DATASHEET

82C52
Data Sheet
November 25, 2015
CMOS Serial Controller Interface
Features
The Intersil 82C52 is a high performance programmable
Universal Asynchronous Receiver/Transmitter (UART) and
Baud Rate Generator (BRG) on a single chip. Utilizing the
Intersil advanced Scaled SAJI IV CMOS process, the 82C52
will support data rates up to 1M baud asynchronously with a
16X clock (16MHz clock frequency).
• Single Chip UART/BRG
The on-chip Baud Rate Generator can be programmed for any
one of 72 different baud rates using a single industry standard
crystal or external frequency source. A unique pre-scale divide
circuit has been designed to provide standard RS-232-C baud
rates when using any one of three industry standard crystals
(1.8432MHz, 2.4576MHz, or 3.072MHz).
A programmable buffered clock output (CO) is available and
can be programmed to provide either a buffered oscillator or
16X baud rate clock for general purpose system usage.
FN2950.4
• DC to 16MHz (1M Baud) Operation
• Crystal or External Clock Input
• On-Chip Baud Rate Generator - 72 Selectable Baud Rates
• Interrupt Mode with Mask Capability
• Microprocessor Bus Oriented Interface
• 80C86 Compatible
• Single +5V Power Supply
• Low Power Operation . . . . . . . . . . . . . . . . . . . . 1mA/MHz Typ
• Modem Interface
• Line Break Generation and Detection
• Operating Temperature Range:
- C82C52 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .0°C to +70°C
- I82C52. . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40°C to +85°C
- M82C52. . . . . . . . . . . . . . . . . . . . . . . . . . . -55°C to +125°C
• Pb-Free Plus Anneal Available (RoHS Compliant)
•
Ordering Information
1M BAUD
PART MARKING
CP82C52
CP82C52
(No longer available or supported
Recommended Replacement:
CP82C52Z)
TEMP
RANGE (°C)
0 to +70
CP82C52Z (Note)
CP82C52Z
IP82C52
IP82C52
-40 to +85
CS82C5296
CS82C52
CS82C52Z*
(Note)
CS82C52Z
IS82C52
IS82C52
IS82C52Z*
(Note)
IS82C52Z
ID82C52
PDIP
PKG. DWG. #
E28.6
PDIP (Pb-Free)**
E28.6
PDIP
E28.6
0 to +70
PLCC (Tape & Reel)
N28.45
0to +70
PLCC
(Pb-Free)
N28.45
-40 to +85
PLCC
N28.45
-40 to +85
PLCC
(Pb-Free)
N28.45
ID82C52
-40 to +85
CERDIP
F28.6
MD82C52/B
MD82C52/B
-55 to +125
8501501XA
8501501XA
MR82C52/B
0 to +70
PACKAGE
-55 to +125
85015013A
85015013A
F28.6
SMD#
F28.6
CLCC
J28.A
SMD#
J28.A
*Add "96" suffix for tape and reel.
**Pb-free PDIPs can be used for through hole wave solder processing only. They are not intended for use in Reflow solder processing applications.
NOTE: Intersil Pb-free plus anneal products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin plate
termination finish, which are RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL
classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020.
1
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 1-888-468-3774 | Copyright Intersil Americas LLC 1997, 2002, 2006, 2015. All Rights Reserved
Intersil (and design) is a trademark owned by Intersil Corporation or one of its subsidiaries.
All other trademarks mentioned are the property of their respective owners.
82C52
Pinouts
D1 4
25 SDI
D2 5
DR
26 DR
VCC
D0 3
CSO
27 VCC
RD
28 CSO
WR
RD 1
WR 2
D0
82C52 (PLCC, CLCC)
TOP VIEW
D1
82C52 (PDIP, CERDIP)
TOP VIEW
4
3
2
1
28
27
26
D3
6
24
INTR
D3 6
23 RST
D4
7
23
RST
D4 7
22 TBRE
D5
8
22
D5 8
21 CO
TBRE
D6 9
20 RTS
D6
9
21
CO
D7 10
19 DTR
D7
10
20
RTS
A0 11
18 DSR
A0
11
19
DTR
A1 12
17 CTS
IX 13
16 GND
OX 14
15 SDO
14
15
SDO
13
OX
12
16
17
18
DSR
24 INTR
CTS
SDI
GND
25
IX
5
A1
D2
Block Diagram
RD
WR
A0
A1
CSO
IX
OX
CO
RST
INTR
1
2
11
12
READ/WRITE
CONTROL
LOGIC
28
13
14
21
PROGRAMMABLE
BOUD RATE
GENERATOR
23
24
UART
CONTROL AND
STATUS
REGISTERS
DATA
BUS
BUFFER
CONTROL
LOGIC
2
INTERNAL DATA BUS
3 - 10
D0-D7
22
26
TRANSMITTER
BUFFER
REGISTER
TRANSMITTER
REGISTER
P
S
15
RECEIVER
BUFFER
REGISTER
RECEIVER
REGISTER
P
S
25
18
MODEM
CONTROL AND
STATUS
REGISTERS
17
19
20
TBRE
DR
SDO
SDI
DSR
CTS
DTR
RTS
FN2950.4
November 25, 2015
82C52
Pin Description
SYMBOL
PIN
NO.
TYPE
ACTIVE
LEVEL
RD
1
I
Low
READ: The RD input causes the 82C52 to output data to the data bus (D0-D7). The data output
depends upon the state of the address inputs (A0-A1). CS0 enables the RD input.
WR
2
I
Low
WRITE: The WR input causes data from the data bus (D0-D7) to be input to the 82C52. Addressing
and chip select action is the same as for read operations.
D0-D7
3-10
I/O
High
DATA BITS 0-7: The Data Bus provides eight, three-state input/output lines for the transfer of data,
control and status information between the 82C52 and the CPU. For character formats of less than 8
bits, the corresponding D7, D6 and D5 are considered “don't cares” for data WRITE operations and
are 0 for data READ operations. These lines are normally in a high impedance state except during
read operations. D0 is the Least Significant Bit (LSB) and is the first serial data bit to be received or
transmitted.
A0, A1
11, 12
I
High
ADDRESS INPUTS: The address lines select the various internal registers during CPU bus
operations.
IX, OX
13, 14
I/O
SDO
15
O
GND
16
CTS
17
DSR
DESCRIPTION
CRYSTAL/CLOCK: Crystal connections for the internal Baud Rate Generator. IX can also be used
as an external clock input in which case OX should be left open.
High
SERIAL DATA OUTPUT: Serial data output from the 82C52 transmitter circuitry. A Mark (1) is a logic
one (high) and Space (0) is logic zero (low). SD0 is held in the Mark condition when CTS is false,
when RST is true, when the Transmitter Register is empty, or when in the Loop Mode.
Low
GROUND: Power supply ground connection.
I
Low
CLEAR TO SEND: The logical state of the CTS line is reflected in the CTS bit of the Modem Status
Register. Any change of state in CTS causes INTR to be set true when INTEN and MIEN are true. A
false level on CTS will inhibit transmission of data on the SD0 output and will hold SD0 in the Mark
(high) state. If CTS goes false during transmission, the current character being transmitted will be
completed. CTS does not affect Loop Mode operation.
18
I
Low
DATA SET READY: The logical state of the DSR line is reflected in the Modem Status Register. Any
change of state of DSR will cause INTR to be set if INTEN and MIEN are true. The state of this signal
does not affect any other circuitry within the 82C52.
DTR
19
O
Low
DATA TERMINAL READY: The DTR signal can be set (low) by writing a logic 1 to the appropriate bit
in the Modem Control Register (MCR). This signal is cleared (high) by writing a logic 0 in the DTR bit
in the MCR or whenever a reset (RST = high) is applied to the 82C52.
RTS
20
O
Low
REQUEST TO SEND: The RTS signal can be set (low) by writing a logic 1 to the appropriate bit in
the MCR. This signal is cleared (high) by writing a logic 0 to the RTS bit in the MCR or whenever a
reset (RST = high) is applied to the 82C52.
CO
21
O
TBRE
22
O
High
TRANSMITTER BUFFER REGISTER EMPTY: The TBRE output is set (high) whenever the
Transmitter Buffer Register (TBR) has transferred its data to the Transmit Register. Application of a
reset (RST) to the 82C52 will also set the TBRE output. TBRE is cleared (low) whenever data is
written to the TBR.
RST
23
I
High
RESET: The RST input forces the 82C52 into an “Idle” mode in which all serial data activities are
suspended. The Modem Control Register (MCR) along with its associated outputs are cleared. The
UART Status Register (USR) is cleared except for the TBRE and TC bits, which are set. The 82C52
remains in an “Idle” state until programmed to resume serial data activities. The RST input is a
Schmitt triggered input.
INTR
24
O
High
INTERRUPT REQUEST: The INTR output is enabled by the INTEN bit in the Modem Control
Register (MCR). The MIEN bit selectively enables modem status changes to provide an input to the
INTR logic. Figure 9 in Design Information shows the overall relationship of these interrupt control
signals.
CLOCK OUT: This output is user programmable to provide either a buffered IX output or a buffered
Baud Rate Generator (16X) clock output. The buffered IX (Crystal or external clock source) output is
provided when the Baud Rate Select Register (BRSR) bit 7 is set to a zero. Writing a logic one to
BRSR bit 7 causes the CO output to provide a buffered version of the internal Baud Rate Generator
clock which operates at sixteen times the programmed baud rate. On reset D7 (CO select) is reset to
0.
3
FN2950.4
November 25, 2015
82C52
Pin Description
(Continued)
SYMBOL
PIN
NO.
TYPE
ACTIVE
LEVEL
SDI
25
I
High
SERIAL DATA INPUT: Serial data input to the 82C52 receiver circuits. A Mark (1) is high, and a
Space (0) is low. Data inputs on SDI are disabled when operating in the loop mode or when RST is
true.
DR
26
O
High
DATA READY: A true level indicates that a character has been received, transferred to the RBR, and
is ready for transfer to the CPU. DR is reset on a data READ of the Receiver Buffer Register (RBR)
or when RST is true.
VCC
27
High
VCC: +5V positive power supply pin. A 0.1F decoupling capacitor from VCC (Pin 27) to GND (Pin
16) is recommended.
CS0
28
Low
CHIP SELECT: The chip select input acts as an enable signal for the RD and WR input signals.
I
4
DESCRIPTION
FN2950.4
November 25, 2015
82C52
Reset
TABLE 1.
During and after power-up, the 82C52 Reset Input (RST)
must be held high for at least two IX clock cycles in order to
initialize and drive the 82C52 circuits to an idle mode until
proper programming can be done. A high on RST causes
the following events to occur
• Resets the internal Baud Rate Generator (BRG) circuit
clock counters and bit counters. The Baud Rate Select
Register (BRSR) is not affected (except for bit 7 which is
reset to 0).
• Clears the UART Status Register (USR) except for
Transmission Complete (TC) and Transmit Buffer Register
Empty (TBRE) which are set. The Modem Control
Register (MCR) is also cleared. All of the discrete lines,
memory elements and miscellaneous logic associated
with these register bits are also cleared or turned off. Note
that the UART Control Register (UCR) is not affected.
Following removal of the reset condition (RST = low), the
82C52 remains in the idle mode until programmed to its
desired system configuration.
Programming The 82C52
CS0
A1
A0
WR
RD
0
0
0
0
1
Data Bus  Transmitter Buffer
Register (TBR)
0
0
0
1
0
Receiver Buffer Register
(RBR)  Data Bus
0
0
1
0
1
Data Bus  UART Control
Register (UCR)
0
0
1
1
0
UART Status Register
(USR)  Data Bus
0
1
0
0
1
Data Bus  Modem Control
Register (MCR)
0
1
0
1
0
MCR  Data Bus
0
1
1
0
1
Data Bus  Bit Rate Select
Register (BRSR)
0
1
1
1
0
Modem Status Register
(MSR)  Data Bus
OPERATION
D7 D6 D5 D4 D3 D2 D1 D0
The complete functional definition of the 82C52 is
programmed by the systems software. A set of control words
(UCR, BRSR and MCR) must be sent out by the CPU to
initialize the 82C52 to support the desired communication
format. These control words will program the character
length, number of stop bits, even/odd/no parity, baud rate,
etc. Once programmed, the 82C52 is ready to perform its
communication functions.
Stop Bit
Select
0 = 1 Stop Bits
Parity
Control
000 = Tx and Rx Even
001 = Tx and Rx Odd
010 = Tx Even, Rx
Odd
011 = Tx Odd, Rx
Even
100 = Tx Even, Rx
Check Disabled
101 = Tx Odd, Rx
Check Disabled
11X = Generation and
Check Disabled
Word
Length
Select
00 = 5 Bits
01 = 6 Bits
10 = 7 Bits
11 = 8 Bits
The control registers can be written to in any order. However,
the MCR should be written to last because it controls the
interrupt enables, modem control outputs and the receiver
enable bit. Once the 82C52 is programmed and operational,
these registers can be updated any time the 82C52 is not
immediately transmitting or receiving data.
Table 1. Shows the control signals required to access 82C52
internal registers.
UART Control Register (UCR)
The UCR is a write only register which configures the UART
transmitter and receiver circuits. Data bits D7 and D6 are not
used but should always be set to a logic zero (0) in order to
insure software compatibility with future product upgrades.
During the Echo Mode, the transmitter always repeats the
received word and parity, even when the UCR is
programmed with different or no parity. See Figure 1.
5
1 = 1.5 Stop Bits (Tx)
and 1 Stop Bit (Rx)
If 5 Data Bits Selected
1 = 2 Stop Bits for 6, 7
or 8 Data Bits Selected
Reserved Set to 00 for Future
Product Upgrade
Compatibility
FIGURE 1. UCR
Baud Rate Select Register (BRSR)
The 82C52 is designed to operate with a single crystal or
external clock driving the IX input pin. The Baud Rate Select
Register is used to select the divide ratio (one of 72) for the
internal Baud Rate Generator circuitry. The internal circuitry
is separated into two separate counters, a Prescaler and a
Divisor Select. The Prescaler can be set to any one of four
division rates, 1, 3, 4, or 5.
FN2950.4
November 25, 2015
82C52
The Prescaler design has been optimized to provide
standard baud rates using any one of three popular crystal
frequencies. By using one of these common system clock
frequencies, 1.8432MHz, 2.4576MHz or 3.072MHz and
Prescaler divide ratios of 3, 4, or 5 respectively, the
Prescaler output will provide a constant 614.4KHz. When
this frequency is further divided by the Divisor Select
counter, any of the standard baud rates from 50 Baud to
38.4Kbaud can be selected (see Table 2). Non-standard
baud rates up to 1Mbaud can be selected by using different
input frequencies (crystal or an external frequency input up
to 16MHz) and/or different Prescaler and Divisor Select
ratios.
TABLE 2.
BAUD RATE
DIVISOR
38.4K
External
19.2K
2
9600
4
7200
16/3
4800
8
3600
32/3
2400
16
2000†
58/3
1800†
22
1200
32
600
64
300
128
200
192
150
256
134.5†
288
110†
352
75
512
50
768
Regardless of the baud rate, the baud rate generator
provides a clock which is 16 times the desired baud rate. For
example, in order to operate at a 1Mbaud data rate, a
16MHz crystal, a Prescale rate of 1, and a Divisor Select
rate of “external” would be used. This would provide a
16MHz clock as the output of the Baud Rate Generator to
the Transmitter and Receiver circuits.
The CO select bit in the BRSR selects whether a buffered
version of the external frequency input (IX input) or the Baud
Rate Generator output (16x baud rate clock) will be output
on the CO output (pin 21). The Baud Rate Generator output
will always be a 50% nominal duty cycle except when
“external” is selected and the Prescaler is set to 3 or 5.
NOTE:
D7 D6 D5 D4 D3 D2 D1 D0
Prescaler 00 =  1
Select
01 =  3
10 =  4
11 =  5
Divisor
Select
CO
Select
FIGURE 2. BRSR
6
00000 =  2
00001 =  4
00010 =  16/3
00011 =  8
00100 =  32/3
00101 =  16
00110 =  58/3
00111 =  22
01000 =  32
01001 = 64
01010 =  128
01011 =  192
01100 =  256
01101 =  288
01110 =  352
01111 =  512
10000 =  768
11111 = External ( 1)
0 = IX Output
1 = Brg Output (On
Reset, D7 (CO Select)
is Reset to 0)
†
These baud rates are based upon the following input
frequency/ Prescale divisor combinations.
1.8432MHz and Prescale =  3
2.4576MHz and Prescale =  4
3.072MHZ and Prescale =  5
All baud rates are exact except for:
BAUD RATE
ACTUAL
PERCENT ERROR
1800
1745.45
3.03%
2000
1986.2
0.69%
134.5
133.33
0.87%
110
109.09
0.83%
Modem Control Register
The MCR is a general purpose control register which can be
written to and read from. The RTS and DTR outputs are
directly controlled by their associated bits in this register.
Note that a logic one asserts a true logic level (low) at these
output pins. The Interrupt Enable (INTEN) bit is the overall
control for the INTR output pin. When INTEN is false, INTR
is held false (low).
The Operating Mode bits configure the 82C52 into one of
four possible modes. “Normal” configures the 82C52 for
normal full or half duplex communications. “Transmit Break”'
enables the transmitter to only transmit break characters
(Start, Data and Stop bits all are logic zero). The Echo Mode
causes any data that is received on the SDI input pin to be
retransmitted on the SDO output pin. Note that this output is
FN2950.4
November 25, 2015
82C52
a buffered version of the data seen on the SDI input and is
not a resynchronized output. Also note that normal UART
transmission via the Transmitter Register is disabled when
operating in the Echo mode (see Figure 4). The Loop Test
Mode internally routes transmitted data to the receiver
circuitry for the purpose of self test. The transmit data is
disabled from the SDO output pin. The Receiver Enable bit
gates off the input to the receiver circuitry when in the false
state.
Modem Interrupt Enable will permit any change in modem
status line inputs (CTS, DSR) to cause an interrupt when this
bit is enabled. Bit D7 must always be written to with a logic
zero to insure correct 82C52 operation.
D7 D6 D5 D4 D3 D2 D1 D0
Request 0 = RTS Output High†
to Send 1 = RTS Output Low
(RTS)
Data
0 = DTR Output High
Terminal 1 = DTR Output Low
Ready
(DTR)
Interrupt 1 = Interrupts Enabled
Enable
0 = interrupts Disabled
(INTEN)
Mode
Select
00 = Normal
01 = Transmit Break
10 = Echo Mode
11 = Loop Test Mode
Receiver 0 = Not Enabled
Enable
1 = Enabled
(REN)
Modem 0 = Not Enabled
Interrupt 1 = Enabled
Enable
(MIEN)
Must be Set to a Logic 0 for
Normal 82C52 Operation
†
See Modem Status Register description for a description of
register flag images with respect to output pins.
FIGURE 3. MCR
UART Status Register (USR)
The USR provides a single register that the controlling sys
tem can examine to determine if errors have occurred or if
other status changes in the 82C52 require attention. For this
reason, the USR is usually the first register read by the CPU
to determine the cause of an interrupt or to poll the status of
the 82C52.
Three error flags OE, FE and PE report the status of any
error conditions detected in the receiver circuitry. These
error flags are updated with every character received during
reception of the stop bits. The Overrun Error (OE) indicates
that a character in the Receiver Register has been received
and cannot be transferred to the Receiver Buffer Register
(RBR) because the RBR was not read by the CPU. Framing
Error (FE) indicates that the last character received in the
RBR contained improper stop bits. This could be caused by
the absence of the required stop bit(s) or by a stop bit(s) that
was too short to be properly detected. Parity Error (PE)
indicates that the last character received in the RBR
contained a parity error based on the programmed parity of
the receiver and the calculated parity of the received
character data and parity bits.
The Received Break (RBRK) status bit indicates that the last
character received was a break character. A break character
would be considered to be an invalid data character in that
the entire character including parity and stop bits are a logic
zero.
The Modem Status bit is set whenever a transition is
detected on any of the Modem input lines (CTS or DSR). A
subsequent read of the Modem Status Register will show the
state of these two signals. Assertion of this bit will cause an
interrupt (INTR) to be generated if the MIEN and INTEN bits
in the MCR register are enabled.
The Transmission Complete (TC) bit indicates that both the
TBR and Transmitter Registers are empty and the 82C52
has completed transmission of the last character it was
commanded to transmit. The assertion of this bit will cause
an interrupt (INTR) if the INTEN bit in the MCR register is
true.
The Transmitter Buffer Register Empty (TBRE) bit indicates
that the TBR register is empty and ready to receive another
character.
SERIAL DATA
FROM
TRANSMITTER
REGISTER
ECHO MODE
LOOP
MODE
SDO
PIN 15
SERIAL DATA
TO RECEIVER
REGISTER
SDI
PIN 25
FIGURE 4. LOOP AND ECHO MODE FUNCTIONALITY
7
The Data Ready (DR) bit indicates that the RBR has been
loaded with a received character (including Break) and that
the CPU may access this data.
Assertion of the TBRE or DR bits do not affect the INTR logic
and associated INTR output pin since the 82C52 has been
designed to provide separate requests via the DR and TBRE
output pins. If a single interrupt for any status change in the
82C52 is desired this can be accomplished by using an
82C59A Interrupt controller with DR, TBRE, and INTR as
inputs. (See Figure 11).
FN2950.4
November 25, 2015
82C52
D7 D6 D5 D4 D3 D2 D1 D0
Parity Error
(PE)
0 = No Error
1 = Error
Framing Error
(FE)
0 = No Error
1 = Error
Overrun Error
(OE)
0 = No Error
1 = Error
D7 D6 D5 D4 D3 D2 D1 D0
Clear to Send
(CTS)
Data Set Ready 0 = False
(DSR)
1 = True
0
Received Break 0 = No Break
(RBRK)
1 = Break
Modem Status
(MS)
0 = No Status
Change
1 = Status
Change
Transmission
Complete
(TC)
0 = Not
Complete
1 = Complete
Transmitter Buf- 0 = Not Empty
fer Register
1 = Empty
Empty (TBRE)
Data Ready
(DR)
0 = Not Ready
1 = Ready
FIGURE 5. USR
Modem Status Register (MSR)
The MSR allows the CPU to read the modem signal inputs
by accessing the data bus interface of the 82C52. Like all of
the register images of external pins in the 82C52, true logic
levels are represented by a high (1) signal level. By following
this consistent definition, the system software need not be
concerned with whether external signals are high or low true.
In particular, the modem signal inputs are low true, thus a 0
(true assertion) at a modem input pin is represented by a 1
(true) in the MSR.
Any change of state in any modem input signals will set the
Modem Status (MS) bit in the USR register. When this
happens, an interrupt (INTR) will be generated if the MIEN
and INTEN bits of the MCR are enabled.
The Data Set Ready (DSR) input is a status indicator from
the modem to the 82C52 which indicates that the modem is
ready to provide received data to the 82C52 receiver
circuitry.
Clear to Send (CTS) is both a status and control signal from
the modem that tells the 82C52 that the modem is ready to
receive transmit data from the 82C52 transmitter output
(SDO). A high (false) level on this input will inhibit the 82C52
from beginning transmission and if asserted in the middle of
a transmission will only permit the 82C52 to finish
transmission of the current character.
0 = False
1 = Truer
0
Undefined
FIGURE 6. MSR
Receiver Buffer Register (RBR)
The receiver circuitry in the 82C52 is programmable for 5, 6,
7 or 8 data bits per character. For words of less than 8 bits,
the data is right justified to the Least Significant Bit (LSB =
D0). Bit D0 of a data word is always the first data bit
received. The unused bits in a less than 8-bit word, at the
parallel interface, are set to a logic zero (0) by the 82C52.
Received data at the SDI input pin is shifted into the
Receiver Register by an internal 1x clock which has been
synchronized to the incoming data based on the position of
the start bit. When a complete character has been shifted
into the Receiver Register, the assembled data bits are
parallel loaded into the Receiver Buffer Register. Both the
DR output pin and DR flag in the USR register are set. This
double buffering of the received data permits continuous
reception of data without losing any of the received data.
While the Receiver Register is shifting a new character into
the 82C52, the Receiver Buffer Register is holding a
previously received character for the system CPU to read.
Failure to read the data in the RBR before complete
reception of the next character can result in the loss of the
data in the Receiver Register. The OE flag in the USR
register indicates the overrun condition.
D7 D6 D5 D4 D3 D2 D1 D0
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
5-Bit
Word
6-Bit
Word
7-Bit
Word
8-Bit
Word
Bit 6
Bit 7
FIGURE 7. RBR
Transmitter Buffer Register (TBR)
The Transmitter Buffer Register (TBR) accepts parallel data
from the data bus (D0-D7) and holds it until the Transmitter
Register is empty and ready to accept a new character for
8
FN2950.4
November 25, 2015
82C52
transmission. The transmitter always has the same word
length and number of stop bits as the receiver. For words of
less than 8 bits the unused bits at the microprocessor data
bus are ignored by the transmitter.
generated during a READ operation, the status bit is not set until the
trailing edge of the RD pulse.
If the bit was already set at the time of the READ operation, and the
same status condition occurs, that status bit will be cleared at the
trailing edge of the RD pulse instead of being set again.
D7 D6 D5 D4 D3 D2 D1 D0
RBRK, TC
OE, FE, PE
(USR)
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
5-Bit
Word
6-Bit
Word
POS.
EDGE
DETECT
INTR
PIN 24
RD (USR)
7-Bit
Word
8-Bit
Word
Bit 6
Bit 7
FIGURE 8. TBR
Bit 0, which corresponds to D0 at the data bus, is always the
first serial data bit transmitted. Provision is made for the
transmitter parity to be the same or different from the
receiver. The TBRE output pin and flag (USR register) reflect
the status of the TBR. The TC flag (USR register) indicates
when both TBR and TR are empty.
DSR, CTS
(MSR)
INTEN
(MCR)
POS. OR
NEG.
EDGE
DETECT
RD (MSR)
MIEN
(MCR)
FIGURE 9. 82C52 INTERRUPT STRUCTURE
Software Reset
A software reset of the 82C52 is a useful method for
returning to a completely known state without exercising a
complete system reset. Such a reset would consist of writing
to the UCR, BRSR and MCR registers. The USR and RBR
registers should be read prior to enabling interrupts in order
to clear out any residual data or status bits which may be
invalid for subsequent operation.
Crystal Operation
82C52 Interrupt Structure
The 82C52 has provisions for software masking of interrupts
generated for the INTR output pin. Two control bits in the
MCR register, MIEN and INTEN, control modem status
interrupts and overall 82C52 interrupts respectively. Figure 9
illustrates the logical control function provided by these
signals.
The modem status inputs (DSR and CTS) will trigger the
edge detection circuitry with any change of status. Reading
the MSR register will clear the detect circuit but has no effect
on the status bits themselves. These status bits always
reflect the state of the input pins regardless of the mask
control signals. Note that the state (high or low) of the status
bits are inverted versions of the actual input pins.
The edge detection circuits for the USR register signals will
trigger only for a positive edge (true assertion) of these
status bits. Reading the USR register not only clears the
edge detect circuit but also clears (sets to 0) all of the status
bits. The output pins associated with these status bits are not
affected by reading the USR register.
A hardware reset of the 82C52 sets the TC status bit in the
USR. When interrupts are subsequently enabled an interrupt
can occur due to the fact that the positive edge detection
circuitry in the interrupt logic has detected the setting of the
TC bit. If this interrupt is not desired the USR should be read
prior to enabling interrupts. This action resets the positive
edge detection circuitry in the interrupt control logic (Figure 9).
The 82C52 crystal oscillator circuitry is designed to operate
with a fundamental mode, parallel resonant crystal. This
circuit is the same one used in the Intersil 82C84A clock
generator/driver. To summarize, Table 3 and Figure 10 show
the required crystal parameters and crystal circuit
configuration respectively.
When using an external clock source, the IX input is driven
and the OX output is left open. Power consumption when
using an external clock is typically 50% of that required when
using a crystal. This is due to the sinusoidal nature of the
drive circuitry when using a crystal.
TABLE 3.
PARAMETER
TYPICAL CRYSTAL
SPECIFICATION
Frequency
1.0 to 16MHz
Type of Operation
Parallel Resonant, Fundamental Mode
Load Capacitance (CL)
20 or 32pF (Typ)
RSERIES(Max)
100 (f = 16MHz, CL = 32pF)
200 (f = 16MHz, CL = 20pF)
NOTE: For USR and MSR, the setting of status bits is inhibited
during status register READ operations. If a status condition is
9
FN2950.4
November 25, 2015
82C52
C1 (NOTE)
GND
By using the Intersil CMOS 82C84A clock generator, the
system can be built with a single crystal providing both the
processor clock and the clock for the 82C52. The 82C52 has
special divider circuitry which is designed to supply industry
standard baud rates with a 2.4576MHz input frequency.
Using a 15MHz crystal as shown, results in less than a 2%
frequency error which is adequate for many applications. For
more precise baud rate requirements, a 14.7456MHz crystal
will drive the 80C86 at 4.9MHz and provide the 82C52 with
the standard baud rate input frequency of 2.4576MHz. If
baud rates above 156Kbaud are desired, the OSC output
can be used instead of the PCLK (6) output for
asynchronous baud rates up to 1Mbaud.
IX
82C52
C2 (NOTE)
OX
NOTE: C1 = C2 = 20pF For CL = 20pF
C1 = C2 = 47pF For CL = 32pF
FIGURE 10.
82C52 - 80C86 Interfacing
The following example (Figure 11) shows the interface for an
82C52 in an 80C86 system.
Use of the Intersil CMOS Interrupt Controller (82C59A) is
optional and necessary only if an interrupt driven system is
desired.
CHIP SELECT
CSO
D0-D7
AD0, AD7
ADDRESS BUS
80C86
OR
80C88
82C88
(MAX MODE)
INT
CLK
X1
CLK
PCLK
15MHz
X2
OSC
INTA
INT IRX
82C59A
IORD
IOWR
3
2
SDO
A0, A1
RD
WR
SDI
SERIAL
DATA
82C52
INTR, DR, TBRE
INTA
IX
5MHz
2.5MHz
15MHz
82C84A OR
82C85
FIGURE 11. 80C86/82C52 INTERFACE
10
FN2950.4
November 25, 2015
82C52
Absolute Maximum Ratings
Thermal Information
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +8.0V
Input, Output or I/O Voltage . . . . . . . . . . . . GND-0.5V to VCC +0.5V
ESD Classification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Class 1
Thermal Resistance (Typical, Note 1)
JA (°C/W) JC (°C/W)
CERDIP Package . . . . . . . . . . . . . . . .
45
8.4
CLCC Package . . . . . . . . . . . . . . . . . .
60
14
PDIP Package . . . . . . . . . . . . . . . . . . .
55
N/A
PLCC Package . . . . . . . . . . . . . . . . . .
46
N/A
Maximum Junction Temperature
Ceramic Package. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +175°C
Plastic Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +150°C
Maximum Storage Temperature Range. . . . . . . . . . -65°C to +150°C
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . +300°C
(Lead Tips Only For Surface Mount Packages)
Operating Conditions
Operating Voltage Range. . . . . . . . . . . . . . . . . . . . . . +4.5V to +5.5V
Operating Temperature Range
C82C52 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C
I82C52 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-40°C to +85°C
M82C52 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-55°C to +125°C
Die Characteristics
Gate Count . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1500 Gates
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.
NOTE:
1. JA is measured with the component mounted on an evaluation PC board in free air.
DC Electrical Specifications VCC = 5.0V 10%, TA = 0°C to +70°C (C82C52), TA = -40°C to +85°C (l82C52)
TA = -55°C to +125°C (M82C52)
SYMBOL
VIH
PARAMETER
Logical One Input Voltage
MIN
MAX
UNITS
TEST CONDITIONS
2.0
-
V
I82C52, C82C52
2.2
-
V
M82C52
-
0.8
V
VIL
Logical Zero Input Voltage
VTH
Schmitt Trigger Logic One Input Voltage
VCC -0.5
-
V
Reset Input
VTL
Schmitt Trigger Logic Zero Input Voltage
-
GND +0.5
V
Reset Input
VIH (CLK)
Logical One Clock Input Voltage
VCC -0.5
-
V
External Clock
VlL (CLK)
Logical Zero Clock Input Voltage
-
GND +0.5
V
External Clock
3.0
-
V
IOH = -2.5mA, Except OX
VCC -0.4
-
V
IOH = -100A, For OX - IOH = -1.0mA
-
0.4
V
lOL = +2.5mA
VOH
VOL
Output High Voltage
Output Low Voltage
II
Input Leakage Current
-1.0
+1.0
A
VIN = GND or VCC, DIP Pins 1, 2, 11, 12, 17,
18, 23, 25, 28
IO
Input/Output Leakage Current
-10.0
+10.0
A
VO = GND or VCC, DIP Pins 3-10
ICCOP
Operating Power Supply Current
(Note 1)
-
4
mA
External Clock F = 2.4576MHz,
VCC = 5.5V, VIN = VCC or GND,
Outputs Open
ICCSB
Standby Supply Current
-
100
A
VCC = 5.5V, VIN = VCC or GND,
Outputs Open
TYPICAL
UNITS
TEST CONDITIONS
Input Capacitance
12
pF
Output Capacitance
15
pF
I/O Capacitance
15
pF
NOTE:
1. Guaranteed and sampled, but not 100% tested. ICCOP is typically  1.5mA/MHz.
Capacitance TA = 25°C
SYMBOL
CIN
COUT
CI/O
PARAMETER
11
FREQ = 1MHz, all measurements are
referenced to device GND
FN2950.4
November 25, 2015
82C52
AC Electrical Specifications VCC = 5.0V 10%, TA = 0°C to +70°C (C82C52), TA = -40°C to +85°C (l82C52)
TA = -55°C to +125°C (M82C52)
Timing Requirements and Responses
SYMBOL
PARAMETER
MIN
MAX
UNITS
TEST CONDITIONS
(1)
TSVCTL
Select Setup to Control Leading Edge
30
-
ns
(2)
TCTHSX
Select Hold from Control Trailing Edge
50
-
ns
(3)
TCTLCTH
Control Pulse Width
150
-
ns
(4)
TCTHCTL
Control Disable to Control Enable
190
-
ns
(5)
TRLDV
Read Low to Data Valid
-
120
ns
1, See AC Test Circuit
(6)
TRHDZ
Read Disable
0
60
ns
2, See AC Test Circuit
(7)
TDVWH
Data Setup Time
50
-
ns
(8)
TWHDX
Data Hold Time
20
-
ns
(9)
FC
Clock Frequency
0
16
MHz
(10)
TCHCL
Clock High Time
25
-
ns
(11)
TCLCH
Clock Low Time
25
-
ns
(12)
TR/TF
IX Input Rise/Fall Time (External Clock)
-
tx
ns
1
tx  ------------ or 50ns
6FC
Whichever is smaller
(13)
TFCO
Clock Output Fall Time
-
15
ns
CL = 50pf
(14)
TRCO
Clock Output Rise Time
-
15
ns
CL = 50pf
Control Consists of RD or
WR
TCHCL + TCLCH must be
 62.5ns
AC Testing Input, Output Waveforms
INPUT
VIH + 0.4V
OUTPUT
VOH
1.5V
OUTPUT
1.5V
VIL - 0.4V
90%
10%
VOL
FIGURE 12. PROPAGATION DELAY
FIGURE 13. ENABLE/DISABLE DELAY
AC TESTING: All input signals (except IX and RST) must switch between VIL -0.4V and VIH +0.4V. Input rise and fall times are driven at 1ns/V.
12
FN2950.4
November 25, 2015
82C52
Timing Waveform
NEXT BUS CYCLE
SELECT VALID
CS0, A0, A1
(1)
TSVCTL
(3)
TCTLCTH
(2)
TCTHSX
WR
WRITE
OPERATION
(7)
TDVWH
D0-D7
(8)
TWHDX
VALID
(1)
TSVCTL
(3)
TCTLCTH
(4)
TCTHCTL
RD
(5)
TRLDV
READ
OPERATION
(6)
TRHDZ
D0-D7
FIGURE 14. BUS OPERATION
AC Test Circuit
V1
TEST CONDITION
R1
OUTPUT FROM
DEVICE UNDER
TEST
TEST POINT
V1
R1
R2
CL
1
Propagation Delay
1.7V
520

100pF
2
Disable Delay
VCC
5K
5K
50pF
R2
CL
13
FN2950.4
November 25, 2015
82C52
UART Timing Characterization
All parameters listed in this table were laboratory bench characterized at room temperature on a small sample of parts. No guarantee is implied. The main intent here is
to clarify functional operation of the 82C52.
82C52 UART Timing Characterized with IX = External Clock
SYMBOL
PARAMETER
MIN
MAX
UNITS
TEST CONDITIONS
(15)
TS1
CO(IX) Delay from IX
-
30
ns
BRSR Bit D7 = 0
(IX Output)
(16)
TS2
CO (BRG) Delay from IX
-
80
ns
BRSR Bit D7 = 1
(BRG Output)
(17)
TCY
CO (BRG) Clock Cycle Time
62.5
-
ns
BRSR Bit D7 = 1
(BRG Output), Note 1
(18)
TDTX
SDO Delay from CO(BRG) Low
-
30
ns
Note 2
(19)
TWLTL
WR Low to TBRE Low
-
50
ns
Note 3
(20)
TCLTH
CO (BRG) Low to TBRE HIgh
-
50
ns
Notes 3, 4
(21)
TIHF
INTR High on Flag
-
50
ns
Note 5A, 5B
(22)
TIHM
INTR High on MS
-
50
ns
Note 5
(23)
TRLIL
RD Low to INTR Low
-
60
ns
(24)
TCTHX
CTS High to Disable Transmit
4TCY + 10
-
ns
TBR Full, Note 6
(25)
TDRH
CO (BRG) Low to DR High
-
40
ns
Note 7
(26)
TRLDL
RD Low to DR Low
-
50
ns
Note 7
(27)
TWHO
WR High to RTS/DTR Active
-
50
ns
NOTES:
1. Prescaler rate of divide by 1, Divisor Select rate of “external” (divide by 1). The Baud Rate Clock (CO-BRG) operates at 16 times the user
programmed bit rate. For example, at 1200 baud: TCY = 1/(16 x 1200) = 52.1s.
2. A. With TR (Transmitter Register) initially empty, TDTX occurs from the 5th falling edge of CO(BRG) after WR goes high.
B. With TR initially full, TDTX occurs from the trailing edge of the 16th CO(BRG) in the last Stop bit provided WR went high by the trailing edge
of the 12th CO(BRG) in the last Stop bit.
C. With CTS high (disable transmit) and TBR full, TDTX occurs from the 5th falling edge of CO(BRG) after CTS goes low.
3. TBRE bit D6 in USR is updated each time TBRE changes state.
4. A. With TR initially empty, TCLTH(TBRE) occurs from the 4th falling edge of CO(BRG) after WR goes high.
B. With TR initially full, TCLTH(TBRE) occurs from the trailing edge of the 15th CO(BRG) in the last Stop bit provided WR went high by the
trailing edge of the 12th CO(BRG) in the last Stop bit.
C. With CTS high (disable transmit) and TBR full, TCLTH(TBRE) occurs from the 4th falling edge of CO(BRG) after CTS goes low.
5. A. INT on TC: INTEN enabled; USR bit D5(TC) is updated at this time regardless of interrupt configuration.
- INT on TC occurs from the trailing edge of the 11th CO(BRG) in the last Stop bit if TBR empty at that time.
B. INTR on receive flags OE, FE, PE, and RBRK: INTEN enabled; Respective USR bits updated at this time regardless of interrupt configuration.
- INT on OE, FE, PE, RBRK occurs from the trailing edge of the 11th CO(BRG) in the last Stop bit. To avoid OE, RD(RBR) must go low by
the trailing edge of the 8th CO(BRG) in the last Stop bit.
C. INTR on MS: INTEN and MIEN enabled; USR bit D4(MS) is updated at this time regardless of INTEN/MIEN.
- INTR on MS occurs whenever CTS or DSR input changes state.
6. TCTHX is time before end of last Stop bit by which CTS must be inactive (high) to prevent transmission of the character waiting in TBR.
7. DR bit D7 in USR is updated each time DR changes state. TDRH always from trailing edge of 11th CO(BRG) in last Stop bit.
14
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November 25, 2015
82C52
UART Timing Characterization
TCHCL (11)
IX
TCLCH (10)
(15)
TS1
CO(IX)
(16)
TS2
CO(BRG)
TCY
(17)
FIGURE 15. CLOCK (IX) AND CO TIMING
CO(BRG)
16 CO(BRG) PERIODS
TDTX (18)
TX DATA
TDTX (18)
DATA BIT
FIGURE 16. TRANSMITTER DATA
CO(BRG)
8 CO(BRG) PERIODS
16 CO(BRG) PERIODS
RX DATA
DATA BIT
START BIT
RX BAUD COUNTER
STARTS HERE
INTERNAL
SAMPLE
FIGURE 17. RECEIVER DATA
15
FN2950.4
November 25, 2015
82C52
UART Timing Characterization
8/I
9/I
10/I
(Continued)
11/I
12/I
13/I
14/I
15/I
16/I
I/1
I/2
I/3
CO(BRG)
WR
(20)
TCLTH
(19)
TWLTL
TBRE
NOTE 2
NOTE 1
(18)
TDTX
NOTE 3
LAST STOP BIT / IDLE
SDO
IDLE / START BIT
RD
(21)
TIHF
(23)
TRLIL
INTR
11
12
13
14
15
16
1
2
CO(BRG)
(24)
TCTHX
CTS
NOTE 4
(20)
TCLTH
NOTE 5
(18)
TDTX
TBRE
NOTE 6
SDO
LAST STOP BIT
IDLE
START BIT
DISABLED
FIGURE 18. TRANSMIT TIMING
16
FN2950.4
November 25, 2015
82C52
UART Timing Characterization
(Continued)
NOTES:
1. TBRE bit D6 in USR is updated each time TBRE changes state.
2. A. With TR initially empty, TCLTH(TBRE) occurs from the 4th falling edge of CO(BRG) after WR goes high.
B. With TR initially full, TCLTH(TBRE) occurs from the trailing edge of the 15th CO(BRG) in the last Stop bit provided WR went high by the
trailing edge of the 12th CO(BRG) in the last Stop bit.
3. A. With TR (Transmitter Register) initially empty, TDTX occurs from the 5th falling edge of CO(BRG) after WR goes high.
B. With TR initially full, TDTX occurs from the trailing edge of the 16th CO(BRG) in the last Stop bit provided WR went high by the trailing edge
of the 12th CO(BRG) in the last Stop bit.
4. TCTHX is time before end of last Stop bit by which CTS must be inactive (high) to prevent transmission of the character waiting in TBR.
5. With CTS high (disable transmit) and TBR full, TCLTH(TBRE) occurs from the 4th falling edge of CO(BRG) after CTS goes low.
6. With CTS high (disable transmit) and TBR full, TDTX occurs from the 5th falling edge of CO(BRG) after CTS goes low.
11
12
13
14
15
16
1/I
2/I
3/I
CO(BRG)
LAST STOP BIT
SDI
START BIT / IDLE
RD
RBR
DR
INTR
USR
(25)
(26)
TDRH
TRLDL
NOTE 1
(21)
(23)
TIHF
TRLIL
NOTE 2
FIGURE 19. RECEIVE TIMING
17
FN2950.4
November 25, 2015
82C52
UART Timing Characterization
(Continued)
MCR
WR
(27)
TWHO
RTS/DTR
MSR
RD
DSR/CTS
INTR
(22)
(23)
TIHM
TRLIL
NOTE 3
FIGURE 20. OTHER TIMING
NOTES:
1. DR bit D7 in USR is updated each time DR changes state. TDRH always from trailing edge of 11th CO(BRG) in last Stop bit.
2. INTR on receive flags OE, FE, PE, and RBRK: INTEN enabled; Respective USR bits updated at this time regardless of interrupt configuration.
- INT on OE, FE, PE, RBRK occurs from the trailing edge of the 11th CO(BRG) in the last Stop bit. To avoid OE, RD(RBR) must go low by the
trailing edge of the 8th CO(BRG) in the last Stop bit.
3. INTR on MS: INTEN and MIEN enabled; USR bit D4(MS) is updated at this time regardless of INTEN/MIEN.
- INTR on MS occurs whenever CTS or DSR input changes state.
18
FN2950.4
November 25, 2015
82C52
Burn-In Circuits
MD82C52 CERDIP
R1
VCC
28
2
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
GND
13
16
GND
14
15
R2
GND
R2
Q4
R2
Q5
R2
Q6
R2
Q7
R2
Q8
R2
Q7
R2
Q8
R2
Q1
R2
Q2
R2
F0
R1
VCC/2
GND
1
R2
Q3
VCC
R1
VCC/2
R1
C2
VCC
R1
VCC/2
A
R1
VCC/2
R1
VCC/2
R1
VCC/2
R1
VCC
VCC/2
R1
C1
VCC
R1
A
R3
VCC/2
MR82C52 CLCC
VCC
Q4 GND Q3
R2
Q5
Q6
Q7
Q8
Q7
Q8
Q1
R2
R2
R2
R2
R2
R2
R2
4
R2
3
VCC
GND
R2
2
C2
R1
1
R1
28
27
26
25
5
6
24
7
23
22
8
21
9
R1
R1
20
11
19
12
13
R2
Q2
R2
F0
14
15
R1
VCC/2
16
17
R1
18
R1
GND
VCC/2
A
R1
R1
R1
10
VCC
R1
VCC/2
VCC/2
VCC
VCC/2
C1
VCC/2
A
R3
VCC
NOTES:
1. VCC = 5.5V 0.5V
GND = 0V
2. VIH = 4.5V 10%
VIL = -0.2V to +0.4V
3. Component Values:
R1 = 1.2K, 1/4W, 5%
R2 = 47K, 1/4W, 5%
R3 = 10K, 1/4W, 5%
C1 = 1.0F nominal
C2 = 0.01F minimum
F0 = 100KHz 10%, F1 = F0/2, F2 = F1/2 . . . F12 = F11/2
19
FN2950.4
November 25, 2015
82C52
Die Characteristics
DIE DIMENSIONS:
178.7 x 187.0 x 19 1mils
GLASSIVATION:
Type: Nitrox
Thickness: 10kÅ
METALLIZATION:
Type: Silicon - Aluminum
Thickness: 11kÅ 2kÅ
WORST CASE CURRENT DENSITY:
2.07 x 104 A/cm2
Metallization Mask Layout
82C52
D0
WR
RD
CSO
VCC
DR
D1
SD1
D2
INTR
D3
RST
D4
TBRE
D5
CO
D6
RTS
D7
DTR
A0
DSR
A1
IX
20
OX
SDO
GND
CTS
FN2950.4
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82C52
Revision History
The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to the web to make sure that
you have the latest revision.
DATE
REVISION
November 25, 2015
FN2950.4
CHANGE
Updated Ordering Information Table on page 1.
Added Revision History and About Intersil sections.
About Intersil
Intersil Corporation is a leading provider of innovative power management and precision analog solutions. The company's products
address some of the largest markets within the industrial and infrastructure, mobile computing and high-end consumer markets.
For the most updated datasheet, application notes, related documentation and related parts, please see the respective product
information page found at www.intersil.com.
You may report errors or suggestions for improving this datasheet by visiting www.intersil.com/ask.
Reliability reports are also available from our website at www.intersil.com/support
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9001 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
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FN2950.4
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