HEF4720VDF [NXP]
IC 256 X 1 STANDARD SRAM, 580 ns, CDIP16, CERDIP-16, Static RAM;型号: | HEF4720VDF |
厂家: | NXP |
描述: | IC 256 X 1 STANDARD SRAM, 580 ns, CDIP16, CERDIP-16, Static RAM 存储 |
文件: | 总16页 (文件大小:181K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
INTEGRATED CIRCUITS
DATA SHEET
For a complete data sheet, please also download:
• The IC04 LOCMOS HE4000B Logic
Family Specifications HEF, HEC
• The IC04 LOCMOS HE4000B Logic
Package Outlines/Information HEF, HEC
HEF4720B
HEF4720V
LSI
256-bit, 1-bit per word random
access memories
January 1995
Product specification
File under Integrated Circuits, IC04
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
interface circuits. The memory operates from a single
power supply. The separate chip select input (CS) allows
simple memory expansion when the outputs are wire-O
Red. If CS is HIGH, the outputs are floating and no new
information can be written into the memory. The signal at
O has the same polarity as the data input D, while the
signal at O is the complement of the signal at O. The write
control W must be HIGH for writing into the memory.
DESCRIPTION
The HEF4720B and HEF4720V are 256-bit, 1-bit per word
random access memories with 3-state outputs. The
memories are fully decoded and completely static.
Recommended supply voltage range for HEF4720B is 3 to
15 V and for HEF4720V is 4,5 to 12,5 V; minimum
stand-by voltage for both types is 3 V.
The use of LOCMOS gives the added advantage of very
low stand-by power. The circuits can be directly interfaced
with standard bipolar devices (TTL) without using special
Fig.1 Functional diagram.
HEF4720BP; HEF4720VP(N): 16-lead DIL; plastic
(SOT38-1)
HEF4720BD; HEF4720VD(F): 16-lead DIL; ceramic
(cerdip) (SOT74)
HEF4720BT; HEF4720VT(D): 16-lead SO; plastic
(SOT109-1)
( ): Package Designator North America
Fig.2 Pinning diagram.
FAMILY DATA
See Family Specifications.
January 1995
2
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
IDD LIMITS
See below.
FUNCTION TABLE
PINNING
CS
chip select input (active LOW)
CS
W
O
O
MODE
W
write enable input
L
H
data written
into memory
data written
into memory
Z
complement of data write
written into memory
D
data input
A0 to A7
address inputs
L
L
complement of data read
written into memory
O
O
3-state output (active HIGH)
3-state output (active LOW)
H
X
Z
inhibit
Notes
1. H = HIGH state (the more positive voltage)
L = LOW state (the less positive voltage)
X = state is immaterial
Z = high impedance OFF-state
SUPPLY VOLTAGE
RATING
RECOMMENDED OPERATING
STAND-BY MIN.
HEF4720B
HEF4720V
−0,5 to 18
−0,5 to 18
3,0 to 15,0
4,5 to 12,5
3
3
V
V
The values given at VDD = 15 V in the following DC and
AC characteristics, are not applicable to the HEF4720V,
because of its lower supply voltage range.
DC CHARACTERISTICS
VSS = 0 V
Tamb (°C)
VDD
V
VOL
V
SYMBOL
−40
+25
+85
MIN. MAX. MIN. MAX. MIN. MAX.
Output current
LOW
4,75
10
15
5
0,4
2,4
4,8
2
4
1,6
3,2
7,5
mA
mA
0,5 IOL
1,5
10,0
10
mA
Quiescent device
current
25
50
25
50
200 µA
400 µA
800 µA
10
15
IDD
100
100
Input leakage current
HEF4720V
10
15
0,3
0,3
0,3
0,3
1 µA
1 µA
±IIN
HEF4720B
January 1995
3
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
AC CHARACTERISTICS
VDD
SYMBOL MIN. TYP. MAX.
V
5
5
5
5
pF
pF
pF
Output capacitance
10 CO
15
A.C. CHARACTERISTICS
VSS = 0 V; Tamb = 25 °C; CL = 50 pF; input transition times ≤ 20 ns
VDD
V
TYPICAL EXTRAPOLATION
FORMULA
SYMBOL MIN.
TYP. MAX.
Read cycle
5
10
15
5
320
130
100
580 ns
220 ns
160 ns
180 ns
70 ns
50 ns
ns
292 ns + (0,55 ns/pF) CL
118 ns + (0,23 ns/pF) CL
92 ns + (0,16 ns/pF) CL
Read access time
tACC
Chip select to
output time
10
15
5
tCO
0
Address hold time
10
15
5
tOA
0
0
ns
ns
Output hold time
with respect to
address input
60
20
15
170
50
ns
142 ns + (0,55 ns/pF) CL
38 ns + (0,23 ns/pF) CL
32 ns + (0,16 ns/pF) CL
10
15
5
tVAL1
tCOH
tCOF
tRC
ns
40
ns
Output hold time
with respect to
chip select input
Output floating time
with respect to
chip select input
130 ns
70 ns
60 ns
ns
10
15
5
0
0
10
15
5
ns
0
ns
580
220
160
ns
Read cycle time
10
15
5
ns
ns
Output transition
times
60
30
20
40
22
15
120 ns
60 ns
40 ns
80 ns
40 ns
30 ns
10 ns + (1,0 ns/pF) CL
9 ns + (0,42 ns/pF) CL
6 ns + (0,28 ns/pF) CL
14 ns + (0,52 ns/pF) CL
11 ns + (0,22 ns/pF) CL
7 ns + (0,16 ns/pF) CL
10
15
5
tTLH
LOW to HIGH
HIGH to LOW
10
15
tTHL
January 1995
4
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
AC CHARACTERISTICS
VSS = 0 V; Tamb = 25 °C; CL = 50 pF; input transition times ≤ 20 ns
VDD
V
SYMBOL
MIN.
TYP.
MAX.
Write cycle
5
580
220
160
110
50
ns
ns
ns
ns
ns
ns
Write cycle time
10
15
5
tWC
Address to write
set-up time
10
15
5
tAW
50
370
130
80
10 000 ns
Write pulse width
Write recovery time
Data set-up time
Data hold time
10
15
5
tWP
tWR
tDW
tDH
10 000 ns
10 000 ns
100
40
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
10
15
5
30
250
100
80
10
15
5
100
30
10
15
5
20
Chip select set-up
time with respect
to write pulse
370
130
80
10
15
5
tCSW
tCSH
tCSL
Chip select hold
time with respect
to write pulse
0
10
15
5
0
0
Chip select lead time
over write pulse to
prevent writing
0
10
15
0
0
January 1995
5
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
VDD
V
SYMBOL
MIN.
TYP.
MAX.
Read-modify-write cycle
Read enable
hold time
5
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
10
15
5
tRH
0
0
Output hold time
with respect to
write pulse
60
10
15
5
tVAL2
20
15
Read-modify-write
cycle time
1050
390
270
10
15
tRWC
Fig.3 Read cycle timing diagram.
January 1995
6
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
Fig.4 Write cycle timing diagram.
January 1995
7
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Fig.5 Read-modify-write cycle timing diagram.
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
APPLICATION INFORMATION
Extension of memory capacity
The memory capacity of the HEF4720B; V is 256 bits (or
256 words of 1 bit). The capacity of a system can be
extended in various ways by the connection of further
HEF4720B; V ICs.
Extending the word length
By connecting a number of HEF4720B; V ICs as shown in
Fig.6, the word length (i.e. bits per word) is multiplied by
that number. That is, each device stores 1 bit per word but
the total number of words remains 256. For example, if
four devices are used in this way, 256 four-binary-bit words
can be stored.
Extending the number of words
If a number of HEF4720B; V ICs are connected as shown
in Fig.7, the words available are multiplied by that number,
but the word length remains 1 bit. Notice that in this case
additional addresses are used in conjunction with the
CS input. In the case shown in Fig.7 (4 × HEF4720B; V in
parallel), the addresses and data inputs are loaded with
four inputs (= 20 pF), the CS inputs are loaded with one
input each.
Extending both the word length and number of words
Figure 8 shows how a combination of the extensions
described above can be used to obtain both greater word
length and additional words. It is clear that the capacitive
load of the driving circuits puts a limit to the free choice of
the interface. In Fig.8, each address is loaded with 16
inputs, i.e. 16 × 5 = 80 pF: each CS inverter is loaded with
8 inputs, i.e. 8 × 5 = 40 pF. The data inverters in this case
are loaded with only two inputs each.
January 1995
9
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
Fig.6 Using extra HEF4720B; V ICs to extend the word length.
January 1995
10
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Fig.7 Using extra HEF4720B; V ICs to obtain more words.
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
Fig.8 Using extra HEF4720B; V ICs to obtain more words and greater word length.
January 1995
12
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
Three possibilities for controlling the rise and fall times at
the HEF4720B; V interface are given here:
Memory retention
It is sometimes necessary to ensure that the information
stored in the memory cannot be erased inadvertently. This
can be arranged by adding detection circuits, by measures
in the timing, and by the addition of a battery. With the
HEF4720B; V, memory retention is very easily obtained
because its current drain in the stand-by condition is
almost zero. The wide supply voltage range makes it
possible to keep the memory active by means of a simple
battery, thereby preventing information loss.
1. LOCMOS gates can be connected between the
address latch and the HEF4720B; V (Fig.9). In the
event of a low voltage, or mains supply failure, the
gates can be blocked by a signal from the memory
retention logic thus isolating the HEF4720B; V from
the address and CS inputs.
2. The interface power supply can be separated from the
TTL power supply by means of a low-value resistor
(Fig.10); a thyristor is connected from the interface
power supply to earth. The system is arranged so that,
upon switching off or failure of the interface supply, the
thyristor turns on thus ensuring a rapid fall of the
supply voltage.
In designing the memory retention circuits, two aspects
should be kept in mind. The memory retention will not
function in an optimum way if the battery voltage is low or
if the voltage transitions at the address input are too slow.
The first of these is usually the result of using too simple a
battery back-up circuit, e.g. a battery charged via a diode
from the TTL supply voltage. In this case, the LOCMOS
supply voltage falls below the safe operating voltage.
Special arrangements should be made to overcome this.
3. The best solution is to select the interface circuits from
the LOCMOS family and to feed all these circuits from
the battery (Fig.11). These stages then remain active
when the TTL 5 V supply fails. The interface circuits
are mostly only active on a clock pulse, have the
possibility of being inactive on a gate level, or can be
forced into one position.
Slow address transitions (the second cause of memory
loss) are due to a long RC-time in the power system. When
the power is switched on or off, the 5 V line changes
between 0 and 5 V in milliseconds to seconds so
producing a correspondingly long transition time in the
various logic outputs. This creates problems in the proper
operation of the HEF4720B; V, with loss of memory as a
possible result. This can be prevented by ensuring that
input rise and fall times do not exceed 10 µs.
January 1995
13
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
(1) These devices have a battery supply.
(2) Alternative connection.
Fig.9 Use of battery-operated LOCMOS gates to isolate the memory in case of power supply failure. Devices
marked (1) are connected to the battery. The HEF4011B can sink about 0,7 mA: if the load is greater than
this, only the memory should be connected, other loads being connected to the address latch as shown
by the dashed-line connections.
January 1995
14
Philips Semiconductors
Product specification
HEF4720B
HEF4720V
256-bit, 1-bit per word random access memories
(1) Leads should be so arranged to prevent cross-talk; thyristor connections must be short.
(2) Slope > 500 mV/µs in the vicinity of the threshold.
Fig.10 Using a thyristor to ensure a rapid fall of interface supply at switch-off or supply failure.
January 1995
15
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Fig.11 Preferred solution for memory retention; all interface circuits are battery-fed LOCMOS. Note that maximum sink current of the
HEF4042B is about 1,5 mA.
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