73M2901/5V
Advanced Single
Chip Modem
DESCRIPTION
The 73M2901/5V is a single-chip modem that
combines all the controller (DTE) and data pump
functions necessary to implement an intelligent
V.22bis data modem. This device is based on TDK
Semiconductor’s implementation of the industry
standard 8032 microcontroller core with a proprietary
multiply and accumulate (MAC) coprocessor; Sigma-
Delta A/D and D/A converters; and an analog front
end. The ROM and RAM necessary to operate the
modem are contained on the device. Additionally,
the 73M2901/5V provides an on-chip oscillator and
Hybrid driver.
The 73M2901/5V is a high performance, low
voltage, low power, single chip modem capable of
data transmission and reception through 2400bps.
The 73M2901/5V is intended for embedded
applications and battery operation. This device
offers options for a low power conventional 5 volt
design with optional internal hybrid and country
specific call progress support.
FEATURES
Low overall system chip count. True one
chip solution for embedded systems
Low operating power (~250mW @ 5V,
automatic low power standby and power
down options available)
Internal ROM and RAM for normal operation
On chip optional hybrid driver
Designed for +5 volts (+/-10%)
Data speeds:
V.22bis – 2400bps
V.22, Bell 212 – 1200bps
V.21, Bell 103 – 300bps
V.23 – 1200/75bps (w/ turnaround (PAVI))
Bell 202 – 1200bps
Bell 202 and V23 4-wire operations
Dynamic Range: -9dBm to –43 dBm
“AT” command set
Host access to modem port pins via AT
commands for custom I/O expansion
DTMF tone generation and detection
Call progress support with multinational
options (FCC68, CTR21, JATE…)
Caller ID capability
Blacklisting capability
Packaging: 32 pin PLCC or 44 pin TQFP
BLOCK DIAGRAM
ROM
MAC
RAM
CPU
AFE
Hybrid
RxA
TxAP
TxAP
HBDEN
TxCLK
ASRCH
RING
DTR
RI
CTS
DCD
DSR
RTS
RxCLK
TxD
RxD
USR10
USR11
RELAY
August 2001
TDK SEMICONDUCTOR CORP.
®
73M2901/5V
Advanced Single
Chip Modem
2
HARDWARE DESCRIPTION
The 73M2901/5V is designed for a single +5 volt
supply with low power consumption (~250mW @ 5
volts). The modem supports automatic standby idle
mode. The modem will also accept a request to
power down from the DTE via hardware control. No
additional major components are required to
complete the modem core logic. The modem
provides direct firmware LED support via port pins.
HARDWARE FEATURES
Fully self-contained. “AT” Command interpreter
and data pump
User pin available
Synchronous serial data I/O available
Asynchronous serial port
On-chip hybrid driver.
Autobaud capability from 300bps to 9600bps
POWER SUPPLY
Power is supplied to the 73M2901/5V via the VPD and
VPA pins. The 73M2901/5V is designed for a single
+5 (+/-10%) volt supply and for low power consumption
(~250mW @ 5 volts). Ground Reference is provided
at the VND and VNA pins.
LOW POWER MODE
The TDK 73M2901/5V supports a low power mode.
If the low power standby option is enabled the
73M2901/5V will go into a power saving mode when
idle. The oscillator will be running, clocks will be
supplied to the UART, timers and interrupt blocks;
but no clocks will be supplied to the CPU. Instruction
processing and activity on the internal busses is
halted. Normal operation is resumed when an
interruption such as DTR, RING or ASRCH (any
character send to the 73M2901/5V) is requested or
when a reset occurs.
ANALOG LINE / HYBRID INTERFACE
The 73M2901/5V provides a differential analog
output (TXAP and TXAN) and a single-ended analog
input (RXA) with internal A/D and D/A converters. A
driver is provided for an internal hybrid function.
The internal hybrid driver is capable of driving an
external load matching impedance and a line-
coupling transformer. If an external hybrid is to be
used, the on-chip hybrid drivers can be reconfigured
to drive a minimum load of 50k and thus reduce
the driver’s power consumption.
The hybrid configuration is controlled by the state of
the HBDEN pin. For driving a line-coupling
transformer, HBDEN should be pulled high. For
driving an external hybrid (load on TXAP and TXAN
is 50k or larger), HBDEN should be pulled low.
The 73M2901/5V provides firmware control for a
hook relay driver (RELAY) as well as interrupt
support for a ring detect opto-coupler (RING).
INTERRUPT PINS
The external interrupt sources, DTR, ASRCH and RING,
come from dedicated input pins of the same name.
DTR informs the 73M2901/5V that the host has
requested the 73M2901/5V perform a specific
function. The actual particulars of that function can
be changed by “AT” commands (described in full in
the TDK 73M2901 User’s Guide).
ASRCH informs the 73M2901/5V that the host is
passing data to the 73M2901/5V over the DTE
interface. This instructs the 73M2901/5V to begin
looking for valid “AT” commands. This pin needs to
be connected to the TXD pin.
RING informs the 73M2901/5V that the external
DAA circuitry has detected a ring signal.
CRYSTAL OSCILATOR
The TDK 73M2901/5V single chip modem can use
an external 11.0592 MHz reference clock or can
generate such a clock using only a crystal and two
capacitors. If an external clock is used, it should be
applied to OSCIN.
SPECIFYING A CRYSTAL
The manufacturer of a crystal resonator verifies its
frequency of oscillation in a test set-up, but to
ensure that the same frequency is obtained in the
application, the circuit conditions must be the same.
The TDK 73M2901/5V modem requires a parallel
mode (antiresonant) crystal, the important
specifications of which are as follows:
Mode: Parallel (antiresonant)
Frequency: 11.0592 MHz
Frequency tolerance: ±50 ppm at initial
temperature.
Temperature drift: ±50 ppm additional over full
Range.
Load capacitance: 18pF or 20pF
ESR: 75 max.
Drive level: Less than 1mW.
73M2901/5V
Advanced Single
Chip Modem
3
RESET
A reset is accomplished by holding the RESET pin
high. To ensure a proper power-on reset, the reset
pin must be held high for a minimum of 3µs. At
power on, the voltage at VPD, VPA, and RESET
must come up at the same time for a proper reset.
ASYNCHRONOUS AND SYNCHRONOUS SERIAL
DATA INTERFACE
The serial data interface consists of the TXD and
RXD data paths (LSBit shifted in and out first,
respectively); and the TXCLK and RXCLK serial
clock outputs associated with the data pins;
CTS/RTS flow control; DCR, DSR and DTR. In
synchronous mode, the data is passed at the bit rate
(tolerance is +1%, -2.5%).
PIN DESCRIPTIONS
POWER PIN DESCRIPTION
PIN NAME 32-PIN 44-PIN TYPE DESCRIPTION
VPA 15 16 I Positive analog voltage (+ Analog Supply)
VNA 21 22 I Negative analog voltage. (Analog Ground)
VPD 6, 25,
29
2,12,
27, 33
I Positive digital voltage (+ Digital Supply)
VND 5, 22,
26
11, 24,
44, 28
I Negative digital voltage. (Digital Ground)
ANALOG INTERFACE PIN DESCRIPTION
PIN NAME 32-PIN 44-PIN TYPE DESCRIPTION
RXA 20 21 I Receive analog data
TXAN 16 17 O Transmit Analog -
TXAP 17 18 O Transmit Analog +
HBDEN 14 15 I 2w/4w hybrid driver enable pin
0 = Driver configured for 50k or greater load (Tie to VND)
1 = Driver configured for driving line-coupling transformer (Tie to
VPD)
VBG 19 20 O
Analog Band Gap voltage reference pin (0.1µF to VNA)
VREF 18 19 O
Analog reference voltage pin (0.1µF to VNA)
EXTERNAL INTERRUPTS PIN DESCRIPTIONS
PIN NAME 32-PIN 44-PIN TYPE DESCRIPTION
RING
ASRCH
DTR
2
1
32
39
38
37
I
I
I
External interrupt – Line interface ring detection circuitry input
External interrupt – Autobaud detection, connected to TXD
External interrupt – DTE DTR signal input
73M2901/5V
Advanced Single
Chip Modem
4
PIN DESCRIPTIONS (continued)
OSCILLATOR PIN DESCRIPTION
PIN NAME 32-PIN 44-PIN TYPE DESCRIPTION
OSCIN 24 26 I Crystal input for internal oscillator, also input for external
source.
OSCOUT 23 25 O Crystal oscillator output.
DIGITAL INTERFACE PIN DESCRIPTION
PIN NAME 32-PIN 44-PIN TYPE DESCRIPTION
RESET 13 9 I Resets 73M2901/5V
RXCLK 31 36 O Receive Data Synchronous Clock
RXD 30 35 O Serial output to DTE.
TXCLK 28 31 O Transmit Data Synchronous Clock
TXD 27 30 I Serial data input from DTE.
USR10 12 8 I/O This pin can optionally be configured as an active low detect
pin. This can be used to implement such functions as “parallel-
pick-up”, “line-in-use”, or “seize” detect.
USR11 11 7 I/O Programmable I/O port. This pin can ooptionnaly be used to
control an external switch for Caller ID decoding operations.
RTS (USR12) 10 6 I Request to Send
CTS (USR13) 9 5 O Clear to Send
DSR (USR14) 8 4 O Data Set Ready
DCD (USR15) 7 3 O Data Carrier Detect
RI (USR16) 4 43 O Ring Indicator
RELAY (USR17) 3 40 O Relay driver output
73M2901/5V
Advanced Single
Chip Modem
5
ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS
Operation above maximum rating may permanently damage the device.
PARAMETER RATING
Supply Voltage -0.5V to +7.0V
Pin Input Voltage -0.5V to VPD + 0.5V
Storage Temperature -55ºC to 150°C
RECOMMENDED OPERATING CONDITIONS
PARAMETER RATING
Supply Voltage +5.0V (+/-10%)
Oscillator Frequency 11.0592MHz +/- 50ppm
Operating Temperature -40C to +85°C
TRANSMITTER
PARAMETER CONDITIONS MIN NOM MAX UNIT
ITU Guard Tone Power 550Hz (relative to carrier)
1800Hz (relative to carrier)
-5
-8
-3.5
-6.5
-2
-5
dB
dB
Calling Tone 1300Hz -11 -9.0 dBm01
Answer Tone Power 2225/2100Hz -11 -9.0 dBm01
DTMF Transmit Power High band tones
Low band tones
-8.0
-10
-6.0
-8.0
dBm01
1 dBm0 refers to the TDK recommended DAA ( 8dB loss from Transmit pins to the line and 5dB loss from the line to the Receive pin). Results
may vary depending on selected DAA. 0dBm = 0.775Vrms. dBm = 10log {Vrms2/[(1mW)(600)]}
73M2901/5V
Advanced Single
Chip Modem
6
ELECTRICAL SPECIFICATIONS (continued)
MAXIMUM TRANSMIT LEVELS
Vref=2.25V; VPA=5.0V
Transmit type Maximum differential line
level (dBm0)
QAM -5.5
DPSK -3.4
FSK -1.2
DTMF (high tone) -6.0
DTMF (low tone) -8.0
DTMF (total) -3.9
Vref=1.25V; VPA=5.0V
QAM -9.6
DPSK -7.4
FSK -5.3
DTMF (high tone) -7.9
DTMF (low tone) -9.8
DTMF (total) -5.7
Note: The recommended DAA (see the TDK 73M2901 Reference Manual) will result in approximately 8dB loss from the transmit pins to the
phone line. This includes the loss through the line matching impedance (475 resistor), transformer, and solid state off-hook relay.
73M2901/5V
Advanced Single
Chip Modem
7
ELECTRICAL SPECIFICATIONS (continued)
TRANSMITTER
PARAMETER CONDITIONS MIN NOM MAX UNIT
Gain Adjust
Tolerance
By step -0.3 0 0.3 dB
Transmit Gain Boost SFR 96h bit 1 (TXBOOST) = 1 4.8 5.1 5.4 dB
Total Harmonic
Distortion (THD)
1Khz sine wave at output (TXAP-TXAN)
1.5Vpk(2.7dBm) for Vref=1.25V
2.4Vpk (6.8dBm) for Vref=2.25V
THD = 2nd and 3rd harmonic.
-50 dB
each unwanted
frequency
component
-33
dB
Intermod Distortion At output (TXAP-TXAN)
1.0kHz, 1.2 kHz sine waves summed
2.0Vpk for Vref=1.25V
2.4Vpk for Vref=2.25V
Refer to CTR21 specification for complete
description of requirements
sum of
unwanted
frequency
components in
pass band
-20
dB
below
low
tone
Power Supply
Rejection Ratio
-30 dBm signal at VPA
300Hz – 30kHz. Measured TXAP to TXAN.
30.0
dB
RECEIVER
PARAMETER CONDITIONS MIN NOM MAX UNIT
Carrier Detect On Tip and Ring -43.0
dBm01
Carrier Detect Off Tip and Ring -48.0
dBm01
Carrier Detect Hysteresis Tip and Ring 2.0 dB
Receive Level Tip and Ring -43.0 -9.0 dBm01
Idle Channel Noise 0.2kHz - 4.0kHz -70 -65 dB
73M2901/5V
Advanced Single
Chip Modem
8
ELECTRICAL SPECIFICATIONS (continued)
RECEIVER (continued)
PARAMETER TEST CONDITION MIN NOM MAX UNITS
Input Impedance RXA 150 --- --- k
Receive Gain
Boost
SFR 96h bit 2 (Rxgain) = 1 2.7 3.0 3.3 dB
VREF=1.25V 0.587 Vpk Maximum Input
Level at RXA VREF=2.25V 1.069 Vpk
Total Harmonic
Distortion (THD)
1kHz 450mV-pk on RXA
THD = 2nd and 3rd harmonic.
-70 -50 dB
DC CHARACTERISTICS
PARAMETER SYMBOL CONDITION MIN NOM MAX UNIT
Input Low Voltage
(Except OSCIN,RESET)
VIL -0.5 0.2Vcc V
Input Low Voltage
OSCIN,RESET
VIL -0.5 0.2 Vcc V
Input High Voltage
(Except OSCIN,RESET)
VIH 0.5 Vcc Vcc + 0.5 V
Input High Voltage
OSCIN,RESET
VIH 0.7 Vcc Vcc + 0.5 V
Output Low Voltage
(Except OSCOUT)
VOL IOL = 4mA
0.45 V
Output Low Voltage
OSCOUT
VOLOSC IOL = 3.0mA
0.7 V
Output High Voltage
(Except OSCOUT)
VOH IOH = -4mA Vcc – 0.45
V
Output High Voltage
OSCOUT
VOHOSC IOH =-3.0mA Vcc – 0.9
V
Input Leakage Current
(Except OSCIN)
IIH Vss < Vin < Vcc 1 µA
Input Leakage Current
OSCIN
IIH Vss < Vin < Vcc 1 30 µA
73M2901/5V
Advanced Single
Chip Modem
9
ELECTRICAL SPECIFICATIONS (continued)
DC CHARACTERISTICS
PARAMETER SYMBOL CONDITION MIN NOM MAX UNIT
5V Operations
Maximum Power Supply
Normal Operation @ 5V
HBDEN pulled high
IDD1 30pF/pin 51 62 mA
Maximum Power Supply
Normal Operation @ 5V
HBDEN pulled low
IDD1 30pF/pin 35 43 mA
Maximum Digital Power
Supply @ 5V
IDDd 30pF/pin 31 37 mA
Maximum Analog Power
supply @ 5V
HBDEN pulled high
IDDah1 30pF/pin 20 25 mA
Maximum Analog Power
Supply @ 5V
HBDEN pulled low
IDDah0 30pF/pin 4 6 mA
Maximum Power Supply
Idle Mode @ 5V
IDD2 30pF/pin 11 15 mA
Maximum Power Supply
Power Down Mode @ 5V
IDD3 30pF/pin 4 10 µA
73M2901/5V
Advanced Single
Chip Modem
10
DC CHARACTERISTICS
PARAMETER CONDITION MIN NOM MAX UNIT
Vbg Vcc=5V 1.19 1.25 1.31 V
Vref Vcc=5V – no boost 1.19 1.25 1.31 V
Vref Vcc=5V + internal boost 2.14 2.25 2.36 V
5 Volts detection threshold 3.8 4.2 4.5 V
73M2901/5V
Advanced Single
Chip Modem
11
FIRMWARE DESCRIPTION2
An “AT” command interpreter provides command
and configuration of the 73M2901/5V. This provides
the user a uniform interface to control the modem in
embedded applications.
The signal processing is performed by obtaining
data from and providing data to the integrated A/D
converter. A MAC hardware processor is provided
for computation.
To provide maximum flexibility, the system host
processor can access the internal RAM and Control
Register space in the modem. This will allow the
OEM user to modify parameters such as filter
response, transmit levels through the AT command
set using proprietary commands. The host
processor can also access the modem I/O port pins,
providing extended I/O capability.
FIRMWARE REQUIREMENTS
The modem always powers up in the idle (on hook)
mode. “AT” commands are issued via the serial
interface from the host. All modem configuration
commands are received in this manner. The data
modem firmware is contained in an internal ROM.
The firmware will automatically enter a power saving
idle mode if the modem is on hook and there are no
incoming host commands. The modem
automatically powers up upon receiving the next
command. This power up sequence occurs without
delay to the host. This function, while saving power,
is transparent to the host processor and can be
disabled by the host via an “AT” command. The
host can also program the modem to power down
via external pin (DTR) or via a firmware command.
2 For a detailed description of the firmware consult the TDK
73M2901 User’s Manual.
FIRMWARE FEATURES
“AT” command set
Supports data standards through V.22bis
Provides DAA control firmware (e.g. ring detect,
hook control, line in use detection support)
Multinational Call progress support (FCC68,
CTR21, JATE…)
Caller ID capability
FSK demodulation (V23 or Bell202)
Intra 1st/2nd ring CID data operations
Post Line reversal CID data operations
Interfaces with standard V.24/EIA-232 (3-5 volt
inverted level) serial interface using the built in
serial port and firmware control of port pins
Provides tone generation and detection, four
imprecise and four precise call progress detect
filters
Host access to program RAM provided
User access to modem functions
73M2901/5V
Advanced Single
Chip Modem
12
DESIGN CONSIDERATIONS
TDK Semiconductor’s single chip modem solutions
include all the basic modem functions. This makes
these devices adaptable to a variety of applications.
Unlike digital logic circuitry, modem designs must
contend with precise frequency tolerances and verify
low level analog signals, to ensure acceptable
performance. Using good analog circuit design
practices will generally result in a sound design.
The crystal oscillator should be held to a 50ppm
tolerance. Following are additional
recommendations that should be taken into
consideration when starting new designs.
LAYOUT CONSIDERATIONS
Good analog/digital design rules must be used to
control system noise in order to obtain high
performance in modem designs. The more digital
circuitry present in the application, the more
attention to noise control is needed.
High speed, digital devices should be locally
bypassed, and the telephone line interface and the
modem should be located next to each other near
where the telephone line connection is accessed. It
is recommended that power supplies and ground
traces should be routed separately to the analog and
digital portions on the board. Digital signals should
not be routed near low level analog or high
impedance analog traces.
The 73M2901/5V should be considered a high
performance analog device. A 10µF electrolytic
capacitor in parallel with a 0.1µF Ceramic capacitor
should be placed between VPD and VND as well as
between VPA and VNA. A 0.1µF ceramic capacitor
should be placed between VREF and VNA as well
as VBG and VNA. Use of ground planes and large
traces on power is recommended.
The 73M2901/5V is the first of a series of parts with
different and/or additional features. In order to insure
full lay out compatibility for all the series, it is
recommended to implement three additional
resistors in the schematics as shown in the
recommended schematics arrangement (R11, R12
and R13).
TELEPHONE LINE INTERFACE
Transmit levels at the line are dependent on the
interface used between the pins and the line. In
order to save having to provide external op-amps to
drive the line coupling transformer, the analog
outputs (TXAP and TXAN) have the capability to be
used as the hybrid drivers for connecting to the
transformer directly (with the required impedance
matching series resistor). Used in this configuration,
there is loss associated in both the receive path and
transmit path.
The line interface circuit shown on the following
page represents the basic components and values3
for interfacing the TDK 73M2901/5V analog pins to
the telephone line.
MODEM PERFORMANCE
CHARACTERISTICS
The curves presented in this data sheet define
modem IC performance under a variety of line
conditions typical of those encountered over public
service telephone lines.
BER VS. SNR
This test represents the ability of the modem to
operate over noisy lines with a minimum amount of
data transfer errors. Since some noise is generated
in the best dial up lines, the modem must operate
with the lowest signal to noise ratio (SNR) possible.
Better modem performance is indicated by test
curves that are closest to the BER axis. A narrow
spread between curves representing the four line
parameters indicates minimal variation in
performance while operating over a range of
aberrant operating conditions. Typically a DPSK
modem will exhibit better BER performance test
curves receiving in the low band (answer mode)
than in the high band (originate mode).
BER VS. RECEIVE LEVEL
This test measures the dynamic range of the
modem. Because signal levels vary widely over dial
up lines, the widest possible dynamic range is
desirable. The SNR is held constant at the indicated
values as the Receive level is lowered from very a
very high to a very low signal level. The width of the
bowl of these curves, taken at the BER point is the
measure of the dynamic range.
3 TDK73M2901 Demo boards use the line interface shown on the
following page. Other designs may have different requirements
and thus will require different component values or a different
configuration. With the shown configuration, there is
approximately an 8dB loss in the transmit path, and approximately
a 5dB loss in the receive path.
73M2901/5V
Advanced Single
Chip Modem
13
Telephone
Line
T1
5.1K
R4R3
21K
R1
TXAP
RXA
TXAN
475 C1
0.033m
Midcom 671-8005
Recommended Line Interface
R2
21K
PRI
R4
470
R3
5.1K
C4
100nF
GND
JP1
HEADER 10
1
2
3
4
5
6
7
8
9
10
R1
10K
GND
VCC
GND
R13
nc
Y1
11.0592 MHZ
U1
2901_P32
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
ASRCH
RING
RELAY
RI
VND
VPD
DCD
DSR
CTS
RTS
USR11
USR10/LIU
RST
HBDEN
VPA
TXAN
TXAP
VREF
VBG
RXA
VNA
VND
OSCOUT
OSCIN
VPD
VND
TXD
TXC
VPD
RXD
RXC
DTR
VPA
VNA
VCC
VCC
+
C2
10uF
1
2
T1
671-8005
1
4
2
3
To
--> RS232
level shifter
--> Host
microprocessor
VCC
R12
0R
TTL V24
signals
interface
R11
0R
C7
.033UF
SEC
C5
100nF
C1
27PF
C3
33PF
GND
GND
Recommended Schematics Arrangement
73M2901/5V
Advanced Single
Chip Modem
14
TYPICAL USA APPLICATION SCHEMATICS
73M2901/5V
Advanced Single
Chip Modem
15
BER VS SNR BER VS RECEIVE LEVEL
V.22bis
3002A Line, 5.0V, 25C
V.22bis
3002A Line, 5.0V, 25C 1.00E+00
1.00E-01
1.00E-02
1.00E-03
1.00E-04
4
10 11 12 13 14 15 16 17 18 19 8 121620242832364044
1.00E-05
1.00E-06
1.00E+00
1.00E-01
1.00E-02
1.00E-03
1.00E-04
1.00E-05
1.00E-06
Receive Level (dBm)
SN R ( Rx Si g n a l/ 3 k Hz ) ( d B)
Bit Erro r Ra te
Originate
Answer
Bit Error Ra te
Origina te
Answer
73M2901/5V
Advanced Single
Chip Modem
16
32 PIN PLCC PIN-OUT
PIN PIN NAME PIN PIN NAME
1 ASRCH 17 TXAP
2 RING 18 VREF
3 RELAY 19 VBG
4 RI 20 RXA
5 VND 21 VNA
6 VPD 22 VND
7 DCD 23 OSCOUT
8 DSR 24 OSCIN
9 CTS 25 VPD
10 RTS 26 VND
11 USR11 27 TXD
12 USR10 28 TXCLK
13 RESET 29 VPD
14 HBDEN 30 RXD
15 VPA 31 RXCLK
16 TXAN 32 DTR
44 PIN TQFP PIN-OUT
PIN PIN NAME PIN PIN NAME PIN PIN NAME PIN PIN NAME
1 N/C 12 VPD 23 N/C 34 N/C
2 VPD 13 N/C 24 VND 35 RXD
3 DCD 14 N/C 25 OSCOUT 36 RXCLK
4 DSR 15 HBDEN 26 OSCIN 37 DTR
5 CTS 16 VPA 27 VPD 38 ASRCH
6 RTS 17 TXAN 28 VND 39 RING
7 USR11 18 TXAP 29 N/C 40 RELAY
8 USR10 19 VREF 30 TXD 41 N/C
9 RESET 20 VBG 31 TXCLK 42 N/C
10 N/C 21 RXA 32 N/C 43 RI
11 VND 22 VNA 33 VPD 44 VND
73M2901/5V
Advanced Single
Chip Modem
17
MECHANICAL DRAWINGS
PIN NO. 1 IDENT.
0.595 (15.11)
0.585 (14.86)
0.453 (11.51)
0.449 (11.40)
0.553 (14.05)
0.549 (13.94)
0.495 (12.57)
0.485 (12.32)
0.023
0.029
0.045 (1.140)
0.020 (0.508)
0.050
0.013
0.021
0.026
0.032
0.430 (10.92)
0.390 (9.91)
0.530 (13.46)
0.490 (12.45)
0.300 REF
(7.62 REF)
0.400 REF
(10.16 REF)
0.095 (2.41)
0.078 (1.98)
0.140 (3.56)
0.123 (3.12)
32-Pin PLCC
73M2901/5V
Advanced Single
Chip Modem
18
MECHANICAL DRAWINGS (continued)
0.37 (0.0148) Typ.
INDEX
1
12.0 BSC (0.48)
12.0 BSC (0.48)
0.80 (0.032) Typ.
10.0 BSC (0.40)
.05 (0.002)
.15 (0.006)
1.35 (.053)
1.45 (.057)
44-Pin TQFP (JEDEC LQFP)
73M2901/5V
Advanced Single
Chip Modem
19
PACKAGE PIN DESIGNATIONS
(Top View)
1 323130
5
6
7
8
9
10
11
12
13
14 15 16 17 18 19 20 21
22
23
24
25
26
27
28
29
234
RI
RELAY
RING
DTR
RXCLK
RXD
VPD
TXCLK
TXD
VND
VPD
OSCIN
OSCOUT
VND
VNARESET
USR10
USR11
RTS
CTS
DSR
DCD
VPD
VND
Pin 1
Indicator
RXA
VBG
VREF
TXAP USR20
TXAN
VPA
HBDEN
N/C 1
VPD
DCD
DSR
CTS
RTS
USR11
USR10
RESET
N/C
VND
VPD
N/C
N/C
HBDEN
VPA
TXAN
TXAP
VREF
VBG
RXA
VNA
N/C
VND
OSCOUT
OSCIN
VPD
VND
N/C
TXD
TXCLK
N/C
VPD
N/C
RXD
RXCLK
DTR
RING
RELAY
N/C
N/C
RI
VND
USR20
2
3
4
5
6
7
8
9
10
11
12 13 14 15 16 17 18 19 20 21 22
23
24
25
26
27
28
29
30
31
32
33
3435363738394041424344
Pin 1
Indicator
32-Lead PLCC 44-Pin TQFP
73M2901-32IH/5 73M2901-IGT/5
ORDERING INFORMATION
PART DESCRIPTION ORDER NUMBER PACKAGING MARK
73M2901/5V
32-Pin Plastic Leaded Chip Carrier 73M2901-32IH/5 73M2901-32IH
73M2901/5V
44-Pin Thin Quad Flat Pack 73M2901-IGT/5 73M2901-IGT
No responsibility is assumed by TDK Semiconductor Corporation for use of this product nor for any infringements of patents and trademarks
or other rights of third parties resulting from its use. No license is granted under any patents, patent rights or trademarks of
TDK Semiconductor Corporation, and the company reserves the right to make changes in specifications at any time without notice.
Accordingly, the reader is cautioned to verify that the data sheet is current before placing orders.
TDK Semiconductor Corp., 2642 Michelle Dr., Tustin, CA 92780, (714) 508-8800, FAX (714) 508-8877, www.tdksemiconductor.com
TDK Semiconductor Corporation 08/30/01 Rev. D
CAUTION: Use handling procedures necessary for a
static sensitive component.