ETC AN202 Testing and specifying fast logic Datasheet

Philips Semiconductors
Application note
Testing and specifying FAST logic
AN202
Thus, specifications such as the most negative voltage that may be
applied to the outputs only guarantees that if less than –0.5V is
applied to the output pin, after that voltage is removed the part will
still be functional and its useful life will not have been shortened — it
is difficult to imagine the meaning of the term “functionality” WHILE
that voltage is applied to the output.
INTRODUCTION
FAST is a second generation Schottky logic family that utilizes
advanced oxide-isolation techniques to increase the speed and
decrease the power dissipation beyond the levels achievable with
conventional junction isolated families. The improved performance
of the family is exhibited in two ways — first, the speed and power
characteristics of the devices are improved, and second, the
conditions under which speed and power are specified are much
tighter. For instance, LS and S TTL families offer AC limits only at a
nominal +5.00V VCC supply voltage and at room temperature, 25°C.
By contrast, FAST guarantees improved AC performance and
specifies that performance over a supply variation of +5.00V ±10%
and at temperatures from 0°C to 70°C. Thus the designer no longer
needs to derate his propagation delays from the data sheet limits to
compensate for speed degradation over the temperature range.
Input voltage and output voltage specification in this table reflect the
device breakdown voltages in the positive direction (+7.0V) and the
effect of the clamping diodes in the negative direction (–0.5V).
RECOMMENDED OPERATING CONDITIONS
The Recommended Operating Conditions table has a dual purpose.
In one sense, it sets some environmental conditions (operating
free-air temperature), and in another, it sets the conditions under
which the limits set forth in the DC Electrical Characteristics table
and AC Electrical Characteristics table will be met. Another way of
looking at this table is to think of it, not as a set of limits guaranteed
by Philips Semiconductors, but as the conditions Philips
Semiconductors uses to test the parts and guarantee that they will
then meet the limits set forth in the DC and AC Electrical
Characteristics tables.
With every advance of this magnitude, there arise new
considerations that must be kept in mind both by the system
designer and the user setting up test procedures. FAST is no
exception, and it is these considerations that will be addressed in
this application note. This paper represents an attempt to describe
the way the FAST logic parts are specified, why they are specified in
the way they are, and how the parts may be tested in the
qualification lab and at incoming inspection to verify their
performance.
Some care must be used in interpreting the numbers in this table.
Philips Semiconductors feels strongly that the specifications set
forth in a data sheet should reflect as accurately as possible the
operation of the part in an actual system. In particular, the input
threshold values of VIH and VIL can be tested by the user with
parametric test equipment … if VIH and VIL are applied to the inputs,
the outputs will be at the voltages guaranteed by the DC Electrical
Characteristics table providing that there is adequate grounding and
the input voltages are free from noise, otherwise a guardbanded VIH
and VIL should be used, i.e., 2.5V instead of 2.0V and 0.5V instead
of 0.8V. There is a tendency on the part of some users to use VIH
and VIL as conditions applied to the inputs to test the part for
functionality in a “truth-table exerciser” mode. This frequently causes
problems because of the noise present at the test head of
automated test equipment. Parametric tests, such as those used for
the output levels under the VIH and VIL conditions are done fairly
slowly, on the order of milliseconds, and any noise present at the
inputs has settled out before the outputs are measured. (This is not
the case with clocked or enabled parts and poor or moderate
fixturing may induce oscillations or severe ground bounce if noise is
present.) But in functionality testing, the outputs are examined much
faster, before the noise on the inputs is settled out and the part has
assumed its final and correct output state. Since these are unloaded
outputs, having faster edge rates, this causes more noise, If the
outputs are loaded, the 50pF per output pin can cause substantial
ground bounce. Thus VIH and VIL should never be used in testing
the functionality of any TTL part including FAST. For these types of
tests input voltages of +4.5V and 0.0V should be used for the High
and Low states respectively.
THE FAST DATA SHEET PHILOSOPHY
Philips Semiconductors FAST data sheets have been configured
with an eye to quick usability … they are self contained and should
require no reference to other sections for information. The typical
propagation delays listed at the top of the page are the average
between tPLH and tPHL for the most significant data path through the
part. In the case of clocked products, this is sometimes the
maximum frequency of operation, but in any event, this number is a
5.00V – 25°C typical specification. The ICC typical current is shown
in that same specification block is the average current (in the case
of a gate, this will be the average of the ICCH and ICCL currents) at
room temperature and VCC = 5.00V. It represents the total current
through the package, not the current through individual
functions.
Other considerations are the Fanout and Loading tables. Some
manufacturers relate these numbers in therms of 7400 gate loads …
Philips Semiconductors feels that FAST is unlikely to be mixed with
other logic families and so gives the loading factors in terms of FAST
unit loads. A FAST unit load is defined to be 0.6mA in the Low state
and 20µA in the High state. Thus in the case of the 74F00 gate, the
inputs are specified as 1 Ful (FAST unit load) each … the outputs
need a little explanation. The standard FAST output is specified with
an IOL sink current of 20mA and an IOH of +1.0mA. Thus the fanout
of this gate in the Low state is 20mA/0.6mA or 33 FAST unit loads.
In the High state the fanout is 1mA/20µA or 50 FAST unit loads. In
each case, the Fanout and Loading Table on the Philips data sheets
states the High/Low fanout numbers … thus the 74F00 output fanout
is specified as 50/33 Ful.
In no way does this imply that the devices are noise sensitive in the
final system. The use of “hard” Highs and Lows during functional
testing is done primarily to (1) reduce the effects of the large
amounts of noise typically present at the test heads of automated
test equipment with cables that may at times reach several feet and
(2) deal with testing parts exhibiting fast edge rates and 50pF per
output pin. The situation in a system on a PC board is less severe
than in a noisy production environment.
ABSOLUTE MAXIMUM RATINGS
The Absolute Maximum Ratings table carries the maximum limits to
which the part can be subjected without damaging it … there is no
implication that the part will function at these extreme conditions.
FAST is a trademark of Fairchild Camera and Instrument Corporation.
June 1987
1
Philips Semiconductors
Application note
Testing and specifying FAST logic
AN202
supplied by the device in the case of charging line capacitance. The
Philips Semiconductors data sheet limits for IOS reflect the
conditions that the part will see in the system — full IOS spikes for
extremely short periods of time. Problems could occur if slow test
equipment or test methods ground an output for too long a time
causing functional failure or damage.
DC ELECTRICAL CHARACTERISTICS
This table reflects the DC limits used by Philips Semiconductors
during its testing operations and conducted under the conditions set
forth under the Recommended Operating Conditions table. VOH, for
example, is guaranteed to be no less than 2.7V when tested with
VCC = +4.75V, VIH = 2.0V, VIL = 0.8V, across the temperature range
from 0° to 70°C, and with an output current of IOH = –1.0mA. In this
table, one sees the heritage of the original junction isolated Schottky
family … VOL = 0.5V at IOL = 20mA. This gives the user a
guaranteed worst-case Low state noise immunity of 0.3V. In the
High state the noise immunity is 0.7V worst case. Although at first
glance it would seem one-sided to have greater noise immunity in
the High state than in the Low, this is a useful state of affairs.
Because the impedance of an output in the High state is generally
much higher than in the Low state, more noise immunity in the High
state is needed. This is because the noise source couples noise
onto the output connection of the device — that output tries to pull
the noise source down by sinking the energy to ground or to VCC
depending on the state. The ability of the output to do that is
determined by its output impedance. The lower half of the output
stage is a very low-impedance transistor which can effectively pull
the noise source down. Because of the higher impedance of the
upper stage of the output, it is not as effective in shunting the noise
energy to VCC, so that an extra 0.4V of noise immunity in the High
state compensates for the higher impedance. The result is a nice
balance of sink and drive current capabilities with the optimum
amount of noise immunity in both states.
AC TESTING
FAST data sheets carry several types of AC information. The AC
Characteristics table contains the guaranteed limits when tested
under the conditions set forth under the AC Test Circuits and
Waveforms. In some cases, the test conditions are further defined
by the AC Setup Conditions — this is generally the case with
counters and flip-flops where setup and hold times are involved. All
of the AC Characteristics are guaranteed with 50pF load
capacitances and with the fewest number possible of outputs
switching, depending upon the functionality of the device. One of the
sets of limits is specified at 25°C and +5.00V VCC — these relate
closely to the standard Schottky specification which are under
similar conditions but use only 15pF load capacitances. While these
numbers are convenient for comparing the two families, keep in
mind that using full 50pF loads with the Schottky devices would add
several nanoseconds to their propagation delays. These numbers
are ideal for checking out test jigs and correlating data since they do
not involve temperature or supply voltage spreads. For system
design, full specifications are included that include temperature and
supply voltage variations — in one case the military ranges and in
the other, the commercial ranges.
II, the maximum input current at maximum input voltage, is a
measure of the input leakage current at the guaranteed minimum
input breakdown voltage of 7.0V. Although some users consider this
to be a test of the input breakdown itself, that voltage is typically
over 15V. At room temperature, this leakage current should be less
than 10µA. (This is not the case with NPN input designated parts.)
AC TEST JIGS AND SETUPS
Each FAST data sheet spells out the test circuit used to check AC
performance, the waveforms, measurement points, rep rate, test
loads, etc., but these are only the quantifiable variables involved in
this testing. There is another more complex side to the issue — test
jigs and equipment setups.
Short-Circuit Output Current is a parameter that has appeared on
digital data sheets since the inception of integrated circuit logic
devices, but the meaning and implications of that specification
have totally changed. Originally, IOS was an attempt to reassure the
user that if a stray oscilloscope probe accidentally shorted an output
to ground the device would not be damaged. In this manner, an
extremely long time was associated with the IOS test. However,
thermally induced malfunctions could occur after several seconds of
sustained test. Over a period of time, IOS became a measure of the
ability of an output to charge line capacitance. Assume a device is
driving a long line and is in the Low state. When the output is
switched High, the rise time of the output waveform is limited by the
rate at which the line capacitance can be charged to its new state of
VOH. At the instant that the output switches, the line capacitance
looks like a short to ground. IOS is the current demanded by the
capacitive load as the voltage begins to rise and the demand
decreases. The full value of IOS need only be supplied for a few
hundred microseconds at most, even with 1.0µF of line capacitance
tied to the output, a load that is unrealistically high by several orders
of magnitude.
To get an appreciation for the problems involved in testing FAST,
consider these facts. The output rise and fall times on FAST outputs
are very sharp. Translating these edge rates into the effective sine
wave equivalents generates frequencies on the order of several
hundred MHz. At these frequencies, attention to RF phenomena is
required.
Because of these RF frequencies, it is necessary to have an AC test
jig that has minimal modifying effect on the input and output
waveforms. To do this, the jig must be constructed properly. The
following items are key in dealing with AC jig construction.
BYPASSING CAPACITORS
Philips Semiconductors uses high quality capacitors that have good
RF qualities to decouple the power supply lines on the test jig, right
at the VCC pin to the ground plane. Four capacitors with absolute
minimum lead length are used. Microwave chip capacitors are
recommended. (Note: In some sensitive test environments it is
advisable to decouple the VCC, as well as bypass. This is done by
passing the VCC through a wire wrapped around a ferrite core
6-8 times. The inductor created helps decouple the noise from VCC
and reduces dramatically the tendency for feedback oscillations
through the VCC and ground current loop. This is a key problem on
clocked parts since the ground bounce created by the fast edge
rates and high currents will effect VCC and ground substantially and
thereby effect internal thresholds.) These are one each, 10µF
dipped tantalum, 0.1µF dipped tantalum or chip, 0.001µF chip and
100pF chip.
The effective of a large IOS surge through the relatively small
transistors that make up the upper part of the output stage is not
serious, AS LONG AS THAT CURRENT IS LIMITED TO A SHORT
DURATION. If the hard short is allowed to remain, the full IOS
current will flow through that output state and may cause functional
failure or damage to the structure. A test induced failure may occur if
the IOS test time is excessive. As long as the IOS condition is very
brief, typically 50ms or less with automated test equipment, the local
heating does not reach the point where damage or functional
failures might occur. As we have already seen, this is considerably
longer than the time of the effective current surge that must be
June 1987
2
Philips Semiconductors
Application note
Testing and specifying FAST logic
AN202
GROUNDING
INTERCONNECTS
One of the biggest contributors to waveform degradation is improper
grounding. In reference to the test jig, the grounding is best done
with one or more large ground planes that are directly connected to
the ground pin of the test socket. The Philips Semiconductors AC
Test Jigs, both DIP and SO styles, are constructed as a four layer
PC board with the 2 internal layers as ground planes. Ground planes
are also interdigitated between all signal lines to decrease crosstalk.
There are holes drilled in these and they are plated through to
connect with the internal 2 layers and the top and bottom layers.
See Figure 3 to see the interdigitated ground planes on the PCB
layout of the SO jig. This grounding scheme has been used with
great success in 10k and 100k ECL fixturing. The board is laid out
so that the characteristic impedance of the signal lines is 50Ω. This
is done by using industry standard stripline techniques. The ground
plane also passes down through the center of the part on the bottom
side of the board and the ground pin is soldered to it using copper
wire to connect the pin and the ground plane. On the top side of the
board, the VCC plane goes through the center of the part too, and
connects to the VCC pin in like manner as the ground pin. See
Figure 1. As the VCC is brought on board, the VCC wire is wrapped
around a 1/2 inch ferrite core, 6-8 times, then makes connection with
the VCC plane on the top side.
The next concern is getting the input signal to the part and the
output signal to the measurement system. As stated before, the
Philips Semiconductors jig is laid out for a 50Ω characteristic
impedance. We recommend that the user maintain a 50Ω
environment for the input signal as close as possible to the input pin
and then terminate in 50Ω. On our jig, we terminate with a 50Ω chip
resistor. The signal is brought on board through an SMB connector
to the 50Ω trace on the top side of the board. The signal is
terminated by the chip resistor, R3, see Figure 2a and 2b. the signal
proceeds to the DUT pin, a distance of about 0.5 inches, through
Jumper 1 (in the Input Only position), and the rest of the trace. The
same pin on the opposite side of the board has a 450Ω chip resistor
soldered to it. The other side of this resistor, R1, is soldered to a
50Ω trace on the bottom side of the board that runs to an SMB
connector on the edge of the jig. This connects to the 50Ω input of
the Sampling Oscilloscope. This 450Ω resistor in series with the
50Ω input of the scope creates a 10X divided 500Ω probe for the
scope and provides impedance matching for the scope. See Figure
2b. This circuit also doubles as the resistive portion of the FAST AC
Output Load and thereby allows the output to be sensed in the same
fashion. When the input is not used for a signal or generator input,
the line may be switched to one of three voltage sources,
VS1 – VS3, by use of a DIP switch on each pin. It may also be left
open and the 50Ω pull-down resistor that is used for an input
terminator pulls the line to ground and can be used as a hard low
level. See Figure 2b. This scheme eliminates excessive cabling to
each input to provide static input levels and thereby reduces
parasitic inductances and cross-talk. It also eliminates the need for
bulky and sometimes unreliable high impedance probes by using the
50Ω input of the Sampling Scope. With the designed-in flexibility of
Jumper 1 and Jumper 2, and the selectable nature of VCC and
Ground pin designations, one can configure this board for any VCC
and Ground pin designations, select which pins are outputs or inputs
and even provide the proper pull-up for 3-State outputs. This makes
the board entirely universal for designated VCC/Ground
configurations. To explain this, the output of the device is connected
to its capacitive load by Jumper 1 in the Output Only position. This
means that no pin can be both output and input at the same time,
but can be either. Jumper 2 allows an output to be connected to the
3-State pull-up resistor, R2, and have that connected to the needed
7V. See Figure 2a and 2b. The scope is connected in the same way
as the input, with the 450Ω resistor and the 50Ω of the scope
comprising the 500Ω needed for the FAST load. One other
consideration exists. In small part quantity testing, the elimination of
a socket is very desirable, using inserted pins that are flush with the
jig. In larger quantity testing, sockets may be needed, however. If
this is the case, some degradation in the performance will occur due
to the increased lead inductance for each pin, which is observable,
and the addition of group delay through the socket may alter or
affect the readings obtained.
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VCC PIN
GROUND
PIN
DUT
VCC PLANE
SOLDER AND COPPER WIRE
GROUND PLANES
BYPASS
CAPACITORS
SOLDER AND
COPPER WIRE
SF01268
Figure 1.
June 1987
3
Philips Semiconductors
Application note
Testing and specifying FAST logic
AN202
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J1 (INPUT ONLY)
J2 (3-STATE)
DEVICE PIN
R1
450Ω
J1
(OUTPUT ONLY)
BOTTOM
SIDE
500Ω R2
PAD
(BOTH SIDES)
50Ω R3
TOP SIDE
GROUND
a. Board Layout
J1 (INPUT ONLY)
S1
V S1
PULSE
GENERATOR
R3
50Ω
R1
450Ω
V S2
V S3
VT (7V)
7V
DUT
50Ω
SCOPE
J3 (3-STATE)
R2
500Ω
J2
(OUTPUT ONLY)
C1
b. Schematic
SF01269
Figure 2. FAST AC Test Fixture
Frequency response also depends on the phase as well as the
magnitude of the impedance. If the phase changes so does the
delay, since delay is the derivative of phase change with frequency.
An S-parameter analysis is needed in evaluating jig performance.
HIGH-FREQUENCY DESIGN
The exact jig delay time is determined by the size of the universal jig
that is being used. It is important to know that the frequency
response of the jig must be High to prevent any delay factor from
varying with the edge rates. The frequency response of the jig
indicates how constant the impedance remains over frequency. The
characteristics impedance of a transmission line is expressed as:
ZO V I
UNIVERSAL JIG CONSTRUCTION
Jig universality is with respect to chip pin count and VCC and ground
pin placements and as such, separate universal test jigs are built for
14, 16, 20, 24, and 28 pin parts.
LO
CO
An S-parameter analysis was performed in a network analyzer to
optimize the jig layout. This assured that the jig had a flat frequency
response over the spectrum of interest for FAST products. Figure 2b
shows the schematic of the fixture and Figure 2a shows a drawing
of the board layout, component placement and signal paths. The
equipment used to analyze the jigs and loads was: HP8505A
Network Analyzer, HP8503A S-Parameter Test Set and HP8501A
Storage Normalizer. In some measurements the equipment was
driven by an HP9845B desk-top computer.
Where LO is the inductance per unit length, CO is the capacitance
per unit length, ZO is in Ohms, LO in Henrys, and CO in Farads.
Propagation velocity and its inverse, delay per unit length d, are also
expressed in LO and CO …
V
1
LOCO
L OC O
where δ is expressed in nanoseconds, LO is in microhenrys per unit
length, and CO in microfarads per unit length. From this, it is clear
that if the ZO changes over frequency, then the delay per unit length
will vary as well. Therefore, it is imperative to know how the jig
responds over frequency and that all measurement line lengths are
identical.
June 1987
Jigs produced in this way should have minimal lead length to reduce
the characteristic inductance. This in turn minimizes reflections with
their accompanying waveform distortions. and measurement
inaccuracies.
4
Philips Semiconductors
Application note
Testing and specifying FAST logic
AN202
The Philips Semiconductors FAST loads solve this problem by
reducing the load capacitor lead inductance by paralleling three
15pF chip capacitors. The resulting load is 45pF. At the same time,
since smaller value caps are used to build up the capacitive load,
the associated series resonant point is above 1.2GHz.
AC TEST LOADS FOR THE
PHILIPS SEMICONDUCTORS JIG
As stated previously, the Network Analyzer was also used to design
and optimize AC test loads to be used with the universal jig. FAST
product loads require 50pF load capacitance and 500Ω resistance to
ground.
The load resistors are 1/8W selected 510Ω ± 10Ω chip resistors.
Philips Semiconductors meets the 50pF requirement through the
use of a 45pF load, 4pF jig capacitance, and 3pF probe
capacitance. The result, 52pF, is slightly more stringent than
required.
The entire load assembly is constructed on the jig PCB along with
the input termination, and the jumpers which select an input or
output path. The load circuit is detailed on the FAST data sheets for
3-State parts.
A few words about load capacitors are in order. All capacitors have
an associated inductance. Due to this inductance, a capacitor will
form a series resonant circuit at some frequency. For single 50pF
capacitors, this typically occurs between 200 and 600MHz
depending on the type of capacitor. Above this resonant frequency,
the capacitor has inductive characteristics and does not present a
capacitive load. this is very important with FAST because harmonics
due to the sharp edge transition rates occur at 600MHz and above.
CORRELATION
While numerous ATE systems are available and are very efficient, it
is imperative that the ATE correlate to a user’s bench setup. Since
the Philips Semiconductors FAST parts are all characterized on the
setup described in this note, it is just as important that the user’s
bench jigs meet the same performance criteria. Without similar jigs,
it will be very difficult to correlate AC data.
Figure 3.
June 1987
5
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