LANSDALE ML145443RP

ML145442
ML145443
Single–Chip 300–Baud Modem
Legacy Device: Motorola MC145442B, MC145443B
The ML145442 and ML145443 silicon–gate CMOS single–chip low–speed
modems contain a complete frequency shift keying (FSK) modulator, demodulator, and filter. These devices are compatible with CCITT V.21 (ML145442)
and Bell 103 (ML145443) specifications. Both devices provide full–duplex or
half–duplex 300–baud data communication over a pair of telephone lines.
They also include a carrier detect circuit for the demodulator section and a
duplexer circuit for direct operation on a telephone line through a simple
transformer.
This Device Offers The Following Performance Features:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
ML145442 Compatible with CCITT V.21
ML145443 Compatible with Bell 103
Low–Band and High–Band Band–Pass Filters On–Chip
Simplex, Half–Duplex, and Full–Duplex Operation
Originate and Answer Mode
Analog Loopback Configuration for Self Test
Hybrid Network Function On–Chip
Carrier Detect Circuit On–Chip
Adjustable Transmit Level and CD Delay Timing
On–Chip Crystal Oscillator (3.579 MHz)
Single +5 V Power Supply Operation
Internal Mid–Supply Generator
Power–Down Mode
Pin Compatible with MM74HC943
Capable of Driving –9 dBm into a 600 W Load
Operating Temperature Range = TA –40° to +85°C
Page 1 of 11
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P DIP 20 = RP
PLASTIC DIP
CASE 738
20
1
SOG 20 = -6P
SOG PACKAGE
CASE 751D
20
1
CROSS REFERENCE/ORDERING INFORMATION
LANSDALE
MOTOROLA
PACKAGE
P DIP 20 H
SO 20W
P DIP 20 H
SO 20W
MC145442BP
MC145442BDW
MC145443BP
MC145443BDW
ML145442RP
ML145442-6P
ML145443RP
ML145443-6P
Note: Lansdale lead free (Pb) product, as it
becomes available, will be identified by a part
number prefix change from ML to MLE.
PIN ASSIGNMENT
DSI
1
20
TLA
LB
2
19
VAG
CD
3
18
Exl
CDT
4
17
TxA
RxD
5
16
RxA1
V DD
6
15
RxA2
CDA
7
14
SQT
X out
8
13
MODE
X in
9
12
V SS
FB
10
11
TxD
Issue b
B
ML145442, ML145443
LANSDALE Semiconductor, Inc.
BLOCK DIAGRAM
4
7
LOW–BAND
BPF
RxA2 15
–
+
RxA1 16
AAF
CARRIER 3
DETECT
S/H
AC AMP
*
HIGH–BAND
BPF
LB
MODE
SQT
TxD
TLA
Xout
Xin
2
13
14
11
20
8
9
MODULATOR
OSCILLATOR
INTERNAL
VAG
CLOCK
DIVIDER
SAMPLING CLOCK: 77.82 kHz
SAMPLING CLOCK: 19.46 kHz
5
CD
RxD
10
FB
1
DSI
SMOOTHING
FILTER
MODE
CONTROL
DEMOD
CDT
CDA
ANALOG
GROUND
GENERATOR
–
17
+
18
19
6
12
TxA
ExI
VAG
VDD
VSS
* Refer to the FB pin description.
ABSOLUTE MAXIMUM RATINGS (Voltages Referenced to VSS)
Rating
Symbol
Supply Voltage
Value
Unit
VDD
–0.5 to 7.0
V
DC Input Voltage
Vin
–0.5 to VDD + 0.5
V
DC Output Voltage
Vout
–0.5 to VDD + 0.5
V
IIK, IOK
±20
mA
DC Output Current, per Pin
Iout
±28
mA
Power Dissipation
PD
500
mW
Clamp Diode Current, per Pin
TA
–40 to 85
°C
Tstg
–65 to 150
°C
Operating Temperature Range
Storage Temperature Range
This device contains circuitry to protect the
inputs against damage due to high static voltages or electric fields; however, it is advised that
normal precautions be taken to avoid application
of any voltage higher than maximum rated
voltages to this high impedance circuit. For
proper operation it is recommended that Vin and
Vout be constrained to the range VSS ≤ (Vin or
Vout) ≤ VDD).
Unused inputs must always be tied to an
appropriate logic voltage level (e.g., either VSS
or VDD).
RECOMMENDED OPERATING CONDITIONS
Parameter
Supply Voltage
DC Input or Output Voltage
Input Rise or Fall Time
Crystal Frequency*
Symbol
Min
Max
Unit
VDD
4.5
5.5
V
Vin, Vout
0
VDD
V
tr, tf
—
500
ns
fcrystal
3.2
5.0
MHz
* Changing the crystal frequency from 3.579 MHz will change the output frequencies. The
change in output frequency will be proportional to the change in crystal frequency.
Page 2 of 11
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Issue b
B
LANSDALE Semiconductor, Inc.
ML145442, ML145443
DC ELECTRICAL CHARACTERISTICS (VDD = 5.0 V ±10%, TA = –40° to 85°C)
Characteristic
Symbol
Min
Typ
Max
Unit
High–Level Input Voltage
LB
Xin, TxD, Mode, SQT
VIH
VDD – 0.8
3.15
—
—
—
—
V
Low–Level Input Voltage
LB
Xin, TxD, Mode, SQT
VIL
—
—
—
—
0.8
1.1
V
VDD – 0.1
3.7
—
—
—
VDD – 0.05
—
—
—
—
—
—
—
—
0.05
0.1
0.4
—
Iin
—
—
—
—
—
10
—
—
±1.0
±12
±20
±10
µA
IDD
—
7
10
mA
CD, RxD
CD, RxD
Xout
Low–Level Output Voltage
IOL = 20 µA
IOL = 2 mA
IOL = 20 µA
CD, RxD
CD, RxD
Xout
Input Current
V
VOH
High–Level Output Voltage
IOH = 20 µA
IOH = 2 mA
IOH = 20 µA
V
VOL
LB, TxD, Mode, SQT
RxA1, RxA2 (0°
TA
85°C)
RxA1, RxA2 (–40°
TA < 0°C)
Xin
Quiesent Supply Current (Xin or fcrystal = 3.579 MHz)
—
200
300
µA
Cin
—
—
10
—
—
10
pF
VAG Output Voltage (IO = ±10 µA)
VAG
2.4
2.5
2.6
V
CDA Output Voltage (IO = ±10 µA)
VCDA
1.1
1.2
1.3
V
Rf
10
20
30
kΩ
Unit
Power–Down Supply Current
Input Capacitance
Xin
All Other Inputs
Line Driver Feedback Resistor
AC ELECTRICAL CHARACTERISTICS
(VDD = 5.0 V ±10%, TA = –40° to 85°C, Crystal Frequency = 3.579 MHz ±0.1%; See Figure 1)
Characteristic
Min
Typ
Max
–13
–10
–12
–9
–11
–8
—
– 56
—
dBm
40
50
—
kΩ
TRANSMITTER
Power Output on TxA
RL = 1.2 kΩ, RTLA = ∞
RL = 1.2 kΩ, RTLA = 5.5 kΩ
dBm
Second Harmonic Power
RL = 1.2 kΩ
RECEIVE FILTER AND HYBRID
Hybrid Input Impedance RxA1, RxA2
FB Output Impedance
—
16
—
kΩ
–48
—
—
dBm
–48
—
–12
dBm
Dynamic Range
—
36
—
dB
Bit Jitter (S/N = 30 dB, Input = –38 dBm, Bit Rate = 300 baud)
—
100
—
µs
Bit Bias
—
5
—
%
—
—
–44
–47
—
—
dBm
Adjacent Channel Rejection
DEMODULATOR
Receive Carrier Amplitude
Carrier Detect Threshold
(CDA = 1.2 V or CDA grounded through a 0.1 µF capacitor)
Page 3 of 11
On to Off
Off to On
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Issue b
ML145442, ML145443
LANSDALE Semiconductor, Inc.
Table 1. Bell 103 and CCITT V.21
Frequency Characteristics
Originate Mode
3.579 MHz ± 0.1%
Data
Transmit
Answer Mode
Receive
Transmit
Receive
Bell 103 (ML145443)
8
9
R TLA
X out
X in
11
20
TLA
TxD
V DD
17
TxA
15
RxA2
ML145442
600 Ω
ML145443
600 Ω
16
5
RxA1
RxD
TEST
CDT
FB
OUTPUT
TEST
4
10
INPUT
0.1 µF
0.1 µF
D out
2025 Hz
2025 Hz
1070 Hz
Mark
1270 Hz
2225 Hz
2225 Hz
1270 Hz
Space
1180 Hz
1850 Hz
1850 Hz
1180 Hz
Mark
980 Hz
1650 Hz
1650 Hz
980 Hz
NOTE: Actual frequencies may be ±5 Hz assuming 3.579545 MHz
crystal is used.
MAXIMUM LEVEL OF OUT–OF–BAND ENERGY
RELATIVE TO THE TRANSMIT CARRIER LEVEL INTO 600 Ω (kHz)
0
C FB
Figure 1. AC Characteristics Evaluation Circuit
PIN DESCRIPTIONS
VDD
Positive Power Supply (Pin 6)
This pin is normally tied to 5.0 V.
VSS
Negative Power Supply (Pin 12)
This pin is normally tied to 0 V.
VAG
Analog Ground (Pin 19)
Analog ground is internally biased to (VDD – VSS)/2. This
pin must be decoupled by a capacitor from VAG to VSS and a
capacitor from VAG to VDD. Analog ground is the common bias
line used in the switched capacitor filters, limiter, and slicer in
the demodulation circuitry.
TLA
Transmit Level Adjust (Pin 20)
This pin is used to adjust the transmit level. Transmit level
adjustment range is typically from –12 dBm to –9 dBm. (See
Legacy Applications Information.)
TxD
Transmit Data (Pin 11)
Binary information is input to the transmit data pin. Data
entered for transmission is modulated using FSK techniques. A
logic high input level represents a mark and a logic low represents a space (see Table 1).
TxA
Transmit Carrier (Pin 17)
This is the output of the line driver amplifier. The transmit
carrier is the digitally synthesized sine wave output of the modulator derived from a crystal oscillator reference. When a 3.579
MHz crystal is used the frequency outputs shown in Table 1
apply. (See Legacy Applications Information.)
Page 4 of 11
1070 Hz
CCITT V.21 (ML145442)
T R A N S MIT C A R R IE R LE V E L ( dBm)
C CDT
D in
Space
2 3.4 4
16
64
256
0
–20
–25
15 dB/OCTAVE
–55
–60
Figure 2. Out–of–Band Energy
ExI
External Input (Pin 18)
The external input is the non–inverting input to the line driver.
It is provided to combine an auxiliary audio signal or speech
signal to the phone line using the line driver. This pin should be
connected to VAG if not used. The average level must be the
same as VAG to maintain proper operation. (See Legacy
Applications Information.)
DSI
Driver Summing Input (Pin 1)
The driver summing input may be used to connect an external
signal, such as a DTMF dialer, to the phone line. A series resistor, RDSI, is needed to define the voltage gain AV (see Legacy
Applications Information and Figure 6). When applying a signal
to the DSI pin, the modulator should be squelched by bringing
SQT (pin 14) to a logic high level. The voltage gain, AV, is calculated by the formula AV = –Rf/RDSI (where Rf≈ 20 kΩ). For
example, a 20 kΩ resistor for RDSI will provide unity gain (AV
= –20 kΩ/20 kΩ = –1). This pin must be left open if not used.
RxD
Receive Data (Pin 6)
The receive data output pin presents the digital binary data
resulting from the demodulation of the receive carrier. If no carrier is present, CD high, the receive data output (RxD) is
clamped high.
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LANSDALE Semiconductor, Inc.
ML145442, ML145443
RxA2, RxA1
Receive Carrier (Pins 15, 16)
The receive carrier is the FSK input to the demodulator through
the receive band–pass filter. RxA1 is the non–inverting input and
RxA2 is the inverting input of the receive hybrid (duplexer) operational amplifier.
LB
Analog Loopback (Pin 2)
When a high level is applied to this pin (SQT must be low), the
analog loopback test is enabled. The analog loopback test connects the TxA pin to the RxA2 pin and the RxA1 to analog
ground. In loopback, the demodulator frequencies are switched to
the modulation frequencies for the selected mode. (See Tables 1
and 2 and Figures 4c and 4d.)
When LB is connected to analog ground (VAG), the modulator
generates an echo cancellation tone of 2100 Hz for ML145442
CCITT V.21 and 2225 Hz for ML145443 Bell 103 systems. For
normal operation, this pin should be at a logic low level (VSS).
The power–down mode is enabled when both LB and SQT are
connected to a logic high level (see Table 2).
Table 2. Functional Table
MODE
Pin 13
SQT
Pin 14
LB
Pin 2
1
0
0
Originate Mode
0
0
0
Answer Mode
X
0
VAG (VDD/2)
X
0
1
Analog Loopback
X
1
0
Squelch Mode
X
1
VAG (VDD/2)
Squelch Mode
X
1
1
Operating Mode
Echo Tone
Power Down
MODE
Mode (Pin 13)
This input selects the pair of transmit and frequencies used during modulation and demodulation. When a logic high level is
placed on this input, originate (Bell) or channel 1(CCITT) is
selected. When a low level is placed on this input, answer (Bell) or
channel 2 (CCITT) is selected. (See Tables 1 and 2 and Figure 4.)
CDT
Carrier Detect Timing (Pin 4)
A capacitor on this pin to VSS sets the amount of time the carrier must be present before CD goes low (see Legacy Applications
Information for the capacitor values).
CD
Carrier Detect Output (Pin 3)
This output is used to indicate when a carrier has been sensed
by the carrier detect circuit. This output goes to a logic low level
when a valid signal above the maximum threshold level (defined
by CDA, pin 7) is maintained on the input to the hybrid circuit
longer then the response (defined by CDT, pin 4). This pin is held
at the logic low level until the signal falls below the maximum
Page 5 of 11
threshold level for longer than the turn off time. (See Legacy
Applications Information and Figure 5.)
CDA
Carrier Detect Adjust (Pin 7)
An external voltage may be applied to this pin to adjust the carrier detect threshold. The threshold hysteresis is internally fixed at
3 dB (see Legacy Applications Information).
Xout, Xin
Crystal Oscillator (Pins 8, 9)
A crystal reference oscillator is formed when a 3.579 MHz
crystal is connected between these two pins. Xout (pin 8) is the
output of the oscillator circuit, and Xin (pin 9) is the input to the
oscillator circuit. When using an external clock, apply the clock to
the Xin (pin 9) pin and leave Xout (pin 8) open. An internal 10
MΩ resistor and internal capacitors, typically 10 pF on Xin and
16 pF on Xout, allow the crystal to be connected without any
other external components. Printed circuit board layout should
keep external stray capacitance to a minimum.
FB
Filter Bias (Pin 10)
This is the negative input to the AC amplifier. In normal operation, this pin is connected to analog ground through a 0.1µF
bypass capacitor in order to cancel the input offset voltage of the
limiter. It has a nominal input impedance of 16 kΩ (see Figure 3).
SQT
Transmit Squelch (Pin 14)
When this input pin is at a logic high level, the modulator is
disabled. The line driver remains active if LB is at a logic low
level (see Table 2).
When both LB and SQT are connected to a logic high level (see
Table 2), the entire chip is in a power down state and all circuitry
except the crystal oscillator is disabled. Total power supply current decreases from 10 mA (max) to 300 µA (max).
FROM
BAND–PASS
FILTER
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TO
CARRIER DETECT CIRCUIT
AND DEMODULATOR
+
–
490 kΩ
16 kΩ
10
FB
0.1 µF
Figure 3. AC Amplifier Circuit
Issue b
ML145442, ML145443
LANSDALE Semiconductor, Inc.
GENERAL DESCRIPTION
The ML145442 and ML145443 are full–duplex low–speed
modems. They provide a 300–baud FSK signal for bidirectional
data transmission over the telephone network. They can be operated
in one of four basic configurations as determined by the state of
MODE (pin 13) and LB (pin 2).The normal (non–loopback) and
self test (loopback) modes in both answer and originate modes will
be discussed.
For an originate or channel 1 mode, a logic high level is placed
on MODE (pin 13) and a logic low level is placed on LB (pin 2). In
this mode, transmit data is input on TxD, where it is converted to a
FSK signal and routed through a low–band band–pass filter. The
filtered output signal is then buffered by the Tx op–amp line driver,
which is capable of driving –9 dBm onto a 600Ω line. The receive
signal is connected through a hybrid duplexer circuit on pins 15 and
16, RxA2 and RxA1. The signal then passes through the anti–aliasing filter, the sample–and–hold circuit, is switched into the
high–band band–pass filter, and then switched into the AC amplifier circuit. The output of the ac amplifier circuit is routed to the
demodulator circuit and demodulated. The resulting digital data is
then output through RxD (pin 5). The carrier detect circuit receives
its signal from the output of the AC amplifier circuit and goes low
when the incoming signal is detected (see Figure 4a).
Page 6 of 11
In the answer or channel 2 mode, a logic low level is placed on
MODE (pin 13) and on LB (pin 2). In this mode, the data follows
the same path except the FSK signal is routed to the high–band
band–pass filter and the sample–and–hold signal is routed through
the low–band band–pass filter (see Figure 4b).
In the analog loopback originate or channel 1 mode, a logic high
level is placed on MODE (pin 13) and on LB (pin 2). This mode is
used for a self check of the modulator, demodulator, and low–band
pass–band filter circuit. The modulator side is configured exactly
like the originate mode above except the line driver output (TxA,
pin 17) is switched to the negative input of the hybrid op–amp. The
RxA2 input pin is open in this mode and the non–inverting input of
the hybrid circuit is connected to VAG. The sample–and–hold output bypasses the filter so that the demodulator receives the modulated Tx data (see Figure 4c). This test checks all internal device
components except the high–band band–pass filter, which can be
checked in the answer or channel 2 mode test.
In the analog loopback or channel 2 mode, a logic low level is
placed on MODE (pin 13) and a logic high level on LB (pin 2).
This mode is used for a self check of the modulator, demodulator,
and high–band pass–band filter circuit. This configuration is exactly like the originate loopback mode above, except the signal is routed through the high–band pass–band filter (see Figure 4d).
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LANSDALE Semiconductor, Inc.
RxA2
ML145442, ML145443
15
–
RxA1
16
AAF
+
AC
AMP
LOW–BAND
BPF
S/H
CARRIER
DETECT
3
5
DEMOD
1
TxD
11
SMOOTHING
FILTER
HIGH–BAND
BPF
MODULATOR
–
17
+
18
CD
RxD
DSI
TxA
Exl
(a) Originate/Channel 1 Mode (MODE = High, LB = Low)
RxA2
15
–
RxA1
16
AAF
+
AC
AMP
LOW–BAND
BPF
S/H
3
CARRIER
DETECT
5
DEMOD
1
TxD
11
SMOOTHING
FILTER
HIGH–BAND
BPF
MODULATOR
–
17
+
18
(b) Answer/Channel 2 Mode (MODE = Low, LB = Low)
RxA2
CD
RxD
DSI
TxA
Exl
15
–
RxA1 16
+
AAF
S/H
LOW–BAND
BPF
AC
AMP
CARRIER
DETECT
DEMOD
3
5
1
TxD
11
HIGH–BAND
BPF
MODULATOR
SMOOTHING
FILTER
–
17
+
18
CD
RxD
DSI
TxA
Exl
(c) Originate/Channel 1 Mode and Analog Loopback State (MODE = High, LB = Low)
RxA2
RxA1
15
16
–
+
AAF
S/H
LOW–BAND
BPF
AC
AMP
CARRIER
DETECT
DEMOD
3
5
1
TxD
11
MODULATOR
HIGH–BAND
BPF
SMOOTHING
FILTER
–
17
+
18
CD
RxD
DSI
TxA
Exl
(d) Answer/Channel 2 Mode and Analog Loopback State (MODE = Low, LB = Low)
Figure 4. Basic Operating Modes
Page 7 of 11
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Issue b
ML145442, ML145443
LANSDALE Semiconductor, Inc.
Legacy Applications Information
CARRIER DETECT TIMING ADJUSTMENT
The value of a capacitor, CCDT at CDT (pin 4) determines
how long a received modem signal must be present above the
minimum threshold level before CD (pin 3) goes low. The
CCDT capacitor also determines how long the CD pin stays
low after the received modem signal goes below the mini mum
threshold. The CD pin is used to distinguish a strong modem
signal from random noise. The following equations show the
relationship between tCDL, the time in seconds required for
CD to go low; tCDH, the time in seconds required for CD to
go high; and CCDT, the capacitor value in µF.
Valid signal to CD response time:
tCDL≈ 6.4 X CCDT
Invalid signal to CD off time:
tCDH ≈ 0.54 X CCDT
Example:
tCDL ≈ 6.4 X 0.1 µF ≈ 0.64 seconds
tCDH ≈ 0.54 X 0.1 µF ≈ 0.054 seconds
CARRIER DETECT THRESHOLD ADJUSTMENT
The carrier detect threshold is set by internal resistors to
activate CD with a typical –44 dBm (into 600 Ω) signal and
deactivate CD with a typical –47 dBm signal applied to the
input of the hybrid circuit. The carrier detect threshold level
can be adjusted by applying an external voltage on CDA (pin
7). The following equations may be used to find the CDA voltage required for a given threshold voltage. (Von and Voff are in
Vrms.)
VCDA = 244 x Von
VCDA = 345 x Voff
Example (Internally Set)
Von = 4.9 mV ≈ –44 dBm: VCDA = 244 x 4.9 mV = 1.2 V
Voff = 3.5 mV ≈ –47 dBm: VCDA = 345 x 3.5 mV = 1.2 V
Example (Externally Set)
Von = 7.7 mV ≈ –40 dBm: VCDA = 244 x 7.7 mV = 1.9 V
Voff = 5.4 mV ≈ –43 dBm: VCDA = 345 x 5.4 mV = 1.9 V
The CDA pin has an approximate Thevenin equivalent voltage of 1.2 V and an output impedance of 100 kΩ. When using
the internal 1.2 V reference, a 0.1 µF capacitor should be connected between this pin and VSS (see Figure 5).
TRANSMIT LEVEL ADJUSTMENT
The power output at TxA (pin 17) is determined by the value
of resistor RTLA that is connected between TLA (pin 20) to
VDD (pin 6). Table 3 shows the RTLA values and the corre-
Page 8 of 11
sponding power output for a 600 Ω load. The voltage at TxA is
twice the value of that at ring and tip because TxA feeds the
signal through a 600 Ω resistor RTx to a 600 Ω line transformer (see Figure 7). When choosing resistor RTLA, keep in
mind that –9 dBm is the maximum output level allowed from a
modem onto the telephone line (in the U.S.). In addition, keep
in mind that maximizing the power output from the modem
optimizes the signal–to–noise ratio, improving accurate data
transmission.
Table 3. Transmit Level Adjust
Output Transmit Level
(Typical into 600 Ω)
RTLA
–12 dBm
–11 dBm
–10 dBm
–9 dBm
∞
19.8 kΩ
9.2 kΩ
5.5 kΩ
THE LINE DRIVER
The line driver is a power amplifier used for driving a telephone line. Both the inverting and noninverting input to the line
driver are available for transmitting externally generated tones.
Exl (pin 18) is the noninverting input to the line driver and
gives a fixed gain of 2 (Ri = 50 kΩ). The average signal level
must be the same as VAG to maintain proper operation. This
pin should be connected to VAG if not used.
The driver summing input (DSI, pin 1) may be used to connect an external signal, such as a DTMF dialer, to the phone
line. When applying a signal to the DSI pin, the modulator
should be squelched by bringing SQT (pin 14) to a logic high
level. DSI must be left open if not used.
AV = –
Rf
R DSI
In addition, the DSI pin is the inverting side of the line driver and allows adjustable gain with a series resistor RDSI (see
Figure 6). The voltage gain, AV, is determined by the equation:
where Rf ≈ 20 kΩ.
Example: A resistor value of 20 kΩ for RDSI will provide
unity gain.
AV = – (20 kΩ/20 kΩ) = –1 .
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Issue b
LANSDALE Semiconductor, Inc.
ML145442, ML145443
Legacy Applications Information
V DD
HYBRID
ac
AMP
16
AUTO–NULLED
COMPARATOR
6 ms
RETRIGGERABLE
ONE–SHOT
RxA1
3
CD
V ref
CDA
7
V CDA ≈ 1.2 V
SAMPLING
CLOCK
THRESHOLD
CONTROL
4
C CDA
0.1 µF
CDT
C CDT
0.1 µF
Figure 5. Carrier Detect Circuit
MODULATOR
OUTPUT
R 0 = Rf
R DSI
DSI
1
R0
Rf
ExI
18
VAG
19
–
TxA
17
+
Ri
Figure 6. Line Driver Using the DSI Input
Page 9 of 11
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Issue b
ML145442, ML145443
LANSDALE Semiconductor, Inc.
Legacy Applications Information
L
Page 10 of 11
ML145407
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Issue b
LANSDALE Semiconductor, Inc.
ML145442, ML145443
Legacy Applications Information
Lansdale Semiconductor reserves the right to make changes without further notice to any products herein to improve reliability, function or design. Lansdale does not assume any liability arising out of the application or use of any product or circuit
described herein; neither does it convey any license under its patent rights nor the rights of others. “Typical” parameters which
may be provided in Lansdale data sheets and/or specifications can vary in different applications, and actual performance may
vary over time. All operating parameters, including “Typicals” must be validated for each customer application by the customer’s technical experts. Lansdale Semiconductor is a registered trademark of Lansdale Semiconductor, Inc.
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