MC100EP196B
http://onsemi.com
11
Figure 5. AC Reference Measurement
IN
IN
Q
Q
t
PHL
t
PLH
V
INPP
= V
IH
(D) − V
IL
(D)
V
OUTPP
= V
OH
(Q) − V
OL
(Q)
Using the FTUNE Analog Input
The analog FTUNE pin on the EP196 device is intended
to add more delay in a tunable gate to enhance the 10 ps
resolution capabilities of the fully digital EP196. The level
of resolution obtained is dependent on the voltage applied to
the FTUNE pin.
To provide this further level of resolution, the FTUNE pin
must be capable of adjusting the additional delay finer than
the 10 ps digital resolution (See Logic Diagram). This
requirement is easily achieved because a 60 ps additional
delay can be obtained over the entire FTUNE voltage range
(See Figure 6). This extra analog range ensures that the
FTUNE pin will be capable even under worst case
conditions of covering a digital resolution. Typically, the
analog input will be driven by an external DAC to provide
a digital control with very fine analog output steps. The final
resolution of the device will be dependent on the width of the
DAC chosen.
To determine the voltage range necessary for the FTUNE
input, Figure 6 should be used. There are numerous voltage
ranges which can be used to cover a given delay range; users
are given the flexibility to determine which one best fits their
designs.
Figure 6. Typical EP196B Delay versus FTUNE Voltage
FTUNE VOLTAGE (V)
−3.3 −2.97 −2.64 −2.31 −1.98 −1.65 −1.32 −0.99 −0.66 −0.33 0
90
80
70
60
50
40
30
20
10
0
−10
DELAY (ps)
−40°C
85°C
25°C
V
CC
= 0 V
V
EE
= −3.3 V
V
CC
V
EE
Cascading Multiple EP196Bs
To increase the programmable range of the EP196B,
internal cascade circuitry has been included. This circuitry
allows for the cascading of multiple EP196Bs without the
need for any external gating. Furthermore, this capability
requires only one more address line per added EP196B.
Obviously, cascading multiple programmable delay chips
will result in a larger programmable range: however, this
increase is at the expense of a longer minimum delay.
Figure 7 illustrates the interconnect scheme for cascading
two EP196Bs. As can be seen, this scheme can easily be
expanded for larger EP196B chains. The D10 input of the
EP196B is the CASCADE control pin. With the
interconnect scheme of Figure 7 when D10 is asserted, it
signals the need for a larger programmable range than is
achievable with a single device and switches output pin
CASCADE HIGH and pin CASCADE
LOW. The A11
address can be added to generate a cascade output for the
next EP196B. For a 2−device configuration, A11 is not
required.