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73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
April 2000
DESCRIPTION
The 73K222BL is a highly integrated single-chip modem IC which provides the functions needed to construct a CCITT V.22, V.21, Bell 212A and Bell 103, compatible modem, capable of 1200 bit/s fullduplex operation over dial-up lines. The 73K222BL is an enhancement of the 73K222AL single-chip modem which adds the hybrid hook switch control, and driver to the 73K222AL. In Bell 212A mode, the 73K222BL provides the normal Bell 212A and Bell 103 functions and employs a 2225 Hz answer tone. The 73K222BL in V.22 mode produces either 550 or 1800 Hz guard tone, recognizes and generates a 2100 Hz answer tone, and allows 600 bit/s V.22 or 0-300 bit/s V.21 operation. The device integrates analog, digital, and switched-capacitor array functions on a single substrate, offering excellent performance and a high level of functional integration in a 32-Lead PLCC and 44-Lead TQFP package. It operates from a single +5 V supply. The 73K222BL includes the DPSK and FSK modulator/demodulator functions, call progress and handshake tone monitor and a tone generator capable of tones required for European applications. This device supports V.22 (except mode v) and V. 21 modes of operation, allowing both synchronous and asynchronous communication. Test features such as analog loop, digital loop, and remote digital loopback are supported. Internal pattern generators are also included for self-testing. (continued)
FEATURES
* * * * * * * * Includes features of 73K222AL single-chip modem One-chip CCITT V.22, V.21, Bell 212A and Bell 103 standard compatible modem data pump Full-duplex operation at 0-300 bit/s (FSK) or 600 and 1200 bit/s (DPSK) On chip 2-wire/4-wire hybrid driver and offhook relay buffer driver Serial or parallel microcontroller control interface Interfaces directly with standard microcontroller (8048, 80C51 typical) Serial port for data transfer Both synchronous and asynchronous modes of operation including V.22 extended overspeed Call progress, carrier, precise answer tone (2100 or 2225 Hz), and long loop detectors DTMF, and 550 or 1800 Hz guard tone generators Test modes available: ALB, DL, RDL, Mark, Space, Alternating bit patterns Precise automatic gain control allows 45 dB dynamic range CMOS technology for low power consumption using 60 mW @ 5 V Single +5 V supply
* * * * * *
BLOCK DIAGRAM
OH DATA BUS BUFFER DTMF & TONE GENERATORS FSK MODULATOR/ DEMODULATOR
AD0-AD7
8-BIT BUS FOR
RD WR ALE CS RESET
READ WRITE CONTROL LOGIC
CONTROL AND STATUS DIGITAL PROCESSING PSK MODULATOR/ DEMODULATOR
TRANSMIT FILTER RECEIVE FILTER 2W/4W HYBRID
TXA1 TXA2 RXA
INT
STATUS AND CONTROL LOGIC
TXD RXD
SERIAL PORT FOR DATA
TESTS: ALB, DLB RDLB PATTERNS CLOCK GENERATOR
SMART DIALING & DETECT FUNCTIONS
POWER
RXCLK
EXCLK
TXCLK
XTL1
XTL2
GND VREF VDD ISET
CLK
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DESCRIPTION (continued)
The 73K222BL is designed to appear to the systems designer as a microprocessor peripheral, and will easily interface with popular one-chip microprocessors (80C51 typical) for control of modem functions through its 8-bit multiplexed address/data bus. An ALE control line simplifies address demultiplexing. Data communications occurs through a separate serial port only. The 73K222BL is ideal for use in either free standing or integral system modem products where fullduplex 1200 bit/s data communications over the 2wire switched telephone network is desired. Its high functionality, low power consumption and efficient packaging simplify design requirements and increase system reliability. A complete modem requires only the addition of the phone line interface, a control microprocessor, and RS-232 level converter for a typical system. The 73K222BL is part of TDK Semiconductor's K-Series family of single-chip modem products. These devices allow systems to be configured for higher speeds and Bell or CCITT operation with only a single component change.
FUNCTIONAL DESCRIPTION
HYBRID AND RELAY DRIVER To make designs more cost effective and space efficient, the 73K222BL includes the 2-wire to 4-wire hybrid with sufficient drive to interface directly to the telecom coupling transformers. In addition, an off hook relay driver with 40 mA drive capability is also included to allow use of commonly available mechanical telecom relays. ASYNCHRONOUS MODE Data transmission for the DPSK mode requires that data ultimately be transmitted in a synchronous fashion. The 73K222BL includes ASYNC/SYNC and SYNC/ASYNC converters which delete or insert stop bits in order to transmit data within a 0.01% rate. In asynchronous mode the serial data comes from the TXD pin into the ASYNC/SYNC converter. The ASYNC/SYNC converter accepts the data provided on the TXD pin which normally must be 1200 or 600 bit/s +1.0%, -2.5%. The converter will then insert or delete stop bits in order to output a signal which is 1200 or 600 bit/s 0.01% ( 0.01% is required synchronous data rate accuracy). The serial data stream from the ASYNC/SYNC converter is passed through the data scrambler and onto the analog modulator. The data scrambler can be bypassed under processor control when unscrambled data must be transmitted. The ASYNC/SYNC converter and the data scrambler are bypassed in all FSK modes. If serial input data contains a break signal through one character (including start and stop bits) the break will be extended to at least 2 * N + 3 bits long (where N is the number of transmitted bits/character).
2
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
Serial data from the demodulator is passed first through the data descrambler and then through the SYNC/ASYNC converter. The SYNC/ASYNC converter will re-insert any deleted stop bits and transmit output data at an intra-character rate (bit-tobit timing) of no greater than 1219 bit/s. An incoming break signal (low through two characters) will be passed through without incorrectly inserting a stop bit. The SYNC/ASYNC converter also has an extended overspeed mode which allows selection of an overspeed range of either +1% or +2.3%. In the extended overspeed mode, stop bits are output at 7/8 the normal width. SYNCHRONOUS MODE The CCITT V.22 standard defines synchronous operation at 600 and 1200 bit/s. The Bell 212A standard defines synchronous operation only at 1200 bit/s. Operation is similar to that of the asynchronous mode except that data must be synchronized to a provided clock and no variation in data transfer rate is allowable. Serial input data appearing at TXD must be valid on the rising edge of TXCLK. TXCLK is an internally derived signal in internal mode and is connected internally to the RXCLK pin in slave mode. Receive data at the RXD pin is clocked out on the falling edge of RXCLK. The ASYNCH/SYNCH converter is bypassed when synchronous mode is selected and data is transmitted out at the same rate as it is input. DPSK MODULATOR/DEMODULATOR The 73K222BL modulates a serial bit stream into di-bit pairs that are represented by four possible phase shifts as prescribed by the Bell 212A or V.22 standards. The baseband signal is then filtered to reduce intersymbol interference on the bandlimited 2-wire telephone line. Transmission occurs using either a 1200 Hz (originate mode) or 2400 Hz carrier (answer mode). Demodulation is the reverse of the modulation process, with the incoming analog signal eventually decoded into di-bits and converted back to a serial bit stream. The demodulator also recovers the clock which was encoded into the analog signal during modulation. Demodulation occurs using either a 1200 Hz carrier (answer mode or ALB originate mode) or a 2400 Hz carrier (originate mode or ALB answer mode). The device uses a phase locked loop coherent demodulation technique for optimum receiver performance. FSK MODULATOR/DEMODULATOR The FSK modulator produces a frequency modulated analog output signal using two discrete frequencies to represent the binary data. In Bell 103, the standard frequencies of 1270 and 1070 Hz (originate, mark and space) or 2225 and 2025 Hz (answer, mark and space) are used. V.21 mode uses 980 and 1180 Hz (originate, mark and space), or 1650 and 1850Hz (answer, mark and space). Demodulation involves detecting the received frequencies and decoding them into the appropriate binary value. The rate converter and scrambler/descrambler are bypassed in the Bell 103 or V.21 modes. PASSBAND FILTERS AND EQUALIZERS High and low band filters are included to shape the amplitude and phase response of the transmit and receive signals and provide compromise delay equalization and rejection of out-of-band signals in the receive channel. Amplitude and phase equalization are necessary to compensate for distortion of the transmission line and to reduce intersymbol interference in the bandlimited receive signal. The transmit signal filtering approximates a 75% square root of raised Cosine frequency response characteristic. AGC The automatic gain control maintains a signal level at the input to the demodulators which is constant to within 1 dB. It corrects quickly for increases in signal which would cause clipping and provides a total receiver dynamic range of > 45 dB.
(continued)
3
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
FUNCTIONAL DESCRIPTION (continued)
PARALLEL BUS INTERFACE Four 8-bit registers are provided for control, option select and status monitoring. These registers are addressed with the AD0, AD1, and AD2 multiplexed address lines (latched by ALE) and appear to a control microprocessor as four consecutive memory locations. Two control registers and the tone register are read/write memory. The detect register is read only and cannot be modified except by modem response to monitored parameters. SPECIAL DETECT CIRCUITRY The special detect circuitry monitors the received analog signal to determine status or presence of carrier, call-progress tones, answer tone and weak received signal (long loop condition). An unscrambled mark request signal is also detected when the received data out of the DPSK demodulator before the descrambler has been high for 165.5 ms 6.5 ms minimum. The appropriate detect register bit is set when one of these conditions changes and an interrupt is generated for all purposes except long loop. The interrupts are disabled (masked) when the enable interrupt bit is set to 0. DTMF GENERATOR The DTMF generator will output one of 16 standard tone pairs determined by a 4-bit binary value and TX DTMF mode bit previously loaded into the tone register. Tone generation is initiated when the DTMF mode is selected using the tone register and the transmit enable (CR0 bit D1) is changed from 0 to 1.
4
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
PIN DESCRIPTION
POWER NAME GND VDD VREF ISET PIN 1 16 31 28 TYPE I I O I DESCRIPTION System Ground Power supply input, 5 V 10%. Bypass with 0.1 and 22 F capacitors to GND. An internally generated reference voltage. Bypass with 0.1 F capacitor to ground. Chip current reference. Sets bias current for op-amps. The chip current is set by connecting this pin to VDD through a 2 M resistor. ISET should be bypassed to GND with a 0.1 F capacitor.
PARALLEL CONTROL INTERFACE ALE AD0-AD7
CS
13 5-12 23
I I/O Tristate I
Address latch enable. The falling edge of ALE latches the address on AD0-AD2 and the chip select on CS. Address/data bus. These bi-directional tri-state multiplexed lines carry information to and from the internal registers. Chip select. A low on this pin during the falling edge of ALE allows a read cycle or a write cycle to occur. AD0-AD7 will not be driven and no registers will be written if CS (latched) is not active. The state of CS is latched on the falling edge of ALE. Output clock. This pin is selectable under processor control to be either the crystal frequency (for use as a processor clock) or 16 times the data rate for use as a baud rate clock in DPSK modes only. The pin defaults to the crystal frequency on reset. Interrupt. This open drain output signal is used to inform the processor that a detect flag has occurred. The processor must then read the detect register to determine which detect triggered the interrupt. INT will stay low until the processor reads the detect register or does a full reset. Read. A low requests a read of the 73K222BL internal registers. Data cannot be output unless both RD and the latched CS are active or low. Reset. An active high signal on this pin will put the chip into an inactive state. All control register bits (CR0, CR1, Tone) will be reset. The output of the CLK pin will be set to the crystal frequency. An internal pull-down resistor permits power-on-reset using a capacitor to VDD.
CLK
2
O
INT
20
O
RD
15 30
I
I/with Pulldown
RESET
5
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
PARALLEL CONTROL INTERFACE (continued) NAME
WR
PIN 14
TYPE I
DESCRIPTION Write. A low on this pin informs the 73K222BL that data is available on AD0-AD7 for writing into an internal register. Data is latched on the rising edge of WR. No data is written unless both WR and the latched CS are low.
SERIAL CONTROL INTERFACE NAME AD0-AD2 DATA (AD7) PIN 5-7 12 TYPE I I/O DESCRIPTION Register Address Selection. These lines carry register addresses and should be valid during any read or write operation. Serial Control Data. Data for a read/write operation is clocked in or out on the falling edge of the EXCLK pin. The direction of data flow is controlled by the RD pin. RD low outputs data. RD high inputs data. Read. A low on this input informs the 73K222BL that data or status information is being read by the processor. The falling edge of the RD signal will initiate a read from the addressed register. The RD signal must continue fort eight falling edges of EXCLK in order to read all eight bits of the referenced register. Read data is provided LSB first. Data will not be output unless the RD signal is active. Write. A low on this input informs the 73K222BL that data or status information has been shifted in through the DATA pin and is available for writing to an internal register. The normal procedure for a write is to shift in data LSB first on the DATA pin for eight consecutive falling edges of EXCLK and then to pulse WR low. Data is written on the rising edge of WR.
RD
15
I
WR
14
I
NOTE: The serial control mode is provided by tying ALE high and CS low. In this configuration AD7 becomes DATA and AD0, AD1 and AD2 become the address only.
6
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DTE USER NAME EXCLK PIN 22 TYPE I DESCRIPTION External Clock. This signal is used in synchronous transmission when the external timing option has been selected. In the external timing mode the rising edge of EXCLK is used to strobe synchronous DPSK transmit data applied to on the TXD pin. Also used for serial control interface. Receive Clock. The falling edge of this clock output is coincident with the transitions in the serial received data output. The rising edge of RXCLK can be used to latch the valid output data. RXCLK will be valid as long as a carrier is present. Received Data Output. Serial receive data is available on this pin. The data is always valid on the rising edge of RXCLK when in synchronous mode. RXD will output constant marks if no carrier is detected. Transmit Clock. This signal is used in synchronous transmission to latch serial input data on the TXD pin. Data must be provided so that valid data is available on the rising edge of the TXCLK. The transmit clock is derived from different sources depending upon the synchronization mode selection. In internal mode the clock is generated internally. In external mode TXCLK is phase locked to the EXCLK pin. In slave mode TXCLK is phase locked to the RXCLK pin. TXCLK is always active. Transmit Data Input. Serial data for transmission is applied on this pin. In synchronous modes, the data must be valid on the rising edge of the TXCLK clock. In asynchronous modes (1200/600 bit/s or 300 baud) no clocking is necessary. DPSK data must be 1200/600 bit/s +1%, -2.5% or +2.3%, -2.5 % in extended over speed mode.
RXCLK
26
O
RXD
25
O/ Weak Pull-up O
TXCLK
21
TXD
24
I
ANALOG INTERFACE AND OSCILLATOR NAME RXA TXA1 TXA2 XTL1 XTL2 PIN 32 18 17 3 4 TYPE I O I I DESCRIPTION Received modulated analog signal input from the telephone line interface. Transmit analog output to the telephone line interface. These pins are for the internal crystal oscillator requiring a 11.0592 MHz parallel mode crystal. Load capacitors should be connected from XTL1 and XTL2 to ground. XTL2 can also be driven from an external clock. Off-hook relay driver. This signal is an open drain output capable of sinking 40 mA and is used for controlling a relay. The output is the complement of the OH register bit in the ID Register.
OH
27
O
7
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
REGISTER DESCRIPTIONS
Four 8-bit internal registers are accessible for control and status monitoring. The registers are accessed in read or write operations by addressing AD0, AD1 and AD2 lines. The address lines are latched by ALE. Register CR0 controls the method by which data is transferred over the phone line. CR1 controls the interface between the microprocessor and the 73K222BL internal state. REGISTER BIT SUMMARY
ADDRESS REGISTER AD2 - AD0 D7 D6 D5 DATA BIT NUMBER D4 D3 D2 D1 D0
DR is the Detect Register which provides an indication of monitored modem status conditions. TR, the Tone Control Register, controls the DTMF generator, answer and guard tones and RXD output gate used in the modem initial connect sequence. All registers are read/write except for DR which is read only. Register control and status bits are identified below:
CONTROL REGISTER 0
CR0
000
MODULATION OPTION
0
TRANSMIT MODE 3
TRANSMIT MODE 2
TRANSMIT MODE 1
TRANSMIT MODE 0
TRANSMIT ENABLE
ORIGINATE/ ANSWER
0 = 1200 BIT/S DPSK 1 = 600 BIT/S DPSK 0 = BELL 103 FSK 1 = V.21 FSK
0000 = PWR DOWN 0001 = INT SYNCH 0010 = EXT SYNCH 0011 = SLAVE SYNCH 0100 = ASYNCH 8 BITS/CHAR 0101 = ASYNCH 9 BITS/CHAR 0110 = ASYNCH 10 BITS/CHAR 0111 = ASYNCH 11 BITS/CHAR 1100 = FSK ENABLE DETECT INTERRUPT BYPASS SCRAMBLER CLK CONTROL
0 = ANSWER 0 = DISABLE TXA OUTPUT 1 = ORIGINATE 1 = ENABLE TXA OUTPUT
CONTROL REGISTER 1
CR1
001
TRANSMIT PATTERN 1
TRANSMIT PATTERN 0
RESET
TEST MODE 1
TEST MODE 0
00 = TX DATA 01 = TX ALTERNATE 10 = TX MARK 11 = TX SPACE
0 = DISABLE 1 = ENABLE
0 = NORMAL 1 = BYPASS SCRAMBLER
0 = XTAL 1 = 16 X DATA RATE OUTPUT AT CLK PIN IN DPSK MODE ONLY CARRIER DETECT
0 = NORMAL 1 = RESET
00 = NORMAL 01 = ANALOG LOOPBACK 10 = REMOTE DIGITAL LOOPBACK 11 = LOCAL DIGITAL LOOPBACK CALL PROGRESS LONG LOOP
DETECT REGISTER
DR
010
X
X
RECEIVE DATA
UNSCR. MARKS
ANSWER TONE
OUTPUTS RECEIVED DATA STREAM TONE CONTROL REGISTER RXD OUTPUT CONTROL TRANSMIT GUARD/ TONE TRANSMIT ANSWER TONE 0 = OFF 1 = ON
0 = CONDITION NOT DETECTED 1 = CONDITION DETECTED
TR
011
TRANSMIT DTMF
DTMF3
DTMF2
DTMF1/ OVERSPEED
DTMF0/ GUARD/ ANSWER/ TONE 0 = 2225 Hz A.T. 1800 Hz G.T. 1 = 2100 Hz A.T. 500 Hz G.T.
RXD PIN 0 = OFF 0 = NORMAL 1 = ON 1 = WEAK PULL-UP
0 = Disable DTMF 1 = TX DTMF
4 BIT CODE FOR 1 OF 16 DUAL TONE COMBINATIONS
ID REGISTER
10
110
1
0
X
OH
X
X
X
X
00XX = 73K212AL, 322L, 321L 01XX = 73K221AL, 302L 10XX = 73K222AL, 222BL 1100 = 73K224L, 224BL 1110 = 73K324L, 324BL
X = Undefined, mask in software
0 = OH Relay driver open 1 = OH Open drain driver pulling low
NOTE:
When a register containing reserved control bits is written into, the reserved bits must be programmed as 0's. X = Undefined, mask in software 8
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
CONTROL REGISTER 0
CR0 000 D7 MODUL. OPTION D6 0 D5 TRANSMIT MODE 3 D4 TRANSMIT MODE 2 D3 TRANSMIT MODE 1 D2 TRANSMIT MODE 0 D1 TRANSMIT ENABLE D0 ANSWER/ ORIGINATE
BIT NO. D0
NAME Answer/ Originate
CONDITION 0 1
DESCRIPTION Selects answer mode (transmit in high band, receive in low band). Selects originate mode (transmit in low band, receive in high band). Disables transmit output at TXA. Enables transmit output at TXA. Note: TX Enable must be set to 1 to allow Answer Tone and DTMF Transmission as well as data carriers.
D1
Transmit Enable
0 1
D5, D4, D3, D2
Transmit Mode
D5 D4 0 0 0 0
D3 D2 0 0 0 1
Selects power-down mode. All functions disabled except digital interface. Internal synchronous mode. In this mode TXCLK is an internally derived 1200 Hz signal. Serial input data appearing at TXD must be valid on the rising edge of TXCLK. Receive data is clocked out of RXD on the falling edge of RXCLK. External synchronous mode. Operation is identical to internal synchronous, but TXCLK is connected internally to EXCLK pin, and a 1200 Hz 0.01% clock must be supplied externally. Slave synchronous mode. Same operation as other synchronous modes. TXCLK is connected internally to the RXCLK pin in this mode. Selects PSK asynchronous mode - 8 bits/character (1 start bit, 6 data bits, 1 stop bit). Selects PSK asynchronous mode - 9 bits/character (1 start bit, 7 data bits, 1 stop bit). Selects PSK asynchronous mode - 10 bits/character (1 start bit, 8 data bits, 1 stop bit). Selects PSK asynchronous mode - 11 bits/character (1 start bit, 8 data bits, Parity and 1 or 2 stop bits). Selects FSK operation. Not used; must be written as a "0."
0
0
1
0
0
0
1
1
0 0 0 0 1 D6
1 1 1 1 1 0
0 0 1 1 0
0 1 0 1 0
9
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
CONTROL REGISTER 0 (continued)
CR0 000 D7 MODUL. OPTION D6 0 D5 TRANSMIT MODE 3 D4 TRANSMIT MODE 2 D3 TRANSMIT MODE 1 D2 TRANSMIT MODE 0 D1 TRANSMIT ENABLE D0 ANSWER/ ORIGINATE
BIT NO.
NAME
CONDITION D7 D5 0 0 1 1 D4 X X 1 1
DESCRIPTION Selects: DPSK mode at 1200 bit/s. DPSK mode at 600 bit/s. FSK Bell 103 mode. FSK CCITT V.21 mode. X = Don't care
D7
Modulation Option
0 1 0 1
CONTROL REGISTER 1 D7 CR1 001 TRANSMIT PATTERN 1 D6 TRANSMIT PATTERN 0 NAME Test Mode D5 ENABLE DETECT INTER. CONDITION D1 0 0 D0 0 1 Analog loopback mode. Loops the transmitted analog signal back to the receiver, and causes the receiver to use the same center frequency as the transmitter. To squelch the TXA pin, transmit enable must be forced low. Selects remote digital loopback. Received data is looped back to transmit data internally, and RXD is forced to a mark. Data on TXD is ignored. Selects local digital loopback. Internally loops TXD back to RXD and continues to transmit carrier from TXA pin. Selects normal operation. Resets modem to power-down state. All control register bits (CR0, CR1, TONE) are reset to zero. The output of the CLK pin will be set to the crystal frequency. This bit clears itself. Selects 11.0592 MHz crystal echo output at CLK pin. Selects 16 times the data rate, output at CLK pin in DPSK modes only. D4 BYPASS SCRAMB D3 CLK CONTROL D2 RESET D1 TEST MODE 1 D0 TEST MODE 0
BIT NO. D1, D0
DESCRIPTION Selects normal operating mode
1
0
1
1
D2
Reset
0 1
D3
CLK Control (Clock Control)
0 1
10
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
CONTROL REGISTER 1 (continued) D7 CR1 001 TRANSMIT PATTERN 1 D6 TRANSMIT PATTERN 0 NAME Bypass Scrambler Enable Detect D5 ENABLE DETECT INTER. CONDITION 0 1 0 1 D4 BYPASS SCRAMB. D3 CLK CONTROL D2 RESET D1 TEST MODE 1 D0 TEST MODE 0
BIT NO. D4 D5
DESCRIPTION Selects normal operation. DPSK data is passed through scrambler. Selects Scrambler Bypass. Bypass DPSK data is routed around scrambler in the transmit path. Disables interrupt at INT pin. Enables INT output. An interrupts will be generated with a change in status of DR bits D1-D4. The answer tone and call progress detect interrupts are masked when the TX enable bit is set. Carrier detect is masked when TX DTMF is activated. All interrupts will be disabled if the device is in power-down mode.
D7, D6
Transmit Pattern
D7 0 0 1 1
D6 0 1 0 1
Selects normal data transmission as controlled by the state of the TXD pin. Selects an alternating mark/space transmit pattern for modem testing. Selects a constant mark transmit pattern. Selects a constant space transmit pattern.
DETECT REGISTER DR 010 BIT NO. D0 D1 D7 X D6 X D5 RECEIVE DATA D4 UNSCR. MARK D3 CARR. DETECT DESCRIPTION Indicates normal received signal. Indicates low received signal level. No call progress tone detected. Indicates presence of call progress tones. The call progress detection circuitry is activated by energy in the 350 to 620 Hz call progress band. D2 ANSWER TONE D1 CALL PROG. D0 LONG LOOP
NAME Long Loop Call Progress Detect
CONDITION 0 1 0 1
11
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DETECT REGISTER (continued) DR 010 BIT NO. D2 D7 X D6 X NAME Answer Tone Detect D5 RECEIVE DATA 0 1 D4 UNSCR. MARK D3 CARR. DETECT DESCRIPTION No answer tone detected. Indicates detection of 2225 Hz answer tone in Bell modes or 2100 Hz in CCITT modes. The device must be in originate mode for detection of answer tone. For CCITT answer tone detection, bit D0 of the Tone Register must be set to a 1. No carrier detected in the receive channel. Indicates carrier has been detected in the receive channel. No unscrambled mark. Indicates detection of unscrambled marks in the received data. A valid indication requires that unscrambled marks be received for > 165.5 6.5 ms. Continuously outputs the received data stream. This data is the same as that output on the RXD pin, but it is not disabled when RXD is tri-stated. Undefined Not used. Mask in software. D2 ANSWER TONE D1 CALL PROG. D0 LONG LOOP
CONDITION
D3
Carrier Detect
0 1
D4
Unscrambled Mark Detect
0 1
D5
ReceiveData
D6, D7 TONE REGISTER D7 TR 011 BIT NO. D0
Not Used
D6 TRANSMIT GUARD TONE
D5 TRANSMIT ANSWER TONE CONDITION D6 D5 D4 D0 X X X X X 1 1 X 0 1 0 1 0 0 0 0 1 0 0 0 0 0 0 0 1 X 0 0 1 1 0 1
D4 TRANSMIT DTMF
D3 DTMF 3
D2 DTMF 2
D1 DTMF 1/ OVERSPEED
D0 DTMF 0/ ANSWER/ GUARD
RXD OUTPUT CONTR.
NAME DTMF 0/ Answer/ Guard Tone
DESCRIPTION D0 interacts with bits D6, D5, and D4 as shown. Transmit DTMF tones. Detects 2225 Hz in originate mode. Transmits 2225 Hz in answer mode (Bell). Detects 2100 Hz in originate mode. Transmits 2100 Hz in answer mode (CCITT). Select 1800 Hz guard tone. Select 550 Hz guard tone. D1 interacts with D4 as shown. Asynchronous DPSK +1.0% -2.5%. Asynchronous DPSK +2.3% -2.5%.
D1
DTMF 1/ Overspeed
D4 D1
12
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
TONE REGISTER (continued) D7 TR 011 BIT NO. D3, D2, D1, D0 RXD OUTPUT CONTR. D6 TRANSMIT GUARD TONE D5 TRANSMIT ANSWER TONE CONDITION D4 TRANSMIT DTMF D3 DTMF 3 D2 DTMF 2 D1 DTMF 1/ OVERSPEED D0 DTMF 0/ ANSWER/ GUARD
NAME DTMF 3, 2, 1, 0
DESCRIPTION Programs 1 of 16 DTMF tone pairs that will be transmitted when TX DTMF (TONE, Bit D4) and TX ENABLE bit (CR0, Bit D1) are set. Tone encoding is shown below: KEYBOARD TONES EQUIVALENT LOW HIGH 1 2 3 4 5 6 7 8 9 0 * # A B C D Disable DTMF. Activates DTMF. The selected DTMF tones are transmitted continuously when this bit is high and TX ENABLE (CR0, Bit 1) is set to one. TX DTMF overrides all other transmit functions. 697 697 697 770 770 770 852 852 852 941 941 941 697 770 852 941 1209 1336 1477 1209 1336 1477 1209 1336 1477 1336 1209 1477 1633 1633 1633 1633
DTMF CODE D3 D2 D1 D0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 D4
Transmit DTMF
0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 1
0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0
1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0
D5
Transmit Answer Tone
D5 0 1
D4 0 0
D0 X 0
D5 interacts with bits D4 and D0 as shown. Disables answer tone generator. Enables answer tone generator. A 2225 Hz answer tone will be transmitted continuously when the TRANSMIT ENABLE bit is set in CR0. The device must be in answer mode. Likewise a 2100 Hz answer tone will be transmitted.
1
0
1
13
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
TONE REGISTER (continued) D7 TR 011 BIT NO. D6 RXD OUTPUT CONTR. D6 TRANSMIT GUARD TONE D5 TRANSMIT ANSWER TONE CONDITION 0 1 0 1 ID REGISTER ID 110 BIT NO. D7, D6 D5, D4 D7 1 NAME DEVICE ID 0 0 1 1 1 1 1 D4 D5, D3-D1 OH Not Used D6 0 D5 X CONDITION D7 D6 D5 D4 0 1 0 1 1 1 1 0 1 NA X X X 0 1 0 1 X X X 0 0 0 0 D4 OH D3 X D2 X D1 X D0 X D4 TRANSMIT DTMF D3 DTMF 3 D2 DTMF 2 D1 DTMF 1/ OVERSPEED D0 DTMF 0/ ANSWER/ GUARD
NAME Transmit Guard Tone RXD Output Control
DESCRIPTION Disables guard tone generator. Enables guard tone generator (See D0 for selection of guard tones). Enables RXD pin. Receive data will be output on RXD. Disables RXD pin. The RXD pin reverts to a high impedance with internal weak pull-up resistor.
D7
DESCRIPTION Indicates device type. 73K212AL, 73K321L or 73K322L 73K221AL or 73K302L 73K222AL, 73K222BL 73K224AL 73K324L 73K224BL 73K324BL Relay driver open Open drain driver pulling low. Mask in firmware.
14
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS PARAMETER VDD Supply Voltage Storage Temperature Reflow Soldering Temperature (10 sec.)/VPS (10 sec.) Applied Voltage RATING 7V -65 to 150 C 235 C/215 C -0.3 to VDD + 0.3 V
NOTE: All inputs and outputs are protected from static charge using built-in, industry standard protection devices and all outputs are short-circuit protected. RECOMMENDED OPERATING CONDITIONS PARAMETER VDD Supply Voltage TA, Operating Free-Air Temperature Clock Variation (11.0592 MHz) Crystal or external clock External to GND Placed between VDD and ISET pins ISET pin to GND External to GND External to GND Depends on crystal characteristics from pin to GND Depends on crystal characteristics from pin to GND See Figure 1 TXA Hybrid Loading -0.01 +0.01 % CONDITION MIN 4.5 -40 NOM 5 MAX 5.5 +85 UNIT V C
External Components (Refer to Application section for placement.) VREF Bypass Capacitor Bias Setting Resistor ISET Bypass Capacitor VDD Bypass Capacitor 1 VDD Bypass Capacitor 2 XTL1 Load Capacitor XTL2 Load Capacitor Hybrid Loading R1 C 0.1 1.8 0.1 0.1 22 Note 1 40 40 600 600 0.033 F 2 2.2 F M F F F pF
NOTE:Minimum for optimized system layout; may require higher values for noisy environments.
15
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DC ELECTRICAL CHARACTERISTICS (TA = -40 C to 85 C, VDD = recommended range unless otherwise noted.) PARAMETER IDD, SUPPLY CURRENT IDDA, Active IDD1, Power-down IDD2, Power-down DIGITAL INPUTS VIH, Input High Voltage Reset, XTL1, XTL2 All other inputs VIL, Input Low Voltage IIH, Input High Current IIL, Input Low Current Reset Pull-down Current Input Capacitance DIGITAL OUTPUTS VOH, Output High Voltage VOL, Output Low Voltage VOL, CLK Output RXD Tri-State Pull-up Current CMAX, CLK Output
OH Output VOL OH Output VOL
CONDITION ISET Resistor = 2 M CLK = 11.0592 MHz CLK = 11.0592 MHz CLK = 19.200 kHz
MIN
NOM 8
MAX 12 4 3
UNIT mA mA mA
3.0 2.0 0 VI = VIH Max VI = VIL Min Reset = VDD All Digital Input Pins IOH MIN = -0.4 mA IO MAX = 1.6 mA IO = 3.6 mA RXD = GND Maximum Capacitive Load IOUT = 40 mA IOUT = 10 mA 1.0 0.5 -1 2.4 -200 1
VDD VDD 0.8 100 50 10 VDD 0.4 0.6 -50 15
V V V A A A pF V V V A pF V V
16
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
ELECTRICAL SPECIFICATIONS (continued)
DYNAMIC CHARACTERISTICS AND TIMING (TA = -40C to +85C, VDD = recommended range unless otherwise noted.) PARAMETER DPSK MODULATOR Carrier Suppression Output Amplitude FSK MODULATOR/DEMODULATOR Output Frequency Error Transmit Level Harmonic Distortion in 700-2900 Hz band Output Bias Distortion Total Output Jitter DTMF GENERATOR Frequency Accuracy Output Amplitude Output Amplitude Twist Long Loop Detect Dynamic Range CALL PROGRESS DETECTOR Detect Level Range Reject Level Delay Time Hold Time Hysteresis
TXA1
CONDITION FIGURE 1 Measured between TXA1 and TXA2 TX scrambled marks FIGURE 1 CLK = 11.0592 MHz Transmit Dotting Pattern THD in the alternate band DPSK or FSK Transmit Dotting Pattern in ALB @ RXD Random Input in ALB @ RXD FIGURE 1 Low Tone , DPSK Mode High Tone , DPSK Mode High-Tone to Low-Tone, DPSK Mode DPSK or FSK Refer to Performance Curves 2-Tones in 350 - 600 Hz band 2-Tones in 350 - 600 Hz band -70 dBm0 to -30 dBm0 STEP -30 dBm0 to -70 dBm0 STEP
MIN 55 -11.5 -0.35 -11.5
NOM
MAX
UNIT dB
-10.0
-9 +0.35 -9 -50
dBm0 % dBm0 DB %
-10.0 -60 8
-15 -0.25 -10 -8 1.0 -38 45 -38 -43 27 27 2
+15 +0.25 -8 -6 3.0 -28
% % dBm0 dBm0 dB dBm0 dB dBm0 dBm0 ms ms dB
-9 -7 2.0
-3 80 80
R1 600 RXA MIDCOM 671-8001
C 0.033 f TXA2 1:1 600
R2 600
NOTE: Parameters expressed in dBm0 refer to signals at the telephone line, i.e., across R2 in Figure 1. All units in dBm0 are measured at the line input to the transformer. The interface circuit (Figure 1) inserts an 8 dB loss in the transmit path (TXA1 - TXA2 to line), and a 3 dB loss in the receive path (line to RXA).
(NOMINAL TELEPHONE LINE IMPEDANCE)
FIGURE 1: Analog Interface Hybrid Loading
17
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DYNAMIC CHARACTERISTICS AND TIMING (continued) PARAMETER CARRIER DETECT Threshold Delay Time Hysteresis Hold Time ANSWER TONE DETECTOR Detect Level Delay Time Hold Time Detect Frequency Range OUTPUT SMOOTHING FILTER Output Spurious Frequency Components Clock Noise CARRIER VCO Capture Range Capture Time RECOVERED CLOCK Capture Range % of frequency center frequency (center at 1200 Hz) Analog data in at RXA pin to receive data valid at RXD pin -625 +625 ppm Originate or Answer -10 Hz to +10 Hz Carrier Frequency Change Assumption -10 40 +10 100 Hz ms TXA1 to TXA2, loaded as shown in Figure 1 (2% THD) Frequency = 76.8 kHz Frequency = 153.6 kHz TXA pin; 76.8 kHz 2.5 -39 -45 1.0 V dBm0 dBm0 mVrms Not in V.21 mode -70 dBm0 to -30 dBm0 STEP -30 dBm0 to -70 dBm0 STEP -48 20 10 -2.5 -42 45 30 +2.5 dBm0 ms ms % CONDITION DPSK or FSK Receive data -70 dBm0 to -30 dBm0 STEP Single tone detected -30 dBm0 to -70 dBm0 STEP -48 15 2 10 3.0 24 -43 45 dBm0 ms dB ms MIN NOM MAX UNIT
Data Delay Time
30
50
ms
18
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
DYNAMIC CHARACTERISTICS AND TIMING (continued) PARAMETER GUARD TONE GENERATOR Tone Accuracy Tone Level (Below DPSK Output) Harmonic Distortion 700 to 2900 Hz TIMING (Refer to Timing Diagrams) TAL TLA TLC TCL TRD TLL TRDF TRW TWW TDW TWD TCKD TCKW (serial mode) TDCK (serial mode) TAC (serial mode) TCA (serial mode) TWH (serial mode)
CS CS/Address setup before ALE Low CS hold after ALE low
CONDITION 550 Hz 1800 Hz 550 Hz 1800 Hz 550 Hz 1800 Hz
MIN
NOM
MAX
UNIT
-20 -4.0 -7.0 -3.0 -6.0
+20 -2.0 -5.0 -50 -60
Hz dB dB dB dB ns ns ns ns ns
12 0 10 10 0 0 15 50 50 50 15 12 200 150 150 50 50 20 70
ADD
Address hold after ALE Low ALE Low to RD/WR Low
RD/WR Control to ALE High
Data out from RD Low ALE width Data float after RD High
RD width WR width
ns ns ns ns ns ns ns ns ns ns ns ns
Data setup before WR High Data hold after WR High Data out after EXCLK Low
WR after EXCLK Low
Data setup before EXCLK Low Address setup before control* Address hold after control* Data Hold after EXCLK
* Control for setup is the falling edge of RD or WR. Control for hold is the falling edge of RD or the rising edge of WR. NOTE: Asserting ALE, CS, and RD or WR concurrently can cause unintentional register accesses. When using non-8031 compatible processors, care must be taken to prevent this from occurring when designing the interface logic.
19
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
TIMING DIAGRAMS
TLL ALE TLC RD WR TLA TAL AD0-AD7 CS ADDRESS READ DATA ADDRESS TRD TRDF TDW WRITE TWD TRW TCL TLC TWW
FIGURE 2: Bus Timing Diagram
EXCLK
RD TAC A0-A2 TCA
ADDRESS TRD TRDF D3 D4 D5 D6 D7
TCKD D1 D2
DATA
D0
FIGURE 3: Read Timing Diagram (Serial Version)
EXCLK
TWW WR TCKW TAC A0-A2 TDCK DATA D0 D1 D2 D3 D4 D5 D6 D7 ADDRESS TCA
TWH
FIGURE 4: Write Timing Diagram (Serial Version) 20
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
APPLICATIONS INFORMATION
GENERAL CONSIDERATIONS Figure 5 shows the basic circuit diagram for a 73K222BL modem integrated circuit designed to be used in conjunction with a control processor, a UART or RS-232 serial data interface, and a DAA phone line interface to function as a typical intelligent modem. The K-Series ICs interface directly with Intel 8048 and 80C51 microprocessors for control and status monitoring purposes. A typical DAA arrangement is shown in Figure 5.This diagram is for reference only and does not represent a production-ready modem design. In most applications the controller will monitor the serial data for commands from the DTE and the received data for break signals from the far end modem. In this way, commands to the modem are sent over the same line as the transmitted data. In other applications the RS-232 interface handshake lines are used for modem control.
(continued)
RING DETECT +5 TX DATA RX DATA 2 M 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 0.1 F GND CLK XTL1 XTL2 AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7 ALE WR RD VDD RXA VREF RESET N/C ISET OH RXCLK RXD TXD CS EXCLK TXCLK INT NC TXA1 TXA2 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 1 F RING DETECTOR
11.0592 MHz
0.1 F 0.1 F
8.2K HOOK RELAY FUSE 1 2 3 4
ADR/DATA BUS CONTROL INTERFACE C ALE C WR C RD + 10 F RXCLK TXCLK EXCLK CHIP SELECT +5
600
+5
0.033 F TYP.
600 1:1
TRANSIENT SUPPRESSOR
RJ-11
FIGURE 5: Typical 73K222BL DAA Circuit
21
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
APPLICATIONS INFORMATION (continued)
DIRECT ACCESS ARRANGEMENT (DAA) The DAA (Direct Access Arrangement) required for the 73K222BL consists of an impedance matching resistor, telecom coupling transformer, and ring detection and fault protection circuitry. The transformer specifications must comply with the impedance of the country in which the modem is being operated. Transformers designed specifically for use with the telephone network should be used. These may present a DC load to the network themselves (a "wet" transformer) or they may require AC coupling with a DC load provided by additional devices (a "dry" transformer). A dry transformer will generally provide higher performance and smaller size than a wet transformer. A wet transformer allows a simpler design, but must not saturate with the worst case DC current passing through it or distortion and poor performance will result. The protection circuitry typically consists of a transient suppression device and current limiter to protect the user and the telephone network from hazardous voltages that can be present under fault conditions. The transient suppressor may be a MOV (metal oxide varistor), Sidactor (Teccor Electronics Inc.), spark gap device , or avalanche diode. Some devices clamp the transient to their specified break down voltage and others go into low impedance crowbar state. The latter require that the fault current to cease before they can return to their inactive state. Current limiting devices can consist of a resistor, Raychem PolySwitch resettable fuse, or slow blow fuse that can withstand the transient tests without permenant damage or replacement. Ring detection circuitry is not required by the FCC, but may be required by the application. The ring detector usually consists of an optoisolator, capacitor, and resistor to present the proper AC load to the network to meet the REN (Ring Equivalency Number) regulations of FCC Part 68. The K-Series Design Manual contains detailed information on the design of a ring detect circuits as well as the other topics concerning the DAA. DESIGN CONSIDERATIONS TDK Semiconductor's 1-chip modem products include all basic modem functions. This makes these devices adaptable for use in a variety of applications, and as easy to control as conventional digital bus peripherals. Unlike digital logic circuitry, modem designs must properly contend with precise frequency tolerances and very low level analog signals, to ensure acceptable performance. Using good analog circuit design practices will generally result in a sound design. Following are additional recommendations which should be taken into consideration when starting new designs. CRYSTAL OSCILLATOR The K-Series crystal oscillator requires a parallel mode (antiresonant) crystal which operates at 11.0592 MHz. It is important that this frequency be maintained to within 0.01% accuracy. In order for a parallel mode crystal to operate correctly and to specification, it must have a capacitor connected to the junction of each of the crystal and internal inverter connections, terminated to ground. The values of these capacitors depend primarily on the crystal's characteristics, and to a lesser degree on the internal inverter circuit. The values used affect the accuracy and start up characteristics of the oscillator. LAYOUT CONSIDERATIONS Good analog/digital design rules must be used to control system noise in order to obtain highest performance in modem designs. The more digital circuitry present on the PC board, the more this attention to noise control is needed. The modem should be treated as a high performance analog device. A 22 F electrolytic capacitor in parallel with a 0.1 F ceramic capacitor between VDD and GND is recommended. Liberal use of ground planes and larger traces on power and ground are also highly favored. High speed digital circuits tend to generate a significant amount of EMI (Electro-Magnetic Interference) which must be minimized in order to meet regulatory agency limitations. To accomplish this, high speed digital devices should be locally bypassed, and the telephone line interface and K-Series device should be located close to each other near the area of the board where the phone line connection is accessed.
22
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
To avoid problems, power supply and ground traces should be routed separately to the analog and digital functions on the board, and digital signals should not be routed near low level or high impedance analog traces. The analog and digital grounds should only connect at one point near the K-Series device ground pin to avoid ground loops. The K-Series modem ICs should have both high frequency and low frequency bypassing as close to the package as possible. USING THE SERIAL MODE ON THE 73K2XXAL AND 73K222BL A sensitivity to specific patterns being written to the control registers in the 73K212/221/222AL and 73K222BL modem data pumps has been seen on some parts when used in the serial control interface mode. An alternating pattern followed by its complement can cause the registers to not have the intended data correctly written to the registers. Specifically, if an alternating ..1010.. pattern is followed by its compliment, ..0101.., the register may instead be programmed with a ..0001.. pattern. After analysis, it has been found that any normal programming sequence should not include these steps with one exception, and that is in DTMF dialing. Since any random DTMF sequence could be dialed, there is the potential for these patterns to appear. For example, if a DTMF digit "5" , 0101 bin is followed by a DTMF digit "0" , 1010 bin, some parts will instead transmit a DTMF digit "8", 1000 bin, in its place. The solution to this problem is to always clear the DTMF bits, D3-D0, between dialed digits. This will not add additional time to dialing since there is ample time between digits when the DTMF bits can be cleared. Previously during the DTMF off time the next digit would be loaded into the TONE register. It is now recommended to first clear bits D3D0, then the next digit to be dialed is loaded into the DTMF bits. As mentioned earlier, under normal circumstances these patterns would not be programmed for other registers. If for some reason other registers are programmed in such a way that an alternating pattern is followed by its compliment, those bits should be cleared before the complimentary pattern is sent. This method has been tested over the entire voltage and temperature operating ranges. It has been found to be a reliable procedure to ensure the correct patterns are always programmed.
MODEM PERFORMANCE CHARACTERISTICS
The curves presented here define modem IC performance under a variety of line conditions while inducing disturbances that are typical of those encountered during data transmission on public service telephone lines. Test data was taken using an AEA Electronics' "Autotest I" modem test set and line simulator, operating under computer control. All tests were run full-duplex, using a Concord Data Systems 224 as the reference modem. A 511 pseudo-random-bit pattern was used for each data point. Noise was C-message weighted and all signal-to-noise (S/N) ratios reflect total power measurements similar to the CCITT V.56 measurement specification. The individual tests are defined as follows. BER VS. S/N This test measures the ability of the modem to operate over noisy lines with a minimum of datatransfer errors. Since some noise is generated in the best of dial-up lines, the modem must operate with the lowest S/N ratio 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 operating conditions. Typically, a DPSK modem will exhibit better BER performance test curves receiving in the low band than in the high band. BER VS. RECEIVE LEVEL This test measures the dynamic range of the modem. Because signal levels vary widely over dialup lines, the widest possible dynamic range is desirable. The minimum Bell specification calls for 36 dB of dynamic range. S/N ratios are held constant at the indicated values while the receive level is lowered from a very high to very low signal levels. The width of the "bowl" of these curves, taken at the BER point, is the measure of dynamic range.
23
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
APPLICATIONS INFORMATION (continued)
*73K222BL
BER vs SIGNALTO NOISE
10-2
HIGH BAND RECEIVE -40 dBm DPSK OPERATION
*73K222BL
BER vs CARRIER OFFSET
10-2
HIGH BAND RECEIVE DPSK OPERATION
1200 BPS
10-3
BIT ERROR RATE
600 BPS
10-3
C2 C1 or 3002 C2 FLAT
10-4
C1 or 3002 FLAT
BIT ERROR RATE
10-4
3002 11.8 dB S/N
10-5
C2 11.3 dB S/N
10-5
10-6 2 4 6 8 10 12 14
10-6 12 8 4 0 -4 -8 -12
SIGNAL TO NOISE (dB)
CARRIER OFFSET (HZ)
*73K222BL BER vs RECEIVE LEVEL
10-2
HIGH BAND RECEIVE DPSK OPERATION C2 LINE
*73K222BL BER vs PHASE JITTER
10-2
HIGH BAND RECEIVE DPSK OPERATION
10-3
10-3
BIT ERROR RATE
10-4
BIT ERROR RATE
10-4
3002 11.5 dB S/N
S/N = 10.8 dB
10-5
10-5
C2 10.8 dB S/N
S/N = 15 dB
10-6 10 0 -10 -20 -30 -40 -50
10-6 0 4 8 12 16 20 24
RECEIVE LEVEL (dBm)
PHASE JITTER ( PEAK)
* = "EQ On" Indicates bit CR1 D4 is set for additional phase equalization.
24
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
MECHANICAL SPECIFICATIONS
32-Pin PLCC
0.453 (11.51) 0.449 (11.40)
0.023 0.029
PIN NO. 1 IDENT.
0.140 (3.56) 0.123 (3.12) 0.050 0.013 0.021 0.300 REF (7.62 REF) 0.430 (10.92) 0.390 (9.91) 0.026 0.032 0.045 (1.140) 0.020 (0.508)
0.595 (15.11) 0.585 (14.86)
0.553 (14.05) 0.549 (13.94)
0.095 (2.41) 0.078 (1.98)
0.400 REF (10.16 REF) 0.530 (13.46) 0.490 (12.45)
0.495 (12.57) 0.485 (12.32)
44-Lead TQFP
16.0 BSC (0.630)
16.0 BSC (0.630)
INDEX 1
14.0 BSC (0.552)
1.35 (0.053) 1.45 (0.057)
0.09 (0.035) 0.20 (0.008)
0.42 (0.0165) Typ. 1.00 (0.0394) Typ.
0.60 (0.024) Typ.
25
73K222BL V.22, V.21, Bell 212A, Bell 103 Single-Chip Modem with Integrated Hybrid
PACKAGE PIN DESIGNATIONS
(Top View)
CAUTION: Use handling procedures necessary for a static sensitive component.
XTAL1
AD0 AD1 AD2 AD3 AD4 AD5 AD6 DATA/AD7 ALE
4 5 6 7 8 9 10 11 12 13 14
WR
3
2
1
32
VREF
31
RESET
XTAL2
GND
RXA
CLK
30 29 28 27 26 25 24 23 22 21
N/C ISET OH RXCLK RXD TXD CS EXCLK TXCLK
15
RD
16
VDD
17
TXA2
18
TXA1
19
N/C
20
INT
32-Lead PLCC 73K222BL-IH
44-Lead TQFP 73K222BL-IGT
ORDERING INFORMATION
PART DESCRIPTION 73K222BL 73K222BL 32-Lead PLCC 44-Lead TQFP ORDER NUMBER 73K222BL-IH 73K222BL-IGT PACKAGING MARK 73K222BL-IH 73K222BL-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 Corporation, 2642 Michelle Drive, Tustin, CA 92780-7019, (714) 508-8800, FAX: (714) 508-8877 TDK Semiconductor Corporation 04/24/00- rev. E
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