDED BY 4
Q DIVIDED BY 4
NOTE:
1. The AC TIMING DIAGRAM applies to PE = VDD. For PE = GND, the negative edge of FB aligns with the negative edge of REF[1:0], divided outputs change on the negative
edge of REF[1:0], and the positive edges of the divide-by-2 and divide-by-4 signals align.
18
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
JITTER AND OFFSET TIMING WAVEFORMS
nQ, QFB
nQ, QFB
tcycle n
tcycle n + 1
tjit(cc) = tcycle n
tcycle n+1
Cycle-to-Cycle jitter
REF[1:0]
REF[1:0]
FB
FB
t(Ø)n + 1
t(Ø)n
∑
t(Ø)
n=N
1
=
t(Ø)n
N
Static Phase Offset
NOTE:
1. Diagram for PE = H and TxS/RxS = L.
19
(N is a large number of samples)
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
JITTER AND OFFSET TIMING WAVEFORMS
nQ, QFB
nQ, QFB
tW(MIN)
tW(MAX)
tJIT(DUTY) = tW(MAX) - tW(MIN)
Duty-Cycle Jitter
nQ, QFB
nQ, QFB
tcycle n
nQ, QFB
nQ, QFB
1
fo
tjit(per)
=
tcycle n
1
fo
Period jitter
nQ, QFB
nQ, QFB
thalf period n+1
thalf period n
nQ, QFB
nQ, QFB
1
fo
tjit(hper) = thalf period n
Half-Period jitter
20
1
2*f o
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
TEST CIRCUITS AND CONDITIONS
VDDI
R1
VIN
3 inch, ~50Ω
Transmission Line
VDD
VDDQ
R2
VDDI
REF[1:0]
D.U.T.
Pulse
Generator
R1
VIN
REF[1:0]
3 inch, ~50Ω
Transmission Line
R2
Test Circuit for Differential Input(1)
DIFFERENTIAL INPUT TEST CONDITIONS
Symbol
VDD = 2.5V ± 0.2V
Unit
R1
100
Ω
R2
100
Ω
VDDI
VCM*2
V
HSTL: Crossing of REF[1:0] and REF[1:0]
eHSTL: Crossing of REF[1:0] and REF[1:0]
VTHI
LVEPECL: Crossing of REF[1:0] and REF[1:0]
V
1.8V LVTTL: VDDI/2
2.5V LVTTL: VDD/2
NOTE:
1. This input configuration is used for all input interfaces. For single-ended testing,
the REF[1:0] must be left floating. For testing single-ended in differential input
mode, the VIN should be floating.
21
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
VDDQ
VDD
VDDQ
REF[1:0]
R1
VDDQ
VDDQ
R1
nQ
CL
D.U.T.
R1
R2
VDDQ
VDD
R2
CL
REF[1:0]
nQ
FB
QFB
FB
QFB
VDDQ
QFB
D.U.T.
R2
CL
R1
FB
QFB
FB
CL
R2
SW1
SW1
Test Circuit for Differential Feedback
Test Circuit for Differential Outputs
DIFFERENTIAL FEEDBACK TEST
CONDITIONS
DIFFERENTIAL OUTPUT TEST
CONDITIONS
Symbol
VDD = 2.5V ± 0.2V
Symbol
Unit
VDD = 2.5V ± 0.2V
Unit
VDDQ = Interface Specified
VDDQ = Interface Specified
CL
15
pF
CL
15
pF
R1
100
Ω
R1
100
Ω
R2
100
Ω
R2
100
Ω
VOX
HSTL: Crossing of nQ and nQ
V
VOX
HSTL: Crossing of QFB and QFB
V
V
VTHO
1.8V LVTTL: VDDQ/2
Open
SW1
TxS = MID or HIGH
Open
TxS = LOW
Closed
eHSTL: Crossing of QFB and QFB
eHSTL: Crossing of nQ and nQ
VTHO
1.8V LVTTL: VDDQ/2
SW1
TxS = MID or HIGH
2.5V LVTTL: VDDQ/2
2.5V LVTTL: VDDQ/2
TxS = LOW
V
Closed
22
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
RECOMMENDED LANDING PATTERN
NL 68 pin
NOTE:
All dimensions are in millimeters.
23
INDUSTRIAL TEMPERATURE RANGE
IDT5T2110
2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER TERACLOCK
INDUSTRIAL TEMPERATURE RANGE
ORDERING INFORMATION
IDT
XXXXX
Device Type
XX
Package
X
Package
I
-40°C to +85°C (Industrial)
BB
NL
NLG
5T2110
CORPORATE HEADQUARTERS
2975 Stender Way
Santa Clara, CA 95054
Plastic Ball Grid Array
Thermally Enhanced Plastic Very Fine
Pitch Quad Flat No Lead Package
VFQFPN - Green
2.5V Zero Delay PLL Differential Clock
Driver Teraclock
for SALES:
800-345-7015 or 408-727-6116
fax: 408-492-8674
www.idt.com
24
for Tech Support:
[email protected]
(408) 654-6459