5-3
CD4000B Series
This section is intended as a guide for circuit and equipment
designers in the operation and application of MOS inte-
grated circuits. It covers general operating and handling con-
siderations with respect to the following critical factors:
• Operating Supply Voltage Range
• Power Dissipation and Derating
• System Noise Considerations
• Power Source Rules
• Gate-oxide Protection Networks
• Input Signals and Ratings
• Chip Assembly and Storage
• Device Mounting
• Testing
More specific information is then given on significant fea-
tures, special design and application requirements, and
standard ratings and electrical characteristics for CMOS B-
series logic circuits, and on CMOS special function circuits
(special interface and display driver circuits).
General Operating and Handling
Considerations
The following paragraphs discuss some key operating and
handling considerations that must be taken into account to
achieve maximum advantage of the CMOS technology.
Additional information on the operation and handling of
CMOS integrated circuits is given in Application Note
AN6525, “Guide to Better Handling and Operation of CMOS
Integrated Circuits”. See Section 8, “How to Use Answer-
FAX”, in this selection guide.
Operating Supply Voltage Range
Because logic systems occasionally experience transient con-
ditions on the power supply line which, when added to the
nominal power-bus voltage, could exceed the safe limits of cir-
cuits connected to the power bus, the recommended operat-
ing supply voltage range is 3V to 18V for B-series devices.
The recommended maximum power supply limit is substan-
tially below the minimum primary breakdown limit for the
devices to allow for limited power supply transient and regula-
tion limits. For circuits that operated in a linear mode over a
portion of the voltage range, such as RC or crystal oscillators,
a minimum supply voltage of 4V is recommended.
Power Dissipation and Derating
The power dissipation of a CMOS integrated circuit is the
sum of a DC (quiescent) component and an AC (dynamic)
components. The DC component is the sum of the net inte-
grated circuit reverse diode junction current and the surface
leakage current times the supply voltage. In standard B-
series logic devices, the DC dissipation typically ranges,
depending upon device complexity, from 100nW to 400nW
for a supply voltage of 10V. Worst-case DC dissipation is the
product of the maximum quiescent current (given in the data
sheet on each device) and the DC supply voltage VDD.
Dynamic power dissipation has three components:
1. The dissipation that results from current that charges and
discharges the external load capacitance of the output
buffers. The dissipation of each output buffer is equal to
CV2f, where C is the load capacitance, V is the supply
voltage, and f is the switching frequency of that output.
2. The dissipation that results from current that charges and
discharges the internal node capacitances.
3. The dissipation caused by the current spikes through the
PMOS and NMOS transistors in series at the instant of
switching. This component amounts to approximately
10% of the total dissipation, shown graphically in the
datasheets of most CMOS circuits.
All CMOS devices are rated at 200mW per package at the
maximum operating ambient temperature rating (TA) of
125oC for all packages. Power ratings for temperatures
below the maximum operating temperature are shown in the
standard CMOS thermal derating chart in Figure 1. This
chart assumes that the device is mounted and soldered (or
placed in a socket) on a PC board; there is natural convec-
tion cooling, with the PC board mounted horizontally; and
the pressure is standard (14.7psia). In addition to the overall
package dissipation, device dissipation per output transistor
is limited to 100mW maximum over the full package operat-
ing temperature range.
FIGURE 1. STANDARD CMOS THERMAL DERATING CHART
System Noise Considerations
In general, CMOS devices are much less sensitive to noise
on power and ground lines than bipolar logic families (such
as TTL or DTL). However, this sensitivity varies as a function
of the power supply voltage, and more importantly as a func-
tion of synchronism between noise spikes and input transi-
tions. Good power distribution in digital systems requires
that the power bus have a low dynamic impedance; for this
purpose, discrete decoupling capacitors should be distrib-
uted across the power bus. A more detailed discussion of
CMOS noise immunity is provided by Application Note
AN6587, “Noise Immunity of B-series CMOS Integrated Cir-
cuits”. See Section 8, “How to Use AnswerFAX”, in this
selection guide.
20 40 60 80 100 120
TA, AMBIENT TEMPERATURE (oC)
600
500
400
300
200
100
PACKAGE DISSIPATION (mW)
85 125
SLOPE = 12mW/oC
Technical Overview
5-4
Technical Overview
Power Source Rules
Figure 2 shows the basic CMOS inverter and its gate-oxide
protection network plus inherent diodes. The safe operating
procedures listed below can be understood by reference to
this inverter.
NOTES:
1. These Diodes are inherently part of the manufacturing process.
2. Diode Breakdown
D1 ≈ 25V
D2 ≈ 50V
R2 << R1
FIGURE 2. BASIC CMOS INVERTER WITH B-SERIES TYPE
PROTECTION NETWORK
1. When separate power supplies are used for the CMOS
device and for the device inputs, the device power supply
should always be turned on before the independent input
signal sources, and the input signals should be turned off
before the power supply is turned off (VSS ≤ VI≤ VDD as
a maximum limit). This rule will prevent over dissipation
and possible damage to the D2 input protection diode
when the device power supply is grounded. When the de-
vice power supply is an open circuit, violation of this rule
can result in undesired circuit operation although device
damage should not result: AC inputs can be rectified by
diode D2 to act as a power supply.
2. The power supply operating voltage should be kept safely
below the absolute maximum supply rating, as indicated
previously.
3. The power supply polarity for CMOS circuits should not be
reversed. The positive (VDD) terminal should never be
more than 0.5V negative with respect to the negative
(VSS) terminal (VDD - VSS > -0.5V). Reversal of polarities
will forward-bias and short the structural and protection
diode between VDD and VSS.
4. VDD should be equal to or greater than VCC for CMOS
buffers which have two power supplies (except for the
CD40109B, and in particular, for CD4009 and CD4010
CMOS-to-TTL “down” conversion devices).
5. Power source current capability should be limited to as
low a value as reasonable to assure good logic operation.
6. Large values of resistors in series with VDD or VSS should
be avoided; transient turn-on of input protection diodes
can result from drops across such resistors during
switching.
Gate-Oxide Protection Network
A problem occasionally encountered in handling and testing
low power semiconductor devices, including MOS and small
geometry bipolar devices, has been damage to gate oxide
VDD
IN
OUT
D2
R1
D1 D1
D2D2
R2
D1
VSS
D1
D1
COS/MOS
(NOTE 1)
(NOTE 1)
and/or P-N junctions. Figure 3 shows the gate-oxide protec-
tion circuits used to protect CMOS devices from static elec-
tricity damage. Application Note AN6525, “Guide to Better
Handling and Operation of CMOS Integrated Circuits”. See
Section 8, “How to Use AnswerFAX”, in this selection guide.
FIGURE 3A. FOR B-SERIES CMOS PRODUCT
FIGURE 3B. FOR CD4049UB AND CD4050B AND CD40109B
CMOS TYPES
FIGURE 3C. FOR CMOS TRANSMISSION GATES
NOTES:
1. These Diodes are inherently part of the manufacturing process.
2. VCC for CD4049UB and CD4050B
3. Diode Breakdown
D1 ≈ 25V
D2 ≈ 50V
FIGURE 3. GATE-OXIDE PROTECTION NETWORKS USED IN
HARRIS CMOS INTEGRATED CIRCUITS
VDD
IN
OUT
VSS
(NOTE 1)
(NOTE 1)
IN
OUT
VDD (NOTE 2)
VSS
(NOTE 1)
(NOTE 1)
CD4049UB
CD40109B
CD4050B
VDD
VSS
P-WELL
IN/OUT OUT/IN
D1 (NOTE 1)
D2 (NOTE 1)
(NOTE 1) D1
(NOTE 1) D2
GATE 1
GATE 2
N-SUB
5-5
Technical Overview
Input Signals and Ratings
Input signals should be maintained with in the power supply
voltage range, VSS ≤ VI≤ VDD. If the input signal exceeds the
recommended input signal swing range, the input current
should be limited to ±100µA to minimize cross talk between
input signals on adjacent terminals, and also to minimize any
reduction in noise immunity.
The absolute maximum input current rating of ±10mA, shown
in the published data, protects the device against the possible
occurrence of an induced VDD - VSS latch condition, or dam-
age to the input protection diodes. Latch-up conditions are
explained in Application Note AN6525, “Guide to Better Han-
dling and Operation of CMOS Integrated Circuits”. See Sec-
tion 8, “How to Use AnswerFAX”, in this selection guide.
ALL CMOS inputs should be terminated. An exception can
be made in the case of unbuffered NOR and NAND gates
where terminating one of the series inputs to the proper
polarity will not permit current flow caused by a floating
input. Thus tying low one of the inputs of an unbuffered
NAND gate, or tying high one of the inputs of an unbuffered
NOR gate will satisfy this requirement.
When CMOS inputs are wired to edge card connectors with
CMOS drive coming from another PC board, a shunt resistor
in the range of 100kW should be connected to VDD or VSS,
as applicable, in case the inputs become unterminated with
the power supply on.
When CMOS circuits are driven by TTL logic, a “pull-up”
resistor should be connected from the CMOS input to 5V
(further information is given in Application Note AN6602,
“Interfacing COS/MOS with Other Logic Families”, See Sec-
tion 8, “How to Use AnswerFAX”, in this selection guide.
Output Rules
1. The power dissipation in a CMOS package should not ex-
ceed the rated value for the ambient temperature speci-
fied. The actual dissipation should be calculated when
shorting outputs directly to VDD or VSS, driving low im-
pedance loads, or directly driving the base of P-N-P or
N-P-N bipolar transistor.
2. Output short circuits often result from testing errors or im-
proper board assembly. Shorts on buffer outputs or
across power supplies greater than 5V can damage
CMOS devices.
3. CMOS, like active pull-up TTL, can be connected in the
“wire-OR” configuration because an “on” PMOS and an
“on” NMOS transistor could be directly shorted across the
power supply rails. (Exception: CD40107B)
4. Paralleling inputs and outputs of gates is recommended
only when the gates are within the same IC package.
5. Output loads should return to a voltage within the supply
voltage range VDD to VSS.
6. Large capacitive loads (greater than 5000pF) on CMOS
buffers or high current drivers act like short circuits and
may over dissipate output transistors.
7. Output transistors may be over dissipated by operating
buffers as linear amplifiers or using these types as one
shot or astable multivibrators.
Noise immunity and Noise Margin
The complementary structure of the inverter, common to all
CMOS logic devices, results in a near-ideal input-output
transfer characteristic, with switching point midway (45% to
55%) between the 0 and 1 output logic levels. The result is
high DC noise immunity.
Figure 4 shows a typical transfer curve that may be used to
define the DC noise immunity of CMOS integrated circuits.
The noise immunity voltage (VIL or VIH) is the noise voltage
at any one input that does not propagate through the sys-
tem. Minimum noise immunity for buffered B-series CMOS
devices is 30%, 30%, and 27%, respectively for supply volt-
ages VDD of 5V, 10V, 15V and 20% of VDD for all unbuffered
gates. The VIL and VIH specifications define the maximum
permissible additive noise voltage at an input terminal when
input signals are within 50mV of the supply rails.
FIGURE 4. TYPICAL TRANSFER CURVE FOR A INVERTING
GATE AT VDD = 10V
Noise margin is the difference between the noise-immunity
voltage (VIL or VIH) and the output voltage VO. Noise margin
voltage is the maximum voltage that can be impressed upon
an input voltage VIN (where VIN is the VOL or VOH voltage of
the preceding stage) at any (or all) logic I/O terminals with-
out upsetting the logic or causing any output to exceed the
output voltage (VO) conditions specified for VIL and VIH rat-
ings. Figure 5 illustrates the noise margin concept in a sim-
ple system. Minimum noise margins for buffered B-series
CMOS devices are 1V, 2V, and 2.5V, respectively, for supply
voltages 5V, 10V, and 15V.
FIGURE 5. NOISE MARGIN EXAMPLE USING INVERTERS
VIL MAX VIH MIN
VIN
10
9
8
7
6
5
4
3
2
1
VIL (TYP)
VO(HIGH)
VOUT
VO(LOW)
VNML = VIL (MAX) - VO(LOW)
VNML = VO(HIGH) - VIH (MIN)
VIH TYP
012345678910
V
IH = 3.5V VOL = 0.5V
VDD = 5V VOL = 0.5V
VNML = 1V
VIL = 1.5V
VOH = 4.5V
VNML = 1V
VIH = 3.5V
5-6
Technical Overview
Of the two noise limitation specifications (noise immunity
and noise margin), noise immunity is more practical for
CMOS devices because CMOS outputs are normally within
50mV of supply rails.
Noise immunity increases as the input pulse width becomes
less than the propagation delay of the circuit. This condition
is often described as AC noise immunity. Further information
on noise immunity is given in Application Note AN6587,
“Noise Immunity of B-series CMOS Integrated Circuits”. See
Section 8, “How to Use AnswerFAX”, in this selection guide.
Clock Rise and Fall Time Requirements
Most CMOS clocked devices have maximum rise and fall
time ratings (normally 5ms to 15ms). With longer rise or fall
times, a device may not function properly because of data
ripple through, false triggering problems, etc. Some B-series
CMOS counters have Schmitt-trigger shaping circuits built
into the clock circuit, removing the restriction for input rise or
fall times. Long rise and fall times on CMOS buffer-type
inputs cause increased power dissipation which may exceed
device capability for operating power supply voltages greater
than 5V.
Parallel Clocking
Process variations leading to differences in input threshold
voltage among random device samples can cause loss of
data between certain synchronously clock sequential cir-
cuits, as shown in Figure 6. This problem can be avoided if
the maximum clock rise time (tRCL) for cascading any two
CMOS sequential devices is limited in accordance with the
following equation:
B-Series Types
where tP = tPHL or tPLH (whichever is smaller) for the unit A in
Figure 6 as specified on the device data sheet at the speci-
fied value of VDD and loading conditions. Schmitt-trigger cir-
cuits such as the CD4093B are an ideal solution to
applications requiring wave-shipping.
FIGURE 6. ERROR EFFECT THAT RESULTS FROM A SLOW
CLOCK IN CASCADED CIRCUITS
Maximum tRCL
0.8VDD V()
1.15V
------------------------------- tP
×ns()=
C
L
C
L
Q1
Q2
VDD
SWITCHING POINT = 0.3VDD
SWITCHING POINT = 0.7VDD
PROPER
ERROR
DQ1 B
Q2
D
A
0.3VDD
0.7VDD
NOTE: CASCADING WITH SLOW
CLOCK CAN CAUSE ERROR
Three-State Logic
Three-state logic can be easily implemented by use of a
transmission gate in the output circuit; this technique pro-
vides a solution to the wire-OR problem in many cases.
Chip Assembly and Storage
Harris CMOS integrated circuits are provided in a chip from
(H suffix) to allow customer design of special and complex
circuits to suit individual needs. CMOS chips are electrically
identical to and offer the features of their counterparts
sealed in ceramic and plastic packages. The following para-
graphs describe mounting considerations, packaging, ship-
ping and storage criteria, handling criteria, visual inspection
criteria, testing criteria, and bonding pad layout and dimen-
sions for each chip.
Mounting Considerations
All CMOS chips are non-gold backed and require the use of
epoxy mounting, conductive silver paste or equivalent is rec-
ommended. In any case the manufacturer’s recommenda-
tions for storage and use should be followed.
In CMOS circuits MOS-transistor P-channel substrates (N-
type bulk material) are connected to VDD, therefore, when
chips are mounted and a conductive paste is used, care
must be taken to keep the active substrate isolated from
ground or other circuit elements.
Packing, Shipping, and Storage Criteria
Solid-state chips, being small in size and unencapsulated,
are physically fragile and require special handling consider-
ation as follows:
• Chips must be stored under proper conditions to insure that
they are not subjected to a moist and/or contaminated atmo-
sphere that could alter their electrical, physical, or mechani-
cal characteristics. After the shipping container is opened,
the chip must be stored under the following conditions:
- Storage Temperature, 40oC Max
- Relative Humidity, 50% Max
- Clean, Dust-Free Environment
• The user must exercise proper care when handling chips
to prevent even the slightest physical damage to the chip.
• During mounting and lead bonding of chips the user must
use proper assembly techniques to obtain proper electri-
cal, thermal, and mechanical performance.
• After the chip has been mounted and bonded, any neces-
sary procedure must be followed by the user to insure that
these non-hermetic chips are not subjected to a moist and
contaminated atmosphere which might cause the develop-
ment of electrical conductive paths across the relatively
small insulating surfaces. In addition, proper consideration
must be given to the protection of these devices from
other harmful environments which could conceivably affect
their performance and/or reliability.
Handling Criteria
The user should find the following suggested precautions
helpful in handling CMOS chips.
5-7
Technical Overview
Because of the extremely small size and fragile nature of
chips, the equipment designer should exercise care in han-
dling these devices.
For additional handling considerations for CMOS devices,
refer to Application Note AN6525, “Guide to Better Handling
and Operation of CMOS Integrated Circuits”. See Section 8,
“How to Use AnswerFAX”, in this selection guide.
• Grounding
- Bonders, pellet pick-up tools, table tops, trim and form
tools, sealing equipment, and other equipment used in
chip handling should be properly grounded.
- The operator should be properly grounded.
• In-Process Handling
- Assemblies or subassemblies of chips should be trans-
ported and stored in conductive carriers.
- All external leads of the assemblies or subassemblies
should be shorted together.
• Bonding Sequence
- Connect VDD first to external connections, for example,
terminal 14 of the CD4001BH.
- Remaining functions may be connected to their external
connections in any sequence.
• Testing
- Transport all assemblies of chips in conductive carriers.
- In testing chip assemblies or subassemblies, the opera-
tor should be properly grounded.
Visual Inspection Criteria
All standard commercial CMOS chips undergo a visual inspec-
tion which is patterned after MIL-STD-883, Method 2010, Con-
dition B with modifications reflecting CMOS requirements.
Testing Criteria
CMOS chips are DC electrically tested 100% in accordance
with the same standards prescribed for Harris devices in
standard packages.
Device Testing
Harris CMOS circuits are 100% tested by circuit probe in the
wafer stage and are 100% tested again after they have been
packaged. DC tests of Harris devices are performed at 5V,
10V, 15V, and 20V; functionality is checked at 2.8V, 17V, and
20V. Sample testing is used to assure adherence to quality
requirements and AC specifications.
Static test, high speed functional and DC parametric tests,
are performed at wafer and package stages by means of a
Teradyne 325 test set or equivalent.
Users should follow the sequences below when testing
CMOS devices:
1. Insert the device into the test socket.
2. Apply VDD.
3. Apply the input signal.
4. Perform the test.
5. On completion of test, remove the input signal.
6. Turn off the power supply (VDD).
7. Remove the device from the test socket and insert it into
a conductive carrier. CMOS devices under test must not
be exposed to electrostatic discharge or forward biasing
of the intrinsic protective diodes shown in Figure 3.
Detailed information on the techniques employed in the test-
ing of Harris CMOS integrated circuits are described in
Application Note AN6532, “Fundamentals of Testing CMOS
Integrated Circuits”. See Section 8, “How to Use Answer-
FAX”, in this selection guide.
Device Mounting
Integrated circuits are normally supplied with lead-tin plated
leads to facilitate soldering into circuit boards. In those rela-
tively few applications requiring welding of the device leads,
rather than soldering, the devices may be obtained with
nickel-plated Kovar leads (See MIL-I-38535). It should be
recognized that this type of plating will not provide complete
protection against lead corrosion in the presence of high
humidity and mechanical stress.
In any method of mounting integrated circuits which involves
bending or forming of the device leads, it is extremely impor-
tant that the lead be supported and clamped between the
bend and the package seal, and that bending be done with
care to avoid damage to lead plating. In no case should the
radius of the bend be less than the diameter of the lead. It is
also extremely important that the ends of bent leads be
straight to assure proper insertion through the holes in the
printed-circuit board.
High Voltage B-Series CMOS
Integrated Circuits
Harris CD4000B series types have a maximum DC supply
voltage rating of -0.5V to 20V, and a recommended operat-
ing supply voltage range of 3V to 18V. The major features of
this series are as follows:
• High Voltage (20V) Ratings
• 100% Tested for Quiescent Current at 20V
• 5V, 10V, and 15V Parametric Ratings
• Standardized, Symmetrical Output Characteristics
• Maximum Input Current of 1µA at 18V Over Full Package
Temperature Range; 100nA at 18V and 25oC
• Noise Margin (Full Package Temperature Range) =
1V at VDD = 5V
2V at VDD = 10V
2.5 V at VDD = 15V
• Meets all requirements of JEDEC Tentative Standard No.
13B, “Standard Specifications for Description of B-Series
CMOS Devices”.
JEDEC Minimum Standard
Under the sponsorship of the Joint Electron Devices Engi-
neering Council (JEDEC) of the Electronic Industries Associ-
ation (EIA), minimum industrial standards have been
established for the maximum ratings, DC and AC electrical
5-8
Technical Overview
characteristics of B-series CMOS integrated circuits. The
JEDEC standard (JEDEC Tentative Standard No. 13B)
defines B-series CMOS integrated circuits as a uniform fam-
ily of both buffered and unbuffered types that have an abso-
lute DC supply voltage rating of at least 18V.
Buffered CMOS Devices
These are types in which the output “on” impedance is inde-
pendent of any and all valid input logic conditions, both pre-
ceding and present. All such CMOS products are designated
by suffix “B” following the basic type number.
Unbuffered CMOS Devices
These are types that meet all B-series specifications except
that the logical outputs are not buffered and the noise-immu-
nity voltages, VIL and VIH, are specified as 20% and 80%,
respectively, of VDD for operation from 5V, 10V, and 17V and
83%, respectively, of VDD for operation from 15V. All such
CMOS product are designated by the suffix “UB”.
The JEDEC minimum standard also includes in the B-series,
CMOS types that have analog inputs or outputs and in addi-
tion, have maximum ratings and logical input and output
parameters that conform to B-series specifications wherever
applicable. These CMOS devices are also designated by the
suffix “B”.
All B-series CMOS devices can directly replace their A-series
counterparts in most applications. The UB types are high volt-
age versions of corresponding A-series (unbuffered) types.
Commercial A-series types have been obsoleted and
replaced by B-series counterparts with only a few exceptions
such as the continuing CD4059A types.
The Absolute Maximum Rating - JEDEC table lists the
minimum standards established for the maximum ratings
and recommended operating conditions for B-series CMOS
integrated circuits.
The DC Electrical Specification - JEDEC table shows the
JEDEC standards for the DC electrical specifications of
CMOS B-series integrated circuits.
Standardized Ratings and Static Characteristics
Harris B-series CMOS integrated circuits meet or exceed the
most stringent requirements of the JEDEC B-series specifi-
cations. The Absolute Maximum Ratings table shows the
standardized maximum ratings and recommended operating
supply voltage range for Harris B-series CMOS integrated
circuits. The standardized DC electrical specifications for
these devices are shown in the DC Electrical Specification
table. As with the JEDEC specifications, the Harris standard-
ized characteristics classify the B-series devices into three
leakage (quiescent device current) categories. Table 1 lists
the Harris types in each category and indicates types that,
although they are still B-series types, differ in one or more
static characteristics.
The Absolute Maximum Ratings table and the DC Electri-
cal Specification table show that in a number on important
respects, Harris has established new performance stan-
dards for B-series CMOS logic circuits.
• Tight Limits For All Packages
Harris devices used the same set of limits for all package
styles. The JEDEC standard establishes two sets of limits
for most DC parameters; a tight set for products having a
full operating temperature range of -55oC to +125oC (all
Harris devices), and a relaxed set for products having a
limited temperature range of -40oC to +85oC. Because
Harris supplies only one premium grade of B-series prod-
uct in all package styles (i.e., fall-out chips are not used),
all B-series CMOS devices are specified to the tight set of
limits only.
• Improved Voltage Rating
All Harris B-series devices are tested to voltages that
insure safe operation at the absolute maximum DC supply
voltage rating of 20V. This higher rating permits greater
derating for reliable 15V operation, permits greater 15V
supply tolerance and peak transients, and permits system
use to 18V with confidence.
• Wider Operating Range
All Harris B-series devices have a recommended maxi-
mum operating voltage of 18V. The higher limit permits
18V system supply operation, and also permits wider
power source tolerance and transients for supplies nor-
mally set up to 18V
• Lower Leakage Current
The JEDEC standard establishes three sets of limits for
quiescent device current (IDD) intended to match chip
complexity to device leakage current as realistically as
possible.
For all three levels of chip complexity, all Harris B-series
devices (regardless of package) conform to the tighter set
of limits established in the standard. In addition, a maxi-
mum rating is specified at 20V, as well as at 5V, 10V, and
15V. As a result:
- In current limited applications, CMOS users can depend
on one tight leakage limit independent of package style
selected.
- Customer use of CMOS product up through 18V is pro-
tected by a published tight leakage current specification at
20V (as well as by an input leakage specification at 18V).
• Symmetrical Output
Most Harris B-series devices have balanced complemen-
tary output drive (i.e., the output high current IOH rating is
the same as the output low current IOL rating specified to
the tighter set of limits established in the JEDEC standard.
The balanced output provides uniform rise and fall time
performance, improved system noise energy (dynamic)
immunity, optimum device speed for both output switching
low-to-high (tPLH) and output switching high-to-low (tPHL),
and in general the identical high and low DC and AC char-
acteristics normally associated with a good complemen-
tary output drive circuit. MOS system design, simulation,
and performance are significantly enhanced by equal high
and low DC and AC performance ratings and one tight
specification limit for all package styles.
5-9
• Improved Input Current (Leakage) Ratings
All Harris B-series devices (regardless of package) have a
maximum input leakage current (IIN) rating of 100nA spec-
ified at voltages up to 18V, and a maximum limit of 1µA at
the upper limit of the package temperature range. Actually,
the 100nA rating is a practical specification limited by the
inability of commercial test equipment to measure lower
currents. Laboratory tests show that input leakage cur-
rents of Harris B-series CMOS devices are significantly
lower than this limit, typically ranging from 10pA to 100pA.
• Buffered and Unbuffered Gates
The new industry standard establishes a suffix “UB” for
CMOS products that meet all B-series specifications
except that the logical outputs of the devices are not buff-
ered and the VIL and VIH specifications are relaxed. The
suffix “B” defines only buf fered output devices in which the
output “on” impedance is independent of any and all valid
input logic conditions, both preceding and present.
Harris supplies both buffered “B” and unbuffered “UB” ver-
sions of a few popular NOR and NAND gates to make
available to designers the advantages of both. The follow-
ing table briefly compares the features of the two versions,
a more detailed coverage of the special features of B- and
UB- series CMOS gates is provided by Application Note
AN6558, “Understanding Buffered and Unbuffered CMOS
Characteristics”. See Section 8, “How to Use AnswerF AX”,
in this selection guide.
•Reliability
Harris B-series CMOS integrated circuits incorporate the
latest improvements in processing technology and plastic
and ceramic packaging techniques. Product quality is real
time controlled using accelerated temperature group qual-
ity screening in which measured DC parameters are criti-
cized against tight B-series limits.
Figure 7 through Figure 10 show the standardized N- and
P-channel drain characteristics for B-series CMOS
devices, and Figure 11 through Figure 14 show the nor-
malized variation of output source and sink currents with
respect to temperature and voltage in these devices.
COMPARISON OF “B” AND “UB”
CHARACTERISTIC BUFFERED
VERSION “B” UNBUFFERED
VERSION “UB”
Propagation Delay
(Speed) Moderate Fast
Noise Immunity/Margin Excellent Good
Output Impedance and
Output Transition Time Constant Variable
AC Gain High Medium
Output Oscillation for
Slow inputs Yes No
Input Capacitance Low High
FIGURE 7. TYPICAL OUTPUT LOW (SINK) CURRENT
CHARACTERISTICS FIGURE 8. MINIMUM OUTPUT LOW (SINK) CURRENT
CHARACTERISTICS
FIGURE 9. TYPICAL OUTPUT HIGH (SOURCE) CURRENT CHARACTERISTICS
30
25
20
15
10
5
051015
V
DS, DRAIN-TO-SOURCE VOLTAGE (V)
IOL, OUTPUT LOW (SINK) CURRENT (mA)
35
20
AMBIENT TEMPERATURE, TA = 25oC
GATE-TO-SOURCE VOLTAGE, VGS = 15V
5V
10V
15
12.5
10
7.5
5
2.5
051015
V
DS, DRAIN-TO-SOURCE VOLTAGE (V)
IOL, OUTPUT LOW (SINK) CURRENT (mA)
20
GATE-TO-SOURCE VOLTAGE, VGS = 15V
10V
5V AMBIENT TEMPERATURE, TA = 25oC
-30
-25
-20
-15
-10
-5
0
IOH, OUTPUT HIGH (SOURCE) CURRENT (mA)
GATE-TO-SOURCE VOLTAGE, VGS = -5V
VDS, DRAIN-TO-SOURCE VOLTAGE (V)
-5-10-15-20
-10V
-15V
AMBIENT TEMPERATURE, TA = 25oC
Technical Overview
5-10
FIGURE 10. MINIMUM OUTPUT HIGH (SOURCE) CURRENT
CHARACTERISTICS FIGURE 1 1. V ARIA TION OF NORMALIZED OUTPUT LOW (SINK)
CURRENT IOL AND OUTPUT HIGH (SOURCE)
CURRENT IOH WITH TEMPERATURE
FIGURE 12. VARIATION OF NORMALIZED OUTPUT LOW (SINK)
CURRENT IOL AND OUTPUT HIGH (SOURCE)
CURRENT IOH WITH SUPPLY VOLTAGE
FIGURE 13. VARIATION OF LOW-TO-HIGH (tTLH) AND HIGH-TO-
LOW (tTHL) TRANSITION TIME, AND LOW-TO-HIGH
(tPHL) PROPAGATION DELAY TIME WITH
TEMPERATURE
FIGURE 14. VARIATION OF LOW-TO-HIGH (tTLH) AND HIGH-TO-
LOW (tTHL) TRANSITION TIME WITH SUPPLY
VOLTAGE
FIGURE 15. VARIATION OF TRANSITION TIME (tTHL, tTLH) WITH
LOAD CAPACITANCE
-15
-10
-5
0
IOH, OUTPUT HIGH (SOURCE) CURRENT (mA)
AMBIENT TEMPERATURE, TA = 25oC
-10V
-15V
VDS, DRAIN-TO-SOURCE VOLTAGE (V)
-5-10-15-20
GATE-TO-SOURCE VOLTAGE, VGS = -5V 2
1
-100 -50 0 50 100 150
TA, AMBIENT TEMPERATURE (oC)
NORMALIZED SINK, IOL, AND
SOURCE, IOH, CURRENT
1.4
1.2
1
0.8
0.6
0.4
0.2 051015
V
DD, SUPPLY VOLTAGE (V)
NORMALIZED SINK, IOL, AND
SOURCE, IOH, CURRENT
-100 -75 -50 -25 0 25 50 75 100 125
NORMALIZED TRANSITION TIME, tTHL, t TLH, AND
PROPAGATION DELAY TIME, tPHL, tPLH
1.4
1.2
1
0.8
0.6
TA, AMBIENT TEMPERATURE (oC)
VDD, SUPPLY VOLTAGE (V)
4
3.5
3
2.5
2
1.5
1
0.5 0 2 4 6 8 10 12 14 16
NORMALIZED LOW-TO-HIGH, tTLH, AND
HIGH-TO-LOW , tTHL, TRANSITION TIME
AMBIENT TEMPERATURE, TA = 25oC
tTHL, tTLH, TRANSITION TIME (ns)
CL, LOAD CAPACITANCE (pF)
020406080
50
100
150
200
AMBIENT TEMPERATURE, TA = 25oC
VDD, SUPPLY VOLTAGE = 5V
100
10V
15V
Technical Overview
5-11
Technical Overview
B-Series AC Electrical Specifications
B-series AC electrical specifications for individual types are
under the following conditions: VDD = 5V, 10V, and 15V;
TA= +25oC; CL = 50pF; RL = 200kΩ; tR and tF = 20ns. Figure
13 shows the variation of B-series AC parameter with temper-
ature. Figure 14 shows the variation of output transition time
with supply voltage. Figure 17 shows the variation of the stan-
dardized output transition time with load capacitance.
Maximum propagation delay or transition times for values of
CL other than the specified 50pF can be determined by use
of the multiplication factor (usually 2) between the typical
and maximum values given in the AC specifications chart
included in the technical data for each device applied to the
typical curves, and also shown in the device technical data.
B-Series AC Switching Specifications
The AC Electrical Specification table defines the major
CMOS AC specifications, with reference to the waveforms
shown in Figure 16 through Figure 19. Test conditions of
VDD, low capacitance (CL), and input conditions are given for
individual types in the published data.
CMOS Special Products
Harris supplies some special CMOS products that have
operating supply voltage ranges and other characteristics
that differ from the standardized data specified for B-series
CMOS integrated circuits.
These special application types include: interface circuits for
level shifting applications to interface CMOS logic levels with
different logic types; display drivers non-multiplexed, 4 digit,
7 segment LCD types containing all the circuitry necessary
for driving conventional LCD displays without the need for
external components, and a video sync generator function.
FIGURE 16. TRANSITION TIMES AND PROPAGATION DELAY
TIMES, COMBINATION LOGIC
NOTE: Outputs should be switching from 10% VDD to 90% VDD in
accordance with the device truth table.
FIGURE 17. CLOCK PULSE RISE AND F ALL TIMES AND PULSE
WIDTH
tPHL tPLH
tTHL tTLH
90%
50%
10%
50%
10%
INVERTING
OUTPUT
INPUT
GND
VDD
tRtF
90% VDD
CLOCK 90% 50%
10% GND
VDD
tRCLtFCL
50% 50%
tWL tWH
10%
tWL + tWH =fCL
1
FIGURE 18A.
FIGURE 18B.
FIGURE 18. THREE-STATE PROPAGATION DELAY WAVE
SHAPES AND TEST CIRCUIT
NOTE:
1. (H) or (L) Optional
FIGURE 19. SETUP TIMES, HOLD TIMES, REMOVAL TIME, AND
PROPAGATION DELAY TIMES FOR EDGE
TRIGGERED SEQUENTIAL LOGIC CIRCUITS
50% 10%
90%
VSS
VDD
10%
90% 50%
50%
OUTPUT
DISABLE
OUTPUT LOW
TO OFF
OUTPUT HIGH
TO OFF
OUTPUTS
CONNECTED OUTPUTS
DISCONNECTED OUTPUTS
CONNECTED
20ns 20ns
tPHZ
tPLZ VDD
VOL
VOH
VSS
90%
10%
tPZH
tPZL
IC WITH
THREE-
STATE
OUTPUT
OTHER
INPUTS
OUTPUT
DISABLE
VDD FOR tPLZ AND tPZL
VSS FOR tPHZ AND tPZH
OUTPUT
RL = 1kΩ
CL
50pF
tRCLtFCL
GND
VDD
GND
VDD
50%
90%
10%
GND
CLOCK
INPUT
DATA
INPUT
OUTPUT
SET, RESET
OR PRESET
VDD
50%
50%50%
50%
90%
10%
50%
90%
tREM
tPLH
tSU(H)
(NOTE 1)
tSU(L) (NOTE 1)
tTLH tTHL
tH(L)
(NOTE 1)
tH(H)
(NOTE 1)
tPHL
GND
VDD
5-12
Family Ratings and Specifications‡
Absolute Maximum Ratings JEDEC Standard for DC Specifications of B-Series CMOS Integrated Circuits (Note 1 and Note 2)
DC Supply Voltage, VDD . . . . . . . . . . . . . . . . . . . . . . -0.5V to +18V
DC Input Voltage, VIN . . . . . . . . . . . . . . . . . . . . -0.5V to VDD +0.5V DC Input Current, IIN (For Any One Input). . . . . . . . . . . . . . . . . .±10mA
Storage Temperature, TS . . . . . . . . . . . . . . . . . . . .-65oC to +150oC
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
Recommended Operating Conditions
DC Supply Voltage, VDD . . . . . . . . . . . . . . . . . . . . . . . +3V to +15V Operating Temperature Range, TA . . . . . . . . . . . . .-55oC to +125oC
DC Electrical Specification JEDEC Standard for DC Specifications of B-Series CMOS Integrated Circuits
PARAMETERS SYMBOL TEST
CONDITIONS TEMP.
RANGE VDD
(V)
(NOTE 3)
TLOW +25oC(NOTE 4)
THIGH
UNITMIN MAX MIN TYP MAX MIN MAX
Quiescent
Device Current IDD VIN = VSS or VDD
All Valid Input
Combinations
Mil 5 - 0.25 - - 0.25 - 7.5 µA
10 - 0.5 - - 0.5 - 15 µA
Gates 15 - 1 - - 1 - 30 µA
Comm 5 - 1 - - 1 - 7.5 µA
10 - 2 - - 2 - 15 µA
15 - 4 - - 4 - 30 µA
Buffers,
Flip-Flops IDD VIN = VSS or VDD
All Valid Input
Combinations
Mil5-1--1-30µA
10 - 2 - - 2 - 60 µA
15 - 4 - - 4 - 120 µA
Comm 5 - 4 - - 4 - 30 µA
10 - 8 - - 8 - 60 µA
15 - 16 - - 16 - 120 µA
MSI IDD VIN = VSS or VDD
All Valid Input
Combinations
Mil 5 - 5 - - 5 - 150 µA
10 - 10 - - 10 - 300 µA
15 - 20 - - 20 - 600 µA
Comm 5 - 20 - - 20 - 150 µA
10 - 40 - - 40 - 300 µA
15 - 80 - - 80 - 600 µA
Low Level
Output Voltage VOL VIN = VSS or VDD
|IO| <1µAAll 5 - 0.05 - - 0.05 - 0.05 V
10 - 0.05 - - 0.05 - 0.05 V
15 - 0.05 - - 0.05 - 0.05 V
High Level
Output Voltage VOH VIN = VSS or VDD
|IO| <1µAAll 5 4.95 - 4.95 - - 4.95 - V
10 9.95 - 9.95 - - 9.95 - V
15 14.95 - 14.95 - - 14.95 - V
‡ For specific technical information on each individual device type, refer to the appropriate data sheet in Harris AnswerFAX.
See Section 8, “How to use AnswerFAX”, in this selection guide.
5-13
Input Low V oltage VIL VO = 0.5V or 4.5V
VO = 1V or 9V
VO = 1.5V or 13.5V
|IO| <1µA
All 5 - 1.5 - - 1.5 - 1.5 V
B Types 10 - 3 - - 3 - 3 V
15 - 4 - - 4 - 4 V
UB Types 5 - 1 - - 1 - 1 V
10 - 2 - - 2 - 2 V
15 - 2.5 - - 2.5 - 2.5 V
Input High Voltage VIH VO = 0.5V or 4.5V
VO = 1V or 9V
VO = 1.5V or 13.5V
|IO| <1µA
All 5 3.5 - 3.5 - - 3.5 - V
B Types 10 7 - 7 - - 7 - V
15 11 - 11 - - 11 - V
UB Types 5 4 - 4 - - 4 - V
108-8--8-V
15 12.5 - 12.5 - - 12.5 - V
Output Low (Sink)
Current IOL VO = 0.4V
VIN = 0V or 5V
VO = 0.5V
VIN = 0V or 10V
VO = 1.5V
VIN = 0V or 15V
Mil 5 0.64 - 0.51 - - 0.36 - mA
10 1.6 - 1.3 - - 0.9 - mA
15 4.2 - 3.4 - - 2.4 - mA
Comm 5 0.52 - 0.44 - - 0.36 - mA
10 1.3 - 1.1 - - 0.9 - mA
15 3.6 - 3.0 - - 2.4 - mA
Output High
(Source) Current IOH VO = 4.6V
VIN = 0V or 5V
VO = 9.5V
VIN = 0V or 10V
VO = 13.5V
VIN = 0V or 15V
Mil 5 -0.25 - -0.2 - - -0.14 - mA
10 -0.62 - -0.5 - - -0.35 - mA
15 -1.8 - -1.5 - - -1.1 - mA
Comm 5 -0.2 - -0.16 - - -0.12 - mA
10 -0.5 - -0.4 - - -0.3 - mA
15 -1.4 - -1.2 - - -1.0 - mA
Input Current IIN VIN = 0V or 15V Mil 15 - ±0.1 - - ±0.1 - ±1µA
VIN = 0V or 15V Comm 15 - ±0.3 - - ±0.3 - ±1µA
Three-State
Output Leakage
Current
IOUT Max VIN = 0V or 15V Mil 15 - ±0.4 - - ±0.4 - ±12 µA
VIN = 0V or 15V Comm 15 - ±1.6 - - ±1.6 - ±12 µA
Input Capacitance
Per Unit Load CIN Any Input All -----7.5--pF
NOTES:
1. Voltages referenced to VSS.
2. Reprinted from JEDEC Standard No. 13-B, “JEDEC Standard Specification for Description of B-Series CMOS Devices”.
3. TLOW = -55oC for Military Temperature Range Device, -40oC for Commercial Temperature Device (All Harris Devices).
4. THIGH = +125oC for Military Temperature Range Device, +85oC for Commercial Temperature Range Device.
DC Electrical Specification JEDEC Standard for DC Specifications of B-Series CMOS Integrated Circuits (Continued)
PARAMETERS SYMBOL TEST
CONDITIONS TEMP.
RANGE VDD
(V)
(NOTE 3)
TLOW +25oC(NOTE 4)
THIGH
UNITMIN MAX MIN TYP MAX MIN MAX
Family Ratings and Specifications‡
‡ For specific technical information on each individual device type, refer to the appropriate data sheet in Harris AnswerFAX.
See Section 8, “How to use AnswerFAX”, in this selection guide.
5-14
Standardized Absolute Maximum Ratings For B-Series CMOS Integrated Circuits
DC Supply Voltage, VDD
Voltage Reference to VSS Terminal. . . . . . . . . . . . . -0.5V to +20V
Input Voltage, All Inputs . . . . . . . . . . . . . . . . . . . -0.5V to VDD +0.5V
DC Input Current,
For Any One Input. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .±10mA
Lead Temperature (During Soldering)
At Distance 1/16in. ± 1/32in. (1.59mm ± 0.79mm)
from Case for 10s Max . . . . . . . . . . . . . . . . . . . . . . . . . . . +265oC
Power Dissipation Per, PD
TA = -55oC to +100oC . . . . . . . . . . . . . . . . . . . . . . . . . . . . 500mW
TA = +100oC to +125oC. . . Derate Linearly at 12mW/oC to 200mW
Device Dissipation Per Output Transistor
For TA = Full Package Temperature Range
(All Package Test) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100mW
Operating Temperature Range, TA . . . . . . . . . . . . .-55oC to +125oC
Storage Temperature, TSTG . . . . . . . . . . . . . . . . . .-65oC to +150oC
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
Recommended Operating Conditions
Supply, Voltage Range
For TA = Full Package Temperature Range . . . . . . . +3V to +18V
Standardized DC Electrical Specification For B-Series CMOS Integrated Circuits
PARAMETERS SYMBOL
TEST CONDITIONS LIMITS +25oC
UNIT
VO
(V) VIN
(V) VDD
(V) -55oC -40oC +85oC +125oC MIN TYP MAX
Quiescent Device
Current IDD Max - 0, 5 5 0.25 0.25 7.5 7.5 - 0.01 0.25 µA
- 0, 10 10 0.5 0.5 15 15 - 0.01 0.5 µA
Gates, Inverters
(Note 1) - 0, 15 15 1 1 30 30 - 0.01 1 µA
- 0, 20 20 5 5 150 150 - 0.02 5 µA
Buffers, Flip-
Flops, Latches,
Multi-Level Gates
(MSI-1 Types)
(Note 1)
- 0, 5 5 1 1 30 30 - 0.02 1 µA
- 0, 10 10 2 2 60 60 - 0.02 2 µA
- 0, 15 15 4 4 120 120 - 0.02 4 µA
- 0, 20 20 20 20 600 600 - 0.04 20 µA
Complex Logic
(MSI-2 Types)
(Note 1)
- 0, 5 5 5 5 150 150 - 0.04 5 µA
- 0, 10 10 10 10 300 300 - 0.04 10 µA
- 0, 15 15 20 20 600 600 - 0.04 20 µA
- 0, 20 20 100 100 3000 3000 - 0.08 100 µA
Output Low (Sink)
Current Min IOL Min 0.4 0, 5 5 0.64 0.61 0.42 0.36 0.51 1 - mA
0.5 0, 10 10 1.6 1.5 1.1 0.9 1.3 2.6 - mA
1.5 0, 15 15 4.2 4 2.8 2.4 3.4 6.8 - mA
Output High (Source)
Current, Min IOH Min 4.6 0, 5 5 -6.4 -0.61 -0.42 -0.36 -0.51 -1 - mA
2.5 0, 5 5 -2 -1.8 -1.3 -1.15 -1.6 -3.2 - mA
9.5 0, 10 10 -1.6 -1.5 -1.1 -0.9 -1.3 -2.6 - mA
13.5 0, 15 15 -4.2 -4 -2.8 -2.4 -3.4 -6.8 - mA
Family Ratings and Specifications‡
‡ For specific technical information on each individual device type, refer to the appropriate data sheet in Harris AnswerFAX.
See Section 8, “How to use AnswerFAX”, in this selection guide.
5-15
Family Ratings and Specifications‡
Output Voltage Low-
Level VOL Max - 0, 5 5 0.05 - 0 0.05 V
- 0, 10 10 0.05 - 0 0.05 V
- 0, 15 15 0.05 - 0 0.05 V
Output Voltage
High-Level VOH Min - 0, 5 5 4.95 4.95 5 - V
- 0, 10 10 9.95 9.95 10 - V
- 0, 15 15 14.95 14.95 15 - V
Input Low Voltage VIL Max 0.5, 4.5 - 5 1.5 - - 1.5 V
1, 9 - 10 3 - - 3 V
B Types 1.5, 13.5 - 15 4 - - 4 V
UB Types 0.5, 4.5 - 5 1 - - 1 V
1, 9 - 10 2 - - 2 V
1.5, 13.5 - 15 2.5 - - 2.5 V
Input High Voltage VIH Max 0.5, 4.5 - 5 3.5 3.5 - - V
1, 9 - 10 7 7 - - V
B Types 1.5, 13.5 - 15 11 11 - - V
UB Types 0.5, 4.5 - 5 4 4 - - V
1, 9 - 10 8 8 - - V
1.5, 13.5 - 15 12.5 12.5 - - V
Input Current IIN Max - 0, 18 18 ±0.1 ±0.1 ±1±1-±10-5 ±0.1 µA
Three-State Output
Leakage Current IOUT Max 0, 18 0, 18 18 ±0.4 ±0.4 ±12 ±12 - ±10-4 ±0.4 µA
NOTE:
1. Classifications of Harris CMOS B-Series Types are Shown in Table 1.
Standardized DC Electrical Specification For B-Series CMOS Integrated Circuits (Continued)
PARAMETERS SYMBOL
TEST CONDITIONS LIMITS +25oC
UNIT
VO
(V) VIN
(V) VDD
(V) -55oC -40oC +85oC +125oC MIN TYP MAX
‡ For specific technical information on each individual device type, refer to the appropriate data sheet in Harris AnswerFAX.
See Section 8, “How to use AnswerFAX”, in this selection guide.
5-16
AC Electrical Specifications Definitions
PARAMETERS SYMBOL MIN MAX NOTES
PROPAGATION DELAY
Outputs Going High to Low tPHL -X-
Outputs Going Low to High tPLH -X-
OUTPUT TRANSITION TIME
Outputs Going High to Low tTHL -X-
Outputs Going Low to High tTLH -X-
PULSE WIDTH
Set, Reset, Preset, Enable, Disable, Strobe, Clock tWL or tWH X-1
Clock Input Frequency fCL - X 1, 2
Clock Input Rise and Fall Time tRCL, tFCL -X-
Set-Up Time tSU X-1
Hold Time tHX-1
Removal Time - Set, Reset, Preset-Enable tREM X-1
THREE-STATE DISABLE DELAY TIMES
High Level to High Impedance tPHZ -X-
High Impedance to Low Level tPZL -X-
Low Level to High Impedance tPLZ -X-
High Impedance to High Level tPZH -X-
NOTES:
1. By placing a defining Min or Max in front of definition, the limits can change from Min to Max, or vice versa.
2. Clock input waveform should have a 50% duty cycle and be such as to cause the Outputs to be switching from 10% VDD to 90% VDD in
accordance with the device truth table.
TABLE 1. CLASSIFICATION OF HARRIS B-SERIES CMOS INTEGRATED CIRCUITS ACCORDING
TO CIRCUIT COMPLEXITY
GATES/INVERTERS
BUFFERS/FLIP-FLOP/
LATCHES/MULTI-LEVEL
GATES (MSl-1) COMPLEX LOGIC (MSI-2)
CD4001B CD4069UB CD4009UB
(Note 1) C04093B CD4006B CD4055B
(Note 1) CD4532B
CD4001UB CD4070B CD4010B
(Note 1) CD4095B CD4008B CD4056B
(Note 1) CD4536B
CD4002B CD4071B CD4013B CD4096B CD4014B CD4060B CD4541B
CD4007UB CD4072B CD4019B CD4098B CD4015B CD4063B CD4543B
CD4011B CD4073B CD4027B CD4502B
(Note 1) CD4017B CD4067B
(Note 1) CD4555B
CD4011UB CD4075B CD4030B CD4503B CD4018B CD4076B CD4556B
CD4012B CD4077B CD4041UB
(Note 1) CD4504B CD4020B CD4089B CD4560B
Family Ratings and Specifications‡
‡ For specific technical information on each individual device type, refer to the appropriate data sheet in Harris AnswerFAX.
See Section 8, “How to use AnswerFAX”, in this selection guide.
5-17
CD4016B
(Note 1) CD4078B CD4042B CD4519B CD4021B CD4094B CD4566B
CD4023B CD4081B CD4043B CD40106B CD4022B CD4097B
(Note 1) CD4585B
CD4025B CD4082B CD4044B CD40107B
(Note 1) CD4024B CD4099B CD4724B
CD4048B CD40117B CD4047B CD40109B
(Note 1) CD4026B CD4508B CD14538B
CD4066B
(Note 1) CD4572UB CD4049UB
(Note 1) CD40174B CD4028B CD4510B CD40100B
CD4068B CD4050B
(Note 1) CD40175B CD4029B CD4511B
(Note 1) CD40102B
CD4085B CD40257B CD4031B CD4512B CD40103B
CD4086B CD4033B CD4514B CD40105B
CD4034B CD4515B CD40110B
(Note 1)
CD4035B CD4516B CD40147B
CD4040B CD4517B CD40160B
CD4045B
(Note 1) CD4518B CD40161B
CD4046B
(Note 1) CD4520B CD40163B
CD4051B
(Note 1) CD4521B CD40192B
CD4052B
(Note 1) CD4522B CD40193B
CD4053B
(Note 1) CD4527B CD40194B
CD4054B
(Note 1) CD4529B
NOTE:
1. Indicates types for which, because of special design requirements, one or more static characteristics differ from the standardized data.
Refer to data pages on these types for specific differences.
TABLE 1. CLASSIFICATION OF HARRIS B-SERIES CMOS INTEGRATED CIRCUITS ACCORDING
TO CIRCUIT COMPLEXITY (Continued)
GATES/INVERTERS
BUFFERS/FLIP-FLOP/
LATCHES/MULTI-LEVEL
GATES (MSl-1) COMPLEX LOGIC (MSI-2)
Family Ratings and Specifications
5-18
Enhanced Product
STANDARD IC CIRCUITS
SUFFIX “X”
Burn-In Time (Note 1) 160 Hours
Temperature (Note 1) +125oC
Bias Voltage CD4000B 15V
Special Differs by Type
PRODUCT IDENTIFICATION
All Enhanced Product is Identified by a Suffix “X”
Examples: Standard CD4001BE Enhanced CD4001BEX
NOTE:
1. Or equivalent means equivalent time-temperature/voltage result-
ing in the same activation energy.
PRODUCT FLOW
100% BURN-IN 160 HRS AT +125oC OR EQUIVALENT
100% PARAMETRIC AND FUNCTIONAL TESTS AT +25oC
SAMPLE
PARAMETRIC AND
FUNCTIONAL TESTS
AT +25oC
AQL = 0.025%
ENHANCED PRODUCT
= PRODUCT STATE OR PROCESS
= QUALITY ASSURANCE STEP
STANDARD PRODUCT
