19
INDUSTRIAL TEMPERATURE RANGE
IDT5T9821
EEPROM PROGRAMMABLE 2.5V ZERO DELAY PLL DIFFERENTIAL CLOCK DRIVER
AC ELECTRICAL CHARACTERISTICS OVER OPERATING RANGE
All outputs at the different interface level
Symbol Parameter Min. Typ. Max Unit
FNOM VCO Frequency Range see JTAG/I
2
C Serial Configurations: VCO Frequency Range table
tRPW Reference Clock Pulse Width HIGH or LOW 1 — — ns
tFPW Feedback Input Pulse Width HIGH or LOW 1 — — ns
tSK(O) Output Skew (Rise-Rise, Fall-Fall, Nominal)
(1,2)
— — 250 ps
tSK1(ω) Multiple Frequency Skew (Rise-Rise, Fall-Fall, Nominal-Divided, Divided-Divided)
(1,2,3)
— — 500 ps
tSK2(ω) Multiple Frequency Skew (Rise-Fall, Nominal-Divided, Divided-Divided)
(1,2,3)
— — 500 ps
tSK1(INV) Inverting Skew (Nominal-Inverted)
(1,2)
——500 ps
tSK2(INV) Inverting Skew (Rise-Rise, Fall-Fall, Rise-Fall, Inverted-Divided)
(1,2,3)
— — 500 ps
tSK(PR) Process Skew
(1,2,4)
——400 ps
t(φ) REF Input to FB Static Phase Offset
(5)
-200 — 200 ps
t
ODCV Output Duty Cycle Variation from 50%
(11,12)
1.8V LVTTL -475 — 475 ps
2.5V LVTTL -375 — 375
t
ORISE Output Rise Time
(6)
HSTL / eHSTL / 1.8V LVTTL — — 1.2 ns
2.5V LVTTL — — 1
t
OFALL Output Fall Time
(6)
HSTL / eHSTL / 1.8V LVTTL — — 1.2 ns
2.5V LVTTL — — 1
tL Power-up PLL Lock Time
(7)
—— 4ms
tL(ω) PLL Lock Time After Input Frequency Change
(7)
—— 1ms
tL(PD) PLL Lock Time After Asserting PD Pin
(7)
—— 1ms
tL(REFSEL1) PLL Lock Time After Change in REF_SEL
(7,9)
— — 100 µs
tL(REFSEL2) PLL Lock Time After Change in REF_SEL (REF1 and REF0 are different frequency)
(7)
—— 1ms
tJIT(CC) Cycle-to-Cycle Output Jitter (peak-to-peak)
(2,8)
— — 100 ps
tJIT(PER) Period Jitter (peak-to-peak)
(2,8)
——100 ps
tJIT(HP) Half Period Jitter (peak-to-peak)
(2,8,10)
——200 ps
tJIT(DUTY) Duty Cycle Jitter (peak-to-peak)
(2,8)
——150 ps
V
OX HSTL and eHSTL Differential True and Complementary Output Crossing Voltage Level VDDQN/2 - 150 VDDQN/2 VDDQN/2 + 150 mV
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 VDDQN/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 VDDQN, 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 1.8V / 2.5V LVTTL input and output, the measurement is taken from VTHI on REF
to VTHI on FB. For HSTL / eHSTL input and output, 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 Bit 60 = 1.
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/VDDQN 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 Bit 60 = 1.
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.