MPC931FA ,Low voltage PLL clock driverLogic DiagramMOTOROLA 2 TIMING SOLUTIONSBR1333 — Rev 6NC GNDOPLL_VCC Qb0Power_Dn Qb1TCLK VCCOMR/Tri ..
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MPC932 ,LOW VOLTAGE PLL CLOCK DRIVERLOGIC DIAGRAMSD0:1PLL_EN÷4STOP Q0÷4 STOP Q1REF_CLKPLL÷5÷2200–480MHzFB_In÷6SD2MODESTOP Q2MR/OECOM_SD ..
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MPC932FA ,Low voltage PLL clock driverLOGIC DIAGRAMSD0:1PLL_EN÷4STOP Q0÷4 STOP Q1REF_CLKPLL÷5÷2200–480MHzFB_In÷6SD2MODESTOP Q2MR/OECOM_SD ..
MPC940L ,MPC940L Low Voltage 1:18 Clock Distribution ChipLOGIC DIAGRAMPECL_CLK0PECL_CLKQ01LVCMOS_CLK16Q1–Q16LVCMOS_CLK_Sel(Internal Pulldown)Q17Pinout: 32–L ..
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MSP430F1101AIDW ,16-bit Ultra-Low-Power Microcontroller, 1kB Flash, 128B RAM, ComparatorMSP430C11x1, MSP430F11x1AMIXED SIGNAL MICROCONTROLLERSLAS241I − SEPTEMBER 1999 − REVISED DECEMBER 2 ..
MPC930FA-MPC931FA
Low voltage PLL clock driver
SEMICONDUCTOR TECHNICAL DATA -
The MPC930/931 is a 3.3V compatible, PLL based clock driver device
targeted for high performance clock applications. With output frequencies
of up to 150MHz and output skews of 300ps the MPC930/931 is ideal for
the most demanding clock distribution designs. The device employs a
fully differential PLL design to minimize cycle to cycle and long term jitter.
This parameter is of significant importance when the clock driver is
providing the reference clock for PLL’s on board todays microprocessors
and ASiC’s. The device offers 6 low skew outputs, and a choice between
internal or external feedback. The feedback option adds to the flexibility of
the device, providing numerous input to output frequency relationships. On–Board Crystal Oscillator (MPC930) Differential LVPECL Reference Input (MPC931) Fully Integrated PLL Output Shut Down Mode Output Frequency up to 150MHz Compatible with PowerPC and Intel Microprocessors 32–Lead TQFP Packaging Power Down Mode ±100ps Typical Cycle–to–Cycle Jitter
The MPC930 and MPC931 are very similar in basic functionality, but
there are some minor differences. The MPC931 has been optimized for
use as a zero delay buffer. In addition to tighter specification limits on the
phase offset of the device, a higher speed VCO has been used on the
MPC931. The MPC930, on the other hand, is more optimized for use as a
clock generator. When choosing between the 930 and 931, pay special
attention to the differences in the AC parameters of each device.
The MPC930/931 offers two power saving features for power conscious portable or “green” designs. The power down pin will
seemlessly reduce all of the clock rates by one half so that the system will run at half the potential clock rate to extend battery life.
The POWER_DN pin is synchronized internally to the slowest output clock rate. This allows the transition in and out of the
power–down mode to be output glitch free. In addition, the shut down control pins will turn off various combinations of clock
outputs while leaving a subset active to allow for total processor shut down while maintaining system monitors to “wake up” the
system when signaled. During shut down, the PLL will remain locked, if internal feedback is used, so that wake up time will be
minimized. The shut down and power down pins can be combined for the ultimate in power savings. The Shut_Dn pins are
synchronized to the clock internal to the chip to eliminate the possibility of generating runt pulses.
The MPC930/931 devices offer a great deal of flexibility in what is used as the PLL reference. The MPC930 offers an
integrated crystal oscillator that allows for an inexpensive crystal to be used as the frequency reference. For more information on
the crystal oscillator please refer to the applications section of this data sheet. In those applications where the 930/931 will be
used to regenerate clocks from an existing source or as a zero delay buffer, alternative reference clock inputs are provided. Both
devices offer an LVCMOS input that can be used as the PLL reference. In addition the MPC931 replaces the crystal oscillator
inputs with a differential PECL reference clock input that allows the device to be used in mixed technology clock distribution trees.
An internal feedback divide by 8 of the VCO frequency is compared with the input reference provided by the on–board crystal
oscillator when the internal feedback is selected. The on–board crystal oscillator requires no external components other than a
series resonant crystal (see Applications Information section for more on crystals). The internal VCO is running at 8x the input
reference clock. The outputs can be configured to run at 4x, 2x, 1.25x or 0.66x the input reference frequency. If the external
feedback is selected, one of the MPC931’s outputs must be connected to the Ext_FB pin. Using the external feedback, numerous
input/output frequency relationships can be developed.
The MPC930/931 is fully 3.3V compatible and requires no external loop filter components. All control inputs accept LVCMOS
or LVTTL compatible levels while the outputs provide LVCMOS levels with the capability to drive terminated 50Ω transmission
lines. For series terminated applications, each output can drive two 50Ω transmission lines, effectively increasing the fanout to
1:12. The device is packaged in a 32–lead TQFP package to provide the optimum combination of board density and cost.
