W134
........................ Document #: 38-07426 Rev. *C Page 5 of 11
Table 5 shows the logic for selecting the Power-down mode,
using the PwrDnB input signal. PwrDnB is active LOW
(enabled when 0). When PwrDnB is disabled, the DRCG is in
its normal mode. When PwrDnB is enabled, the DRCG is put
into a powered-off state, and the Clk and ClkB outputs are
three-stated.
Table of Frequencies and Gear Ratios
Table 6
shows
several
supported
Pclk
and
Busclk
frequencies, the corresponding A and B dividers required in
the DRCG PLL, and the corresponding M and N dividers in the
gear ratio logic. The column Ratio gives the Gear Ratio as
defined Pclk/Synclk (same as M and N). The column F@PD
gives the divided down frequency (in MHz) at the Phase
Detector, where F@PD = Pclk/M = Synclk/N.
State Transitions
The clock source has three fundamental operating states.
Figure 4 shows the state diagram with each transition labelled
A through H. Note that the clock source output may NOT be
glitch-free during state transitions.
Upon powering up the device, the device can enter any state,
depending on the settings of the control signals, PwrDnB and
StopB.
In Power-down mode, the clock source is powered down with
the control signal, PwrDnB, equal to 0. The control signals S0
and S1 must be stable before power is applied to the device,
and can only be changed in Power-down mode (PwrDnB = 0).
The reference inputs, VDDR and VDDPD, may remain on or may
be grounded during the Power-down mode.
The control signals Mult0 and Mult1 can be used in two ways.
If they are changed during Power-down mode, then the
Power-down transition timings determine the settling time of
the DRCG. However, the Mult0 and Mult1 control signals can
also be changed during Normal mode. When the Mult control
signals are “hot-swapped” in this manner, the Mult transition
timings determine the settling time of the DRCG.
In Normal mode, the clock source is on, and the output is
enabled.
Table 7 lists the control signals for each state.
Figure 5 shows the timing diagrams for the various transitions
between states, and Table 8 specifies the latencies of each
state transition. Note that these transition latencies assume
the following.
Refclk input has settled and meets specification shown in the
Operating Conditions table.
The Mult0, Mult1, S0 and S1 control signals are stable.
Table 4. Bypass and Test Mode Selection
Mode
S0
S1
Bypclk
(int.)
Clk
ClkB
Normal
0
Gnd
PAclk
PAclkB
Output Test (OE)
0
1
–
Hi-Z
Bypass
1
0
PLLclk
PLLclkB
Test
1
Refclk
RefclkB
Table 5. Power-down Mode Selection
Mode
PwrDnB
Clk
ClkB
Normal
1
PAclk
PAclkB
Power-down
0
GND
Table 6. Examples of Frequencies, Dividers, and Gear Ratios
Pclk Refclk Busclk Synclk A B M N Ratio F@PD
67
33
267
67
8 1 2 2
1.0
33
100
50
300
75
6 1 8 6
1.33
12.5
100
50
400
100
8 1 4 4
1.0
25
133
67
267
67
4 1 4 2
2.0
33
133
67
400
100
6 1 8 6
1.33
16.7
Table 7. Control Signals for Clock Source States
State
PwrDnB
StopB
Clock
Source
Output
Buffer
Power-down
0
X
OFF
Ground
Clock Stop
1
0
ON
Disabled
Normal
1
ON
Enabled
Test
M
N
L
K
Normal
Power-Down
Clk Stop
D
C
G
A
E
F
H
VDD Turn-On
B
J
Figure 4. Clock Source State Diagram