3D3418
MONOLITHIC 8-BIT
PROGRAMMABLE DELAY LINE
(SERIES 3D3418 – LOW NOISE)
FEATURES
All-silicon, low-power 3.3V CMOS technology
Vapor phase, IR and wave solderable
Auto-insertable (DIP pkg.)
Low ground bounce noise
Leading- and trailing-edge accuracy
Increment range: 0.25 through 7.5ns
Delay tolerance: 1% (See Table 1)
Temperature stability: ±3% typical (0C-70C)
Vdd stability: ±1% typical (3.0V-3.6V)
Static Idd: 1.3ma typical
Minimum input pulse width: 10% of total
delay
Programmable via 3-wire serial or 8-bit parallel interface
PACKAGES
16
15
14
13
12
11
10
9
1
2
3
4
5
6
7
8
IN
AE
SO/P0
P1
P2
P3
P4
GND
VDD
OUT
MD
P7
P6
SC
P5
SI
3D3418 DIP
3D3418G Gull Wing
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
IN
AE
SO/P0
P1
P2
P3
P4
GND
VDD
OUT
MD
P7
P6
SC
P5
SI
3D3418S SOL
(300 Mil)
For mechanical dimensions, click here.
FUNCTIONAL DESCRIPTION
The 3D3418 Programmable 8-Bit Silicon Delay Line product family
consists of 8-bit, user-programmable CMOS silicon integrated
circuits. Delay values, programmed either via the serial or parallel
interface, can be varied over 255 equal steps ranging from 250ps
to 7.5ns inclusively. Units have a typical inherent (address 0)
delay of 20ns (See Table 1). The input is reproduced at the output
without inversion, shifted in time as per user selection. The
3D3418 is CMOS-compatible, and features both rising- and
falling-edge accuracy.
The all-CMOS 3D3418 integrated circuit has been designed as a
reliable, economic alternative to hybrid TTL programmable delay lines. It is offered in a standard 16-pin
auto-insertable DIP and a space saving surface mount 16-pin SOIC.
PIN DESCRIPTIONS
IN Signal Input
OUT Signal Output
MD Mode Select
AE Address Enable
P0-P7 Parallel Data Input
SC Serial Clock
SI Serial Data Input
SO Serial Data Output
VDD +3.3 Volts
GND Ground
TABLE 1: PART NUMBER SPECIFICATIONS
PART DELAYS AND TOLERANCES INPUT RESTRICTIONS
NUMBER Step 0
Delay (ns)
Step 255
Delay (ns)
Delay
Increment (ns)
Max Operating
Frequency
Absolute Max
Oper Freq
Min Operating
P.W.
Absolute Min
Oper P.W.
3D3418-0.25 19.5 ± 3.0 83.25 ± 4.0 0.25 ± 0.15 6.25 MHz 90 MHz 80.0 ns 5.5 ns
3D3418-0.5 19.5 ± 3.0 147.0 ± 4.0 0.50 ± 0.25 3.15 MHz 45 MHz 160.0 ns 11.0 ns
3D3418-1 19.5 ± 3.0 274.5 ± 5.0 1.00 ± 0.50 1.56 MHz 22 MHz 320.0 ns 22.0 ns
3D3418-2 20.0 ± 3.5 530.0 ± 6.0 2.00 ± 1.00 0.78 MHz 11 MHz 640.0 ns 44.0 ns
3D3418-3 20.0 ± 3.5 785.0 ± 8.0 3.00 ± 1.50 0.52 MHz 7.5 MHz 960.0 ns 66.0 ns
3D3418-4 20.0 ± 3.5 1040 ± 9.0 4.00 ± 2.00 0.39 MHz 5.5 MHz 1280.0 ns 88.0 ns
3D3418-5 20.0 ± 3.5 1295 ± 10 5.00 ± 2.50 0.31 MHz 4.4 MHz 1600.0 ns 110.0 ns
3D3418-7.5 20.5 ± 3.5 1933 ± 15 7.50 ± 3.75 0.21 MHz 2.9 MHz 2400.0 ns 165.0 ns
NOTES: Any delay increment between 0.25 and 7.5 ns not shown is also available.
All delays referenced to input pin 2002 Data Delay Devices
Doc #02006 DATA DELAY DEVICES, INC. 1
10/28/02 3 Mt. Prospect Ave. Clifton, NJ 07013
3D3418
APPLICATION NOTES
The 8-bit programmable 3D3418 delay line
architecture is comprised of a number of delay
cells connected in series with their respective
outputs multiplexed onto the Delay Out pin (OUT)
by the user-selected programming data. Each
delay cell produces at its output a replica of the
signal present at its input, shifted in time.
INPUT SIGNAL CHARACTERISTICS
The Frequency and/or Pulse Width (high or low)
of operation may adversely impact the specified
delay and increment accuracy of the particular
device. The reasons for the dependency of the
output delay accuracy on the input signal
characteristics are varied and complex.
Therefore a Maximum and an Absolute
Maximum operating input frequency and a
Minimum and an Absolute Minimum operating
pulse width have been specified.
OPERATING FREQUENCY
The Absolute Maximum Operating Frequency
specification, tabulated in Table 1, determines
the highest frequency of the delay line input
signal that can be reproduced, shifted in time at
the device output, with acceptable duty cycle
distortion.
The Maximum Operating Frequency
specification determines the highest frequency of
the delay line input signal for which the output
delay accuracy is guaranteed.
To guarantee the Table 1 delay accuracy for
input frequencies higher than the Maximum
Operating Frequency, the 3D3418 must be
tested at the user operating frequency.
Therefore, to facilitate production and device
identification, the part number will include a
custom reference designator identifying the
intended frequency of operation. The
programmed delay accuracy of the device is
guaranteed, therefore, only at the user specified
input frequency. Small input frequency variation
about the selected frequency will only marginally
impact the programmed delay accuracy, if at all.
Nevertheless, it is strongly recommended that
the engineering staff at DATA DELAY
DEVICES be consulted.
OPERATING PULSE WIDTH
The Absolute Minimum Operating Pulse
Width (high or low) specification, tabulated in
Table 1, determines the smallest Pulse Width of
the delay line input signal that can be
reproduced, shifted in time at the device output,
with acceptable pulse width distortion.
The Minimum Operating Pulse Width (high or
low) specification determines the smallest Pulse
Width of the delay line input signal for which the
output delay accuracy tabulated in Table 1 is
guaranteed.
To guarantee the Table 1 delay accuracy for
input pulse width smaller than the Minimum
Operating Pulse Width, the 3D3418 must be
tested at the user operating pulse width.
Therefore, to facilitate production and device
identification, the part number will include a
custom reference designator identifying the
intended frequency and duty cycle of operation.
The programmed delay accuracy of the device is
guaranteed, therefore, only for the user specified
input characteristics. Small input pulse width
variation about the selected pulse width will only
marginally impact the programmed delay
accuracy, if at all. Nevertheless, it is strongly
recommended that the engineering staff at
DATA DELAY DEVICES be consulted.
SPECIAL HIGH ACCURACY
REQUIREMENTS
The Table 1 delay and increment accuracy
specifications are aimed at meeting the
requirements of the majority of the applications
encountered to date. However, some systems
may place tighter restrictions on one accuracy
parameter in favor of others. For example, a
channel delay equalizing system is concerned in
minimizing delay variations among the various
channels. Therefore, because the inter channel
skew is a delay difference, the programmed
delay tolerance may need to be considerably
decreased, while the increment and its tolerance
are of no consequence. The opposite is true for
an under-sampled multi-channel data acquisition
system.
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3D3418
Doc #02006 DATA DELAY DEVICES, INC. 3
10/28/02 3 Mt. Prospect Ave. Clifton, NJ 07013
APPLICATION NOTES (CONT’D)
The flexible 3D3418 architecture can be
exploited to conform to these more demanding
user-dictated accuracy constraints. However, to
facilitate production and device identification, the
part number will include a custom reference
designator identifying the user requested
accuracy specifications and operating conditions.
It is strongly recommended that the
engineering staff at DATA DELAY DEVICES
be consulted.
POWER SUPPLY AND
TEMPERATURE CONSIDERATIONS
The delay of CMOS integrated circuits is strongly
dependent on power supply and temperature.
The monolithic 3D3418 programmable delay line
utilizes novel and innovative compensation
circuitry to minimize the delay variations induced
by fluctuations in power supply and/or
temperature.
The thermal coefficient is reduced to 600
PPM/C, which is equivalent to a variation, over
the 0C-70 C operating range, of ±3% from the
room-temperature delay settings. The power
supply coefficient is reduced, over the 3.0V-
3.6V operating range, to ±1% of the delay
settings at the nominal 3.3VDC power supply
and/or ±2ns, whichever is greater.
It is essential that the power supply pin be
adequately bypassed and filtered. In addition,
the power bus should be of as low an
impedance construction as possible. Power
planes are preferred.
PROGRAMMED DELAY (ADDRESS)
UPDATE
A delay line is a memory device. It stores
information present at the input for a time equal
to the delay setting before presenting it at the
output with minimal distortion. The 3D3418 8-bit
programmable delay line can be represented by
256 serially connected delay elements
(individually addressed by the programming
data), each capable of storing data for a time
equal to the device increment (step time). The
delay line memory property, in conjunction with
the operational requirement of “instantaneously”
connecting the delay element addressed by the
programming data to the output, may inject
spurious information onto the output data stream.
In order to ensure that spurious outputs do not
occur, it is essential that the input signal be idle
(held high or low) for a short duration prior to
updating the programmed delay. This duration is
given by the maximum programmable delay.
Satisfying this requirement allows the delay line
to “clear” itself of spurious edges. When the new
address is loaded, the input signal can begin to
switch (and the new delay will be valid) after a
time given by tPDV or tEDV (see section below).
PROGRAMMED DELAY (ADDRESS)
INTERFACE
Figure 1 illustrates the main functional blocks of
the 3D3418 delay program interface. Since the
3D3418 is a CMOS design, all unused input pins
must be returned to well defined logic levels,
VCC or Ground.
TRANSPARENT PARALLEL MODE
(MD = 1, AE = 1)
The eight program pins P0 - P7 directly control
the output delay. A change on one or more of
the program
pins will be reflected on the output delay after a
time tPDV, as shown in Figure 2. A register is
required if the programming data is bused.
LATCHED PARALLEL MODE
(MD = 1, AE PULSED)
The eight program pins P0 - P7 are loaded by the
falling edge of the Enable pulse, as shown in
Figure 3. After each change in delay value, a
settling time tEDV is required before the input is
accurately delayed.
SERIAL MODE (MD = 0)
While observing data setup (tDSC) and data hold
(tDHC) requirements, timing data is loaded in
MSB-to-LSB order by the rising edge of the clock
(SC) while the enable (AE) is high, as shown in
Figure 4. The falling edge of the enable (AE)
activates the new delay value which is reflected
at the output after a settling time tEDV. As data is
shifted into the serial data input (SI), the previous
contents of the 8-bit input register are shifted out
of the serial output port pin (SO) in MSB-to-LSB
order, thus allowing cascading of multiple
devices by connecting the serial output pin (SO)
of the preceding device to the serial data input
3D3418
APPLICATION NOTES (CONT’D)
pin (SI) of the succeeding device, as illustrated in
Figure 5. The total number of serial data bits in
a cascade configuration must be eight times the
number of units, and each group of eight bits
must be transmitted in MSB-to-LSB order.
To initiate a serial read, enable (AE) is driven
high. After a time tEQV , bit 7 (MSB) is valid at the
serial output port pin (SO). On the first rising
edge of the serial clock (SC), bit 7 is loaded with
the value present at the serial data input pin (SI),
while bit 6 is presented at the serial output pin
(SO). To retrieve the remaining bits seven more
rising edges must be generated on the serial
clock line. The read operation is destructive.
Therefore, if it is desired that the original delay
setting remain unchanged, the read data must be
written back to the device(s) before the enable
(AE) pin is brought low.
Pin 3, if unused, must be allowed to float if the
device is configured in the serial programming
mode.
PROGRAMMABLE
DELAY LINE
LATCH
8-BIT INPUT
REGISTER
MD
SC
SI
A
E
IN
SO
OUT
P0 P1 P2 P3 P4 P5 P6 P7
MODE SELECT
SHIFT CLOCK
SERIAL INPUT
A
DDRESS ENABLE
SIGNAL IN SIGNAL OUT
SERIAL OUTPUT
PARALLEL INPUTS
Figure1: Functional block diagram
PREVIOUS VALUE
PREVIOUS VALUE
NEW VALUE
NEW VALUE
tPDX tPDV
PARALLEL
INPUTS
P0-P7
DELAY
TIME
Figure 2: Non-latched parallel mode (MD=1, AE=1)
PREVIOUS VALUE
NEW VALUE
NEW VALUE
tEDX tEDV
PARALLEL
INPUTS
P0-P7
DELAY
TIME
tDSE tDHE
tEW
ENABLE
(AE)
Figure 3: Latched parallel mode (MD=1)
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3D3418
APPLICATION NOTES (CONT’D)
NEW
VALUE
NEW
BIT 7
NEW
BIT 0
NEW
BIT 6
OLD
BIT 7
OLD
BIT 6
OLD
BIT 0
ENABLE
(AE)
CLOCK
(SC)
SERIAL
INPUT
(
SI
)
SERIAL
OUTPUT
(
SO
)
DELAY
TIME
tEW
tES
tCW tCW tEH
tDSC tDHC
tEGV tCQV tCQX tEQZ
tEDV
tEDX
PREVIOUS VALUE
Figure 4: Serial mode (MD=0)
FROM
WRITING
DEVICE
TO
NEXT
DEVICE
SI SO
SC
A
E
3D3418 3D3418 3D3418
Figure 5: Cascading Multiple Devices
SI SO
SC
A
E
SI SO
SC
A
E
TABLE 2: DELAY VS. PROGRAMMED ADDRESS
PROGRAMMED ADDRESS NOMINAL DELAY (NS)
PARALLEL P7 P6 P5 P4 P3 P2 P1 P0 3D3418 DASH NUMBER
SERIAL Msb Lsb -.25 -.5 -1 -2 -5
STEP 0 0 0 0 0 0 0 0 0 19.50 19.5 19.5 20 20
STEP 1 0 0 0 0 0 0 0 1 19.75 20.0 20.5 22 25
STEP 2 0 0 0 0 0 0 1 0 20.00 20.5 21.5 24 30
STEP 3 0 0 0 0 0 0 1 1 20.25 21.0 22.5 26 35
STEP 4 0 0 0 0 0 1 0 0 20.50 21.5 23.5 28 40
STEP 5 0 0 0 0 0 1 0 1 20.75 22.0 24.5 30 45
STEP 253 1 1 1 1 1 1 0 1 82.75 146.0 272.5 526 1285
STEP 254 1 1 1 1 1 1 1 0 83.00 146.5 273.5 528 1290
STEP 255 1 1 1 1 1 1 1 1 83.25 147.0 274.5 530 1295
DELAY CHANGE 63.75 127.5 255 510 1275
Doc #02006 DATA DELAY DEVICES, INC. 5
10/28/02 3 Mt. Prospect Ave. Clifton, NJ 07013
3D3418
DEVICE SPECIFICATIONS
TABLE 3: ABSOLUTE MAXIMUM RATINGS
PARAMETER SYMBOL MIN MAX UNITS NOTES
DC Supply Voltage VDD -0.3 7.0 V
Input Pin Voltage VIN -0.3 VDD+0.3 V
Input Pin Current IIN -10 10 mA 25C
Storage Temperature TSTRG -55 150 C
Lead Temperature TLEAD 300 C 10 sec
TABLE 4: DC ELECTRICAL CHARACTERISTICS
(0C to 70C, 3.0V to 3.6V)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Static Supply Current* IDD 1.3 2.0 mA VDD = 3.6V
High Level Input Voltage VIH 2.0 V
Low Level Input Voltage VIL 0.8 V
High Level Input Current IIH -0.1 0.0 0.1
µA VIH = VDD
Low Level Input Current IIL -0.1 0.0 0.1
µA VIL = 0V
High Level Output Current IOH -8.0 -6.0 mA VDD = 3.0V
VOH = 2.4V
Low Level Output Current IOL 6.0 7.5 mA VDD = 3.0V
VOL = 0.4V
Output Rise & Fall Time TR & TF 2 ns CLD = 5 pf
*IDD(Dynamic) = CLD * VDD * F Input Capacitance = 10 pf typical
where: CLD = Average capacitance load/line (pf) Output Load Capacitance (CLD) = 25 pf max
F = Input frequency (GHz)
TABLE 5: AC ELECTRICAL CHARACTERISTICS
(0C to 70C, 3.0V to 3.6V)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Clock Frequency fC 80 MHz
Enable Width tEW 10 ns
Clock Width tCW 10 ns
Data Setup to Clock tDSC 10 ns
Data Hold from Clock tDHC 3 ns
Data Setup to Enable tDSE 10 ns
Data Hold from Enable tDHE 3 ns
Enable to Serial Output Valid tEQV 20 ns
Enable to Serial Output High-Z tEQZ 20 ns
Clock to Serial Output Valid tCQV 20 ns
Clock to Serial Output Invalid tCQX 10 ns
Enable Setup to Clock tES 10 ns
Enable Hold from Clock tEH 10 ns
Parallel Input Valid to Delay Valid tPDV 20 40 ns 1
Parallel Input Change to Delay Invalid tPDX 0 ns 1
Enable to Delay Valid tEDV 35 45 ns 1
Enable to Delay Invalid tEDX 0 ns 1
Input Pulse Width tWI 8 % of Total Delay See Table 1
Input Period Period 20 % of Total Delay See Table 1
Input to Output Delay tPLH, tPHL ns See Table 2
NOTES: 1 - Refer to PROGRAMMED DELAY (ADDRESS) UPDATE section
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3D3418
Doc #02006 DATA DELAY DEVICES, INC. 7
10/28/02 3 Mt. Prospect Ave. Clifton, NJ 07013
SILICON DELAY LINE AUTOMATED TESTING
TEST CONDITIONS
INPUT: OUTPUT:
Ambient Temperature: 25oC ± 3oC Rload: 10K ± 10%
Supply Voltage (Vcc): 3.3V
± 0.1V Cload: 5pf ± 10%
Input Pulse: High = 3.3V ± 0.1V Threshold: 1.5V (Rising & Falling)
Low = 0.0V ± 0.1V
Source Impedance: 50 Max.
10K
4705pf
Device
Under
Test
Digital
Scope
Rise/Fall Time: 3.0 ns Max. (measured
between 0.6V and 2.4V
)
Pulse Width: PWIN = 1.25 x Total
Delay
Period: PERIN = 2.5 x Total
Delay
NOTE: The above conditions are for test only and do not in any way restrict the operation of the device.
OUT
TRIG
IN
REF
TRIG
Figure 6: Test Setup
DEVICE UNDER
TEST (DUT)
DIGITAL SCOPE/
TIME INTERVAL COUNTER
PULSE
GENERATOR
OUTIN
COMPUTER
SYSTEM
PRINTER
Figure 7: Timing Diagram
tPLH tPHL
PERIN
PWIN
tRISE tFALL
0.6V0.6V 1.5V1.5V
2.4V 2.4V
1.5V1.5V
VIH
VIL
VOH
VOL
INPUT
SIGNAL
OUTPUT
SIGNAL