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U4091BM-RFNG3Y

U4091BM-RFNG3Y

  • 厂商:

    ATMEL(爱特梅尔)

  • 封装:

  • 描述:

    U4091BM-RFNG3Y - Programmable Telephone Audio Processor - ATMEL Corporation

  • 数据手册
  • 价格&库存
U4091BM-RFNG3Y 数据手册
Features • • • • Speech Circuit with Anti-clipping Tone-ringer Interface with DC/DC Converter Speaker Amplifier with Anti-distortion Power-supply Management (Regulated and Unregulated) and a Special Supply for Electret Microphone • Voice Switch • Interface for Answering Machine and Cordless Phone Applications • • • • • Feature Phone Answering Machine Fax Machine Speaker Phone Cordless Phone Programmable Telephone Audio Processor U4091BM-R Benefits • No Piezoelectric Transducer Necessary for Tone Ringing • Complete System Integration of Analog Signal Processing on One Chip • Very Few External Components 1. Description The programmable telephone audio processor U4091BM-R is a linear integrated circuit for use in feature phones, answering machines and fax machines. It contains the speech circuit, tone-ringer interface with DC/DC converter, sidetone equivalent and ear-protection rectifiers. The circuit is line-powered and contains all components necessary for signal amplification and adaptation to the line. The U4091BM-R can also be supplied via an external power supply. An integrated voice switch with loudspeaker amplifier enables hands-free or open-listening operation. With an anti-feedback function, acoustic feedback during open listening can be reduced significantly. The generated supply voltage is suitable for a wide range of peripheral circuits. Rev. 4872A–CORD–08/05 Figure 1-1. Block Diagram Speech circuit Voice switch Audio amplifier Serial bus DTMF Tone ringer Clock Data Reset MCU 2 U4091BM-R 4872A–CORD–08/05 Figure 1-2. 4872A–CORD–08/05 VL 2 44 1 38 17 TXACL 15 STBAL 16 12 AGATX MICRO AGARX TXA 43 8 39 42 9 10 5 Power supply Detailed Block Diagram 4 3 11 30 Offset canceler Filter MUX MIC V MIC 40 DTMF/ melody Offset canceler 22 21 Ringing power converter 19 20 LIDET VMP RFDO AGCO DTMF AMPB LRX ADC V RING AGC AGCI AMREC EPO RXLS LTX Switch matrix optional 41 REG POR 7 6 SACL SA 14 13 35 34 AFS control RA DIV. 1/8/16/32 18 BIDIR serial bus 37 36 33 31 32 24 25 23 OSC. 3.58 MHz 26 28 29 27 µC RECO1 MICO V MP U4091BM-R 3 2. Pin Configuration Figure 2-1. Pinning SSO44 RECIN TXACL MIC3 MIC2 MIC1 RECO2 RECO1 IND VL SENSE GND VB SAO2 SAO1 VMPS VMP VMIC TSACL VRING IMPA COSC SWOUT 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 U4091BM 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 STRC STC STO AMREC AMPB MICO IMPSW TLDT INLDT INLDR TLDR CT BNMT BNMR ADIN ES 28 OSCOUT 27 RESET 26 25 24 23 OSCIN SDA SCL INT 4 U4091BM-R 4872A–CORD–08/05 U4091BM-R Table 2-1. Pin Pin Description Symbol Function Receive amplifier input(1) Time constant adjustment for transmit anti-clipping Microphone input for hands-free operation Input of symmetrical microphone amplifier with high common-mode rejection ratio Input of symmetrical microphone amplifier with high common-mode rejection ratio Output of the receive amplifier Output of the receive amplifier, also used for sidetone network The internal equivalent inductance of the circuit is proportional to the value of the capacitor at this pin. A resistor connected to ground may be used to adjust the DC mask Positive supply-voltage input to the device in speech mode Input for sensing the available line current Ground, reference point for DC and AC signals Unstabilized supply voltage for speech network Negative output of speaker amplifier (push-pull only) Positive output of speaker amplifier (single-ended and push-pull operation) Unregulated supply voltage for the microcontroller (via series regulator to VMP) Regulated output voltage for supplying the microcontroller (typically 3.3V/6 mA in speech mode) Reference node for microphone amplifier, supply for electret microphones Time constant for speaker amplifier anti-clipping Input for ringer supply Input for adjusting the ringer input impedance 70-kHz oscillator for ringing power converter Output for driving the external switch resistor Interrupt line for serial bus Clock input for serial bus Data line for serial bus Input for 3.58-MHz oscillator Reset output for the microcontroller Clock output for the microcontroller Input for external supply indication Input of A/D converter Output of background-noise monitor receive Output of background-noise monitor transmit Time constant for mode switching of voice switch Time constant of receive-level detector Input of receive-level detector Input of transmit-level detector Time constant of transmit-level detector Switch for additional line impedance Microphone preamplifier output 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 33 34 35 36 37 38 39 Note: RECIN TXACL MIC3 MIC2 MIC1 RECO2 RECO1 IND VL SENSE GND VB SAO2 SAO1 VMPS VMP VMIC TSACL VRING IMPA COSC SWOUT INT SCL SDA OSCIN RESET OSCOUT ES ADIN BNMR BNMT CT TLDR INLDR INLDT TLDT IMPSW MICO 1. The protection device at pin RECIN is disconnected. 5 4872A–CORD–08/05 Table 2-1. Pin Pin Description Symbol Function Input for playback signal of answering machine Output for recording signal of answering machine Output for connecting the sidetone network Input for sidetone network Input for sidetone network 40 41 42 43 44 Note: AMPB AMREC STO STC STRC 1. The protection device at pin RECIN is disconnected. 3. DC Line Interface and Supply-voltage Generation The DC line interface consists of an electronic inductance and a dual-port output stage which charges the capacitors at VMPS and VB. The value of the equivalent inductance is given by: 2 × R SENSE × C IND × ( R DC × R 30 ) L = -----------------------------------------------------------------------------------------( R DC + R 30 ) The U4091BM-R contains two identical series regulators which provide a supply voltage VMP of 3.3V suitable for a microprocessor. In speech mode, both regulators are active because VMPS and VB are charged simultaneously by the DC line interface. The output current is 6 mA. The capacitor at VMPS is used to provide the microcomputer with sufficient power during long line interruptions. Thus, long flash pulses can be bridged or an LCD display can be turned on for more than 2 seconds after going on-hook. When the system is in ringing mode, VB is charged by the on-chip ringing power converter. In this mode, only one regulator is used to supply VMP with maximum 3 mA. 4. Supply Structure of the Chip A main benefit of the U4091BM is the easy implementation of various applications due to the flexible system structure of the chip. Possible applications: • Group listening phone • Hands-free phone • Phones which feature ringing with the built-in speaker amplifier • Answering machine with external supply The special supply topology for the various functional blocks is shown in Figure 4-1 on page 7. There are four major supply states: 1. Speech condition In speech condition, the system is supplied by the line current. If the LIDET block detects a line voltage above approximately 2V, the internal signal VLON is activated. This is detected via the serial bus, all the blocks which are needed have to be switched on via the serial bus. For line voltages below 2V, the switches remain in quiescent state as shown in the diagram. 6 U4091BM-R 4872A–CORD–08/05 U4091BM-R 2. Power down (pulse dialing) When the chip is in power-down mode (bit LOMAKE), for example, during pulse dialing, all internal blocks are disabled via the serial bus. In this condition, the voltage regulators and their internal band gap are the only active blocks. 3. Ringing During ringing, the supply for the system is fed into VB via the Ringing Power Converter (RPC). Normally, the speaker amplifier in single-ended mode is used for ringing. The frequency for the melody is generated by the DTMF/Melody generator. 4. External supply In an answering machine, the chip is powered by an external supply via pin VB. The answering machine connections can be directly made to U4091BM-R. The answering machine is connected to the pin AMREC. For the output AMREC, an AGC function is selectable via the serial bus. The output of the answering machine will be connected to the pin AMPB, which is directly connected to the switching matrix. This enables the signal to be switched to every desired output. Figure 4-1. Supply Generator VL RSENSE 10 C 1 µF IND R + R 300 kΩ V 220 µF + + 3.3V VMP 47 µF 5.5V VB 5.5V VMPS 470 µF 5. Ringing Power Converter (RPC) The RPC transforms the input power at VRING (high voltage/low current) into an equivalent output power at VB (low voltage/high current) which is capable of driving the low-ohmic loudspeaker. The input impedance at VRING is adjustable from 3 k Ω t o 12 k Ω b y R IMPA (ZRING = RIMPA / 100) and the efficiency of the step-down converter is approximately 65%. 6. Ringing Frequency Detector (RFD) The U4091BM-R provides an output signal for the microcontroller. This output signal is always double the value of the input signal (ringing frequency). It is generated by a current comparator with hysteresis. The levels for the on-threshold are programmable in 16 steps, the off-level is fixed. Every change of the comparator output generates a high level at the interrupt output INT. The information can then be read out by means of a serial bus with either normal or fast read mode. The block RFD is always enabled. 7 4872A–CORD–08/05 Table 6-1. Threshold Level RINGTH[0:3] 0 15 Step VRING 7V 22V 1V 7. Clock Output Divider Adjustment The pin OSCOUT is a clock output which is derived from the crystal oscillator. It can be used to drive a microcontroller or another remote component and thereby reduces the number of crystals required. The oscillator frequency can be divided by 1, 8, 16, or 32. During power-on reset, the divider will be reset to 1 until it is changed by setting the serial bus. Table 7-1. Clock Output CLK[0:1] 0 1 2 3 Divider 1 8 16 32 Frequency 3.58 MHz 447 kHz 224 kHz 112 kHz 8. Serial Bus Interface The circuit is controlled by an external microcontroller through the serial bus. The serial bus is a bi-directional system consisting of a single-directional clock line (SCL) which is always driven by the microcontroller, and a bi-directional data-signal line. It is driven by the microcontroller as well as by the U4091BM-R (see Figure 20-1 on page 37). The serial bus requires external pull-up resistors as only pull-down transistors (pin SDA) are integrated. 8.1 WRITE The data is a 12-bit word: A0-A3: address of the destination register (0 to 15) D0-D7: content of the register The data line must be stable when the clock is high. Data must be shifted serially. After 12 clock periods, the write indication is sent. Then, the transfer to the destination register is (internally) generated by a strobe signal transition of the data line when the clock is high. 8.2 READ There is a normal and a fast-read cycle. In the normal read cycle, the microcontroller sends a 4-bit address followed by the read indicator, then an 8-bit word is read out. The U4091BM-R drives the data line. The fast read cycle is indicated by a strobe signal. With the following two clocks the U4091BM-R reads out the status bits RFDO and LIDET which indicate that a ringing signal or a line signal is present (see Figure 10-1 on page 11, Figure 10-2 on page 11 and Figure 10-3 on page 11). 8 U4091BM-R 4872A–CORD–08/05 U4091BM-R 9. DTMF Dialing The DTMF generator sends a multi-frequency signal through the matrix to the line. The signal is the result of the sum of two frequencies and is internally filtered. The frequencies are chosen from a low and a high frequency group. The circuit conforms to the CEPT recommendation concerning DTMF option. Three different levels for the low level group and two different preemphasis (2.5 dB and 3.5 dB) can be chosen by means of the serial bus (rec. T/CF 46-03). Attention: In high gain mode, distortion can occur if AGATX is high and DC mask is low. 10. Melody and Confidence Tone Generation Melody and confidence tone frequencies are given in Table 10-1. The frequencies are provided at the DTMF input of the switch matrix. A sinusoidal wave, a square wave or a pulsed wave can be selected by the serial bus. A square signal means the output is high for half of the frequency cycle, and low for the other half. A pulsed signal means high impedance phases of 1/6 of the period occur between the high and low phases. Table 10-1. 0 1 2 3 4 5 6 7 Status of Melody Generating DTMFM[0:2] 000 001 010 011 100 101 110 111 DTMF generator OFF Confidence tone melody on (sine) Ringer melody (pulse) Ringer melody (square signal) DTMF (mid level) DTMF (low level) DTMF (high level) – Status Decimal Table 10-2. DTMF Frequencies DTMFF[0:1] in DTMF Mode 00 01 10 11 Frequency 697 770 852 941 Error (%) –0.007 –0.156 0.032 0.316 Decimal 0 1 2 3 Table 10-3. DTMF Frequencies DTMFF[2:3] in DTMF Mode 00 01 10 11 Frequency 1209 1336 1477 1633 Error (%) –0.110 0.123 –0.020 –0.182 Decimal 0 1 2 3 9 4872A–CORD–08/05 Table 10-4. DTMFF4 in DTMF Mode Pre-emphasis Selection 0 1 Level 2.5 dB 3.5 dB Table 10-5. Decimal 0 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 DTMF and Melody Frequencies DTMFF [0:4] 00000 00001 00010 00011 00100 00101 00110 00111 01000 01001 01010 01011 01100 01101 01110 01111 10000 10001 10010 10011 10100 10101 10110 10111 11000 11001 11010 11011 11100 11101 11110 11111 f (Hz) 440.0 466.2 493.9 523.2 554.4 587.3 622.3 659.3 698.5 740.0 784.0 830.0 880.0 932.3 987.8 1046.5 1108.7 1174.7 1244.5 1318.5 1396.9 1480.0 1568.0 1661.2 1760.0 1864.6 1975.5 2093.0 2217.5 2349.3 2663.3 2983.0 Tone/ Name A 4 4 Error (%) –0.008 –0.016 –0.003 0.014 0.018 –0.023 –0.129 0.106 –0.216 –0.222 0.126 –0.169 0.288 –0.014 –0.004 –0.335 –0.355 –0.023 –0.129 0.106 –0.214 –0.222 0.126 –0.241 –0.302 –0.014 0.665 0.367 0.387 0.771 ----- DTMF Freq. 697 770 852 941 697 770 852 941 697 770 852 941 697 770 852 941 697 770 852 941 697 770 852 941 697 770 852 941 697 770 852 941 DTMP Freq. 1209 1209 1209 1209 1336 1336 1336 1336 1477 1477 1477 1477 1633 1633 1633 1633 1209 1209 1209 1209 1336 1336 1336 1336 1477 1477 1477 1477 1633 1633 1633 1633 Key 1 4 7 * 2 5 8 0 3 6 9 # A B C D 1 4 7 * 2 5 8 0 3 6 9 # A B C D A# C B4 4 4 C# D E F 4 D#4 4 4 4 F# G4 G# A B A# 4 5 5 5 C5 C# D D# F 5 5 5 E5 5 5 F# G 5 G#5 A6 A# B 6 6 C6 C# D 6 6 10 U4091BM-R 4872A–CORD–08/05 U4091BM-R Figure 10-1. Write Cycle Write cycle CLOCK DATA D7 D6 D5 D4 D3 D2 D1 D0 A3 A2 A1 A0 R/W=0 Data from µP Strobe from µP Figure 10-2. Normal Read Cycle Normal read cycle CLOCK DATA A3 A2 A1 A0 R/W = 1 Strobe from µP D7 D6 D5 D4 D3 D2 D1 D0 Data from µP Data from U4091BM Figure 10-3. Fast Read Cycle Fast read cycle CLOCK DATA Strobe from µP D7=IZC D6=IVE Data from U4091BM 11 4872A–CORD–08/05 Table 10-6. Register Names and Functions of the Serial Registers Group No. R0B0 R0B1 R0B2 R0B3 R0B4 R0B5 R0B6 R0B7 R1B0 R1B1 R1B2 R1B3 R1B4 R1B5 R1B6 R1B7 R2B0 R2B1 R2B2 R2B3 R2B4 R2B5 R2B6 R2B7 R3B0 R3B1 R3B2 R3B3 R3B4 R3B5 R3B6 R3B7 Name ENRING ERX ETX ENVM ENMIC ENSTBAL MUTE ENRLT ENSACL ENSA ENSAO ENAM ENAGC Reserved Reserved FOFFC I1O1 I1O2 I1O3 I1O4 I1O5 I2O1 I2O2 I2O3 I2O4 I2O5 I3O1 I3O2 I3O3 I3O4 I3O5 I4O1 Description Enable ringer Enable receive part Enable transmit part Enable VM generator Enable microphone Enable sidetone Muting earpiece amplifier Enable POR low threshold Enable anti-clipping for speaker amplifier Enable speaker amplifier and AFS Enable output stage speaker amplifier Enable answering machine connections Enable AGC for answering machine Speed up offset canceller Switch on MIC/LTX Switch on MIC/SA Switch on MIC/EPO Switch on MIC/AMREC Switch on MIC/AGCI Switch on DTMF/LTX Switch on DTMF/SA Switch on DTMF/EPO Switch on DTMF/AMREC Switch on DTMF/AGCI Switch on LRX/LTX Switch on LRX/SA Switch on LRX/EPO Switch on LRX/AMREC Switch on LRX/AGCI Switch on AMPB/LTX 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 1 Status 1 R0 Enables R1 Enables R2 Matrix R3 Matrix 12 U4091BM-R 4872A–CORD–08/05 U4091BM-R Table 10-6. Register R4 Names and Functions of the Serial Registers (Continued) Group Matrix No. R4B0 R4B1 R4B2 R4B3 R4B4 R4B5 R4B6 R4B7 R5B0 Name I4O2 I4O3 I4O4 I4O5 I5O1 I5O2 I5O3 I5O4 EAFS AGATX0 AGATX1 AGATX2 MICHF DBM5 MIC0 MIC1 SD Reserved SL0 SL1 LF0 LF1 LF2 LF3 P0 P1 P2 P3 P4 AGARX0 AGARX1 AGARX2 EA0 EA1 EA2 EA3 EA4 IMPH LOMAKE AIMP Description Switch on AMPB/SA Switch on AMPB/EPO Switch on AMPB/AMREC Switch on AMPB/AGCI Switch on AGCO/LTX Switch on AGCO/SA Switch on AGCO/EPO Switch on AGCO/AMREC Enable AFS block Gain transmit AGA LSB Gain transmit AGA Gain transmit AGA MSB Select RF-microphone input Maximum transmit level for anti-clipping Gain microphone amplifier LSB Gain microphone amplifier MSB Shut down Slope adjustment for sidetone LSB Slope adjustment for sidetone MSB Low frequency adjustment for sidetone LSB Low frequency adjustment for sidetone Low frequency adjustment for sidetone Low frequency adjustment for sidetone MSB Pole adjustment for sidetone LSB Pole adjustment for sidetone Pole adjustment for sidetone Pole adjustment for sidetone Pole adjustment for sidetone MSB Gain receive AGC LSB Gain receive AGC Gain receive AGC MSB Gain earpiece amplifier LSB Gain earpiece amplifier Gain earpiece amplifier Gain earpiece amplifier Gain earpiece amplifier MSB Line impedance selection (1 = 1 kΩ) Short circuit during pulse dialing Switch for additional external line impedance Status 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R5 AGATX MICLIM R5B1 R5B2 R5B3 R5B4 R5B5 R5B6 R5B7 R6B0 R6B1 R6B2 R6B3 R6B4 R6B5 R6B6 R6B7 R7B0 R7B1 R7B2 R7B3 R7B4 R7B5 R7B6 R7B7 R8B0 R8B1 R8B2 R6 Shut down Sidetone R7 Sidetone AGARX R8 EARA Line impedance R8B3 R8B4 R8B5 R8B6 R8B7 13 4872A–CORD–08/05 Table 10-6. Register Names and Functions of the Serial Registers (Continued) Group No. R9B0 R9B1 R9B2 R9B3 R9B4 R9B5 R9B6 R9B7 R10B0 R10B1 R10B2 R10B3 R10B4 R10B5 R10B6 R10B7 R11B0 R11B1 R11B2 R11B3 R11B4 R11B5 R11B6 R11B7 R12B0 R12B1 R12B2 R12B3 R12B4 R12B5 R12B6 R12B7 R13B0 R13B1 R13B2 CLK RTH TM R13B3 R13B4 R13B5 R13B6 R13B7 Name AFS0 AFS1 AFS2 AFS3 AFS4 AFS5 AFS4PS Reserved SA0 SA1 SA2 SA3 SA4 SE LSCUR0 LSCUR1 ADC0 ADC1 ADC2 ADC3 NWT SOC ADCR MSKIT DTMFF0 DTMFF1 DTMFF2 DTMFF3 DTMFF4 DTMFM0 DTMFM1 DTMFM2 CLK0 CLK1 RTH0 RTH1 RTH2 RTH3 TME0 TME1 Description AFS gain adjustment LSB AFS gain adjustment AFS gain adjustment AFS gain adjustment AFS gain adjustment AFS gain adjustment MSB Enable 4-point sensing Gain speaker amplifier LSB Gain speaker amplifier Gain speaker amplifier Gain speaker amplifier Gain speaker amplifier MSB Speaker amplifier single-ended mode Speaker amplifier charge-current adjustment LSB Speaker amplifier charge-current adjustment MSB Input selection ADC Input selection ADC Input selection ADC Input selection ADC Network tuning Start of ADC conversion Selection of ADC range Mask for interrupt bits DTMF frequency selection DTMF frequency selection DTMF frequency selection DTMF frequency selection DTMF frequency selection Generator mode selection Generator mode selection Generator mode selection Selection clock frequency for microcontroller Selection clock frequency for microcontroller Ringer threshold adjustment LSB Ringer threshold adjustment Ringer threshold adjustment Ringer threshold adjustment MSB Test mode enable (low active) Test mode enable (high active) Status 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R9 AFS R10 SA R11 ADC R12 DTMF R13 14 U4091BM-R 4872A–CORD–08/05 U4091BM-R Table 10-6. Register Names and Functions of the Serial Registers (Continued) Group No. R14B0 R14B1 R14B2 R14B3 R14B4 R14B5 R14B6 R14B7 R15B0 R15B1 R15B2 R15B3 R15B4 R15B5 R15B6 R15B7 Name TME2 TME3 Reserved CLOR0 CLOR1 CLOR2 CLOR3 CLOR4 Reserved Reserved Reserved CLOT0 CLOT1 CLOT2 CLOT3 CLOT4 Description Test mode enable (high active) Test mode enable (low active) Adjustment for calculated receive log amp LSB Adjustment for calculated receive log amp Adjustment for calculated receive log amp Adjustment for calculated receive log amp Adjustment for calculated receive log amp MSB Adjustment for calculated transmit log amp LSB Adjustment for calculated transmit log amp Adjustment for calculated transmit log amp Adjustment for calculated transmit log amp Adjustment for calculated transmit log amp MSB Status 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R14 TM CLOR R15 CLOT 10.1 Power-on Reset To avoid undefined states of the system when it is powered on, an internal reset clears the internal registers. The system (U4091BM-R + microcontroller) is woken up by any of the following conditions: • VMP > 2.75V and VB > 2.95V • and line voltage (VL) • or ringer (VRING) • or external supply (ES) The power-down of the circuit is caused by a shut-down sent by the serial bus (SD = 1), low-voltage reset, or by the watchdog function (see Figure 12-2 on page 17, Figure 12-3 on page 17 and Figure 12-4 on page 17). 11. Watchdog Function To avoid the system operating the microcontroller in a fault state, the circuit provides a watchdog function. The watchdog has to be retriggered every second by triggering the serial bus (sending information to the IC or other remote components at the serial bus). If there has been no bus transmission for more than one second, the watchdog initiates a reset. The watchdog provides a reset for the external microcontroller, but does not change the U4091BM-R’s registers. 15 4872A–CORD–08/05 12. Acoustic Feedback Suppression Acoustical feedback from the loudspeaker to the hands-free microphone may cause instability of the system. The U4091BM-R has a very efficient feedback-suppression circuit which offers a 4-point or (alternatively) a 2-point signal-sensing topology (see Figure 12-1). Two attenuators (TXA and SAI) reduce the critical loop gain via the serial bus either in the transmit or in the receive path. The overall loop gain remains constant under all operating conditions. The LOGs produce a logarithmically-compressed signal of the TX- and RX-envelope curve. The AFSCON block determines whether the TX or the RX signal has to be attenuated. The voice-switch topology can be selected by the serial bus. In 2-point-sensing mode, AFSCON is controlled directly by the LOG outputs. Figure 12-1. Basic System Configurations MICRO TXA MICO STO CTU RTU TLDT INLDT LOG BNMT LOG CALCT CTLO CBNMT AGATX BNM Mode control BNM Line AGARX LOG CALCR CT CCT AFSCON SA SAI DTD RECO2 BNMR CBNMR TLDR CRLO LOG INLDR RRU CRU RECO1 HV 16 U4091BM-R 4872A–CORD–08/05 U4091BM-R Figure 12-2. Power-on Reset (Line) Line LID IVDD OSCOUT ton VMP Reset trt - ton = 4.5 ms ton = start-up oscillator trt Figure 12-3. Power-on Reset (Ringing) VRING VB IVDD VMP OSCOUT Reset ton trt Figure 12-4. Power-on Reset (Low Voltage Reset) Line LID VMP LVI LVR LVI Reset OSCOUT 17 4872A–CORD–08/05 12.1 Dial-tone Detector The dial-tone detector is a comparator with one side connected to the speaker amplifier input and the other to VM with a 35-mV offset (see Figure 12-5 on page 21). If the circuit is in idle mode, and the incoming signal is greater than 35 mV (25 mVrms), the comparator's output will change thus disabling the receive idle mode. This circuit prevents the dial tone (which would be considered as continuous noise) from fading away as the circuit would have the tendency to switch to idle mode. By disabling the receive idle mode, the dial tone remains at the normally expected full level. 12.2 Background Noise Monitors This circuit distinguishes speech (which consists of bursts) from background noise (a relatively constant signal level). There are two background-noise monitors, one for the receive path and the other for the transmit path. The receive background-noise monitor is operated on by the receive level detector, while the transmit background noise monitor is operated on by the transmit level detector (see Figure 12-6 on page 21). They monitor the background noise by storing a DC voltage representative of the respective noise levels in capacitors at CBNMR and CBNMT. The voltages at these pins have slow rise times (determined by the internal current source and an external capacitor), but fast decay times. If the signal at TLDR (or TLDT) changes slowly, the voltage at BNMR (or BNMT) will remain more positive than the voltage at the non-inverting input of the monitor's output comparator. When speech is present, the voltage at the non-inverting input of the comparator will rise more quickly than the voltage at the inverting input (due to the burst characteristic of speech), causing its output to change. This output is sensed by the modecontrol block. 12.3 4-point Sensing In 4-point-sensing mode, the receive- and the transmit-sensing paths include additional CLOGs (calculated logarithmic amplifiers). The block MODECON compares the detector output signals and decides whether receive, transmit or idle mode has to be activated. Depending on the mode decision, MODECON generates a differential voltage to control AFSCON. The MODECON block has seven inputs: • The output of the transmit log (LOGT) – the comparison of LOGT, CLOGR • The output of the receive clog (CLOGR) – designated I1 • The output of the transmit clog (CLOGT) – the comparison of CLOGT, LOGR • The output of the receive log (LOGR) – designated I2 • The output of the transmit background-noise monitor (BNMT) – designated I3 • The output of the receive background-noise monitor (BNMR) – designated I4 • The output of the dial-tone detector The differential output (AFST, AFSR) of the block MODECON controls AFSCON. The effect of I1-I4 in Table 12-1 on page 19. 18 U4091BM-R 4872A–CORD–08/05 U4091BM-R Table 12-1. Mode Decision for Signal Sensing Input I1 T T R R T T R R Note: I2 T R T R T R T R I3 S Y Y X N N N X I4 X Y Y S X N N N Output Mode Transmit Change mode Change mode Receive Idle Idle Idle Idle X = don’t care; Y = I3 and I4 are not both noise. LOGT > CLOGR LOGT < CLOGR LOGR < CLOGT LOGR > CLOGT BNMT detects speech BNMT detects noise BNMR detects speech BNMR detects noise I1 = T I1 = R I2 = T I2 = R I3 = S I3 = N I4 = S I4 = N 12.4 Term Definitions 1. Transmit means the transmit attenuator is fully on, and the receive attenuator is at maximum attenuation. 2. Receive means the receive attenuator is fully on, and the transmit attenuator is at maximum attenuation. 3. In idle mode, the transmit and receive attenuator are at half of their maximum attenuation. – Change mode means both the transmit and receive speech are present in approximately equal levels. The attenuators are quickly switched (30 ms) to the opposite mode until one speech level dominates the other. – Idle means speech has ceased in both transmit and receive paths. The attenuators are then slowly switched (1.5s) to idle mode. 4. Switching to full transmit or receive modes from the idle mode is done at a fast rate (30 ms). 19 4872A–CORD–08/05 12.5 Summary of Truth Table 1. The circuit will switch to transmit mode if – Both transmit level detectors sense higher signal levels than the respective receive level detectors, and – The transmit background-noise monitor indicates the presence of speech 2. The circuit will switch to receive mode if – Both receive level detectors sense higher signal levels than the respective transmit level detectors, and – The receive background-noise monitor indicates the presence of speech 3. The circuit will switch to the reverse mode if – The level detectors disagree on the relative strengths of the signal levels, and – At least one of the background-noise monitors indicates speech 4. The circuit will switch to idle mode when – Both speakers are quiet (no speech present), or – When one speaker speech level is continuously overridden by noise at the other speaker’s location The time required to switch the circuit between transmit, receive and idle is determined by internal current sources and the capacitor at pin CT. A diagram of the CT circuitry is shown in Figure 12-7 on page 21. It operates as follows: • CCT is typically 4.7 µF. • To switch to transmit mode, ITX is turned on (IRX is off), charging the external capacitor to –240 mV below VM. (An internal clamp prevents further charging of the capacitor.) • To switch to receive mode, IRX is turned on (ITX is off), increasing the voltage on the capacitor to +240 mV with respect to VM. • To switch to reverse mode, the current sources ITX, IRX are turned off, and the current source IFI is switched on, discharging the capacitor to VM. • To switch to idle mode, the current sources ITX, IRX, IFI are turned off, and the current source ISI charges the capacitor to VM. 20 U4091BM-R 4872A–CORD–08/05 U4091BM-R Figure 12-5. Dial Tone Detector IN + - OUT to mode control 35 mV VM DTD I4 Figure 12-6. Background Noise Monitor VB BNMR (BNMT) TLDR (TLDT) + + 1 µF + - 56 kΩ 33 kΩ VM 36 mV I4 (I3) Figure 12-7. Generation of Control Voltage (CT) for Mode Switching CT CCT IRX 10 µA ITX 10 µA IFI ISI AFS control to attenuators Control circuit 4 I1-4 Dial tone det. VM VM 21 4872A–CORD–08/05 Figure 12-8. Block Diagram Hands-free Mode U4091BM-R 2-point Signal Sensing TXA MICRO LOG AFS control Line LOG SA SAI Figure 12-9. Block Diagram Hands-free Mode U4091BM-R 4-point Signal Sensing TXA MICRO LOGT CLOGT BNMT Mode control BNMR Line CLOGR CT CCT AFS control SA SAI DTD LOGR 22 U4091BM-R 4872A–CORD–08/05 U4091BM-R 13. Analog-to-Digital Converter (ADC) This circuit is a 7-bit successive-approximation analog-to-digital converter in switched capacitor technique. An internal band gap circuit generates a 1.25-V reference voltage which is the equivalent of 1 MSB (1 LSB = 19.5 mV). The possible input voltage at ADIN is 0V to 2.48V. The ADC needs an SOC (Start Of Conversion) signal. In the High phase of the SOC signal, the ADC is reset. Then, 50 µs after the beginning of the Low phase of the SOC signal, the ADC generates an EOC (End Of Conversion) signal which indicates that the conversion is finished. The rising edge of EOC generates an interrupt at the INT output. The result can be read out by the serial bus. Voltages higher than 2.45V have to be divided. The signal connected to the ADC is determined by 4 bits: ADC0, ADC1, ADC2 and ADC3. TLDR/TLDT measuring is possible relative to a preceding reference measurement. The current range of IL can be doubled by ADCR. If ADCR is High, S has the value 0.5, otherwise S = 1. The source impedance at ADIN must be lower than 250 kΩ. Accuracy: 1 LSB + 3% Figure 13-1. Timing of ADC SOC 50 µs EOC Figure 13-2. ADC Input Selection IL x 20 mV/(1 mA x S ) ADIN 0.4 x VB 0.4 x VMP S 0.4 x VMP 8 x (TLDR - REF) 8 x (TLDT - REF) 0.4 x S AO1 0.4 x OFF1 0.4 x OFF2 0.4 x OFF3 EOC ADC S OC MS B BIT5 BIT4 BIT3 BIT2 BIT1 LS B 23 4872A–CORD–08/05 Table 13-1. Decimal 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Note: Input Selection ADC ADC[1:4] 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 Symbol OFF IL ADIN extern VB VMPS VMP TLDR TLDT Not used SAO1 Offcan1 Offcan2 Offcan3 Not used Not used Not used Value I1 = S × 127 mA × D / 128 V2 = 2.5V × D / 128 (maximum 2.5V) V3 = (2.5V / 0.4) × D / 128 V4 = (2.5V / 0.4) × D / 128 V5 = (2.5V / 0.4) × D / 128 V6 = 8 × (Vp – Ref) × D / 128 V7 = 8 × (Vp – Ref) × D / 128 V4 = (2.5V / 0.4) × D / 128 Atmel’s internal use - D = measured digital word (0 ≤ D ≤ 127) S = programmable gain 0.5 or 1 Vp = peak value of the measured signal 24 U4091BM-R 4872A–CORD–08/05 U4091BM-R 14. Switch Matrix The switch matrix has 5 inputs and 5 outputs. Every pair of I/Os except AGCO and AGCIN can be connected. The inputs and outputs used must be enabled. If 2 or more inputs are switched to an output, the sum of the inputs is available at the output. The inputs MIC and LRX have offset cancellers with a 3-dB corner frequency of 270Hz. AMPB has a 60-kΩ input impedance. The TXO output has a digitally-programmable gain stage with a gain of 2 dB to 9 dB (in 1 dB steps) depending on AGATX0 (LSB), AGATX1, AGATX2 (MSB), and a first order low-pass filter with 0.5 dB damping at 3300Hz and 3 dB damping at 9450Hz. The outputs RXLS, EPO and AMREC have a gain of 0 dB. The offset at the outputs of the matrix is less than 30 mV. If a switch is open, the path has a damping of more than 60 dB. Figure 14-1. Switch Matrix Diagram AGCO AMPB LRX DTMF Offset cancel I5 I4 I3 I2 MIC Offset cancel I1 AGC Low pass O5 O4 O3 O2 O1 AGATX0 AGATX1 AGATX2 TXO -10 dB STO 2.9 dB LTX AMREC EPO RXLS AGCI 25 4872A–CORD–08/05 Table 14-1. Register Bits and Corresponding Switches No. R2B0 R2B1 R2B2 R2B3 R2B4 R2B5 R2B6 R2B7 R3B0 R3B1 R3B2 R3B3 R3B4 R3B5 R3B6 R3B7 R4B0 R4B1 R4B2 R4B3 R4B4 R4B5 R4B6 R4B7 Name I1O1 I1O2 I1O3 I1O4 I1O5 I2O1 I2O2 I2O3 I2O4 I2O5 I3O1 I3O2 I3O3 I3O4 I3O5 I4O1 I4O2 I4O3 I4O4 I4O5 I5O1 I5O2 I5O3 I5O4 Description Switch on MIC/LTX Switch on MIC/RXLS Switch on MIC/EPO Switch on MIC/AMREC Switch on MIC/AGCI Switch on DTMF/LTX Switch on DTMF/RXLS Switch on DTMF/EPO Switch on DTMF/AMREC Switch on DTMF/AGCI Switch on LRX/LTX Switch on LRX/RXLS Switch on LRX/EPO Switch on LRX/AMREC Switch on LRX/AGCI Switch on AMPB/LTX Switch on AMPB/RXLS Switch on AMPB/EPO Switch on AMPB/AMREC Switch on AMPB/AGCI Switch on AGCO/LTX Switch on AGCO/RXLS Switch on AGCO/EPO Switch on AGCO/AMREC R2 R3 R4 26 U4091BM-R 4872A–CORD–08/05 U4091BM-R 15. Sidetone System Figure 15-1. Principle Circuit of Sidetone Balancing LTX 8 dB LINE CK ZL LRX 0 - 7 dB + - DIFF1 -10 dB MOD RECIN AGARX STO_DIFF AMP1 STO -10 dB 9 dB AMP2 STOAMP Sidetone balancing STO 8.2 kΩ g LF P STRC CTO 33 nF SL STC f LF P SL The Sidetone Balancing (STB) has the task of reducing the cross-talk from LTX (microphone) to LRX (earpiece) in the frequency range of 0.3 kHz to 3.4 kHz. The LTX signal is converted into a current in the MOD block. This current is transformed into a voltage signal (LINE) by the line impedance ZL. The LINE signal is fed into the summing amplifier DIFF1 via capacitor CK and attenuator AMP1. On the other hand the LTX buffered by STOAMP drives an external low-pass filter (RST, CST). The external low-pass filter and the internal STB have the transfer function drawn in the STB box. The amplified STB output signal drives the negative input of the summing block. If both signals at the DIFF1 block are equal in level and phase, we have good suppression of the LTX signal. In this condition, the frequency and phase response of the STB block will represent the frequency curve on line. In real life, the line impedance ZL varies strongly for different users. To obtain good suppression with one application for all different line impedances, the STB function is programmable. 27 4872A–CORD–08/05 The 3 programmable parameters are 1. LF (gain at low frequency) LF has 15 programming steps of 0.5 dB LF(0) provides –2 dB gain, LF(15) provides 5.5 dB gain STO_DIFF(LF) = (–10 dB – 2 dB + 0.5 dB × LF + 9 dB) × LTX 2. P (the pole position of the low-pass) The P adjustment has 31 steps. P(0) means the lowpass determined by the external application (RST, CST). The internally processed low-pass frequency is fixed by the following equation. 1 P f(P) = --------------------------------------------------- × 1.122 2 × π × CST × RST 3. SL (sidetone slope; the pole frequency of the high-pass) The SL has 3 steps. SL(0) is a lower frequency of the high-pass. SL(3) is a higher frequency of the high-pass. SL can be used to influence the suppression at high frequencies. Figure 15-2. Audio Frequency Signal Management U4091BM-R -10 dB -3 dB to -10 dB and 7 dB (NWT) ST 7 dB --> 0 dB and 20 dB (NWT) Sidetone balancing 1 dB steps Offset cancel LRX RXLS Offset cancel 32 dB --> -23dB 6 dB 1.5dB steps SAO2 26 dB --> -3 dB and -10 dB (DTMF) RECO1 Earpiece DTMF < -34 dBm/ -32 dBm > RECO2 SAO1 Loudspeaker VL Line DTMF generator MIC1 Handset microphone MIC2 Intercom microphone Answering machine MIC3 0 dB 6 dB steps Filter --> DTMF DTMF < -24 dBm/ -22 dBm > EPO 1 dB steps 9 dB --> 2 dB VL 8 dB 1 dB steps MOD 0 dB 30 dB --> 12 dB 7 dB --> -48 dB Offset cancel 1 dB steps Switching matrix MIC LTX Line AMREC 0 dB AMPB AMPB AMREC 0 dB Answering machine 0 dB AGCO AGCI 0 dB AGC 28 U4091BM-R 4872A–CORD–08/05 U4091BM-R 16. Absolute Maximum Ratings Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Parameters Line current DC line voltage Maximum input current Junction temperature Ambient temperature Storage temperature Total power dissipation, Tamb = 60°C Symbol IL VL IRING Tj Tamb Tstg Ptot Value 140 12 15 125 –25 to +75 –55 to +150 0.9 Unit mA V mA °C °C °C W 17. Thermal Resistance Parameters Junction ambient SSO44 Symbol RthJA Value 70 Unit K/W 18. Electrical Characteristics f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters DC Characteristics IL = 2 mA IL = 14 mA IL = 60 mA IL = 100 mA 4.4 8.6 1.6 4.8 7.2 9.2 5.2 9.8 V V V V Test Conditions Symbol Min. Typ. Max. Unit DC voltage drop over circuit VL Transmission Amplifier, IL = 14 mA, VMIC = 2 mV, MICG[0:1] = 2, AGATX[0:2] = 7 ERX = ETX = ENMIC = ENSTBAL = I1O1 = I3O3 = 1, (GT = 48 dB) Transmit amplification Frequency response due to internal filters Gain change with current Gain deviation CMRR of microphone amplifier Input resistance of MIC amplifier Input resistance of MIC3 amplifier Gain difference between MIC1/MIC2 to MIC3 Distortion at line MICHF = 1 MICHF = 1 IL ≥ 14 mA, VL = 700 mVrms IL ≥ 19 mA, d < 5%, VMIC = 10 mV CTXA = 1 µF, DBM5 = 0 Maximum output voltage DBM5 = 1 VMIC = 20 mV, MICG[0:1] = 3 Note: MICG[0:1] = 2 AGATX[0:2] = 7 IL ≥ 14 mA, f = 1 kHz to 3.4 kHz IL = 14 mA to 100 mA Tamb = –10°C to +60°C GT ∆GT ∆GT ∆GT CMRR Ri Ri ∆GT dt VLmax VLmax VMICOmax 1.8 4.8 3.0 6.0 –4.2 75 60 80 50 150 300 ±0.4 2 4.2 6.6 45.3 –1 46.5 47.7 0 ±0.5 ±0.5 dB dB dB dB dB kΩ kΩ dB % dBm dBm dBm 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 29 4872A–CORD–08/05 18. Electrical Characteristics (Continued) f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters Noise at line psophometrically weighted Anti-clipping attack time release time Gain at low operating current Test Conditions IL ≥ 14 mA, MICG[0:1] = 2 AGATX[0:2] = 7 CTXA = 1 µF each 3 dB overdrive IL = 8 mA, IMP = 1 mA VMIC = 0.5 mV IVMIC = 300 µA IL = 8 mA, IMP = 1 mA VMIC = 5 mV IVMIC = 300 µA Symbol Min. Typ. Max. Unit No –73 –70 dBmp ta tr GT 45 2 80 48 ms ms dB Distortion at low operating current dt 5 % Receiving Amplifier IL = 14 mA, VGEN = 300 mV, ERX = ETX = ENMIC = ENSTBAL = I1O1 = I3O3 = 1, SL[0:1] = 0, LF[0:3] = 1, P[0:4] = 31, AFS[0:5] = 54, AGARX[0:2] = 0 Adjustment range of receiving gain Single ended, IL ≥ 14 mA, Mute = 1, EA[0:4] = 2 to 31 AGARX[0:2] = 0 to 7 Differential AGARX[0:2] = 0 EA[0:4] = 15 EA[0:4] = 31 IL ≥ 14 mA, f = 1 kHz to 3.4 kHz IL = 14 mA to 100 mA Tamb = –10°C to +60°C IL ≥ 14 mA, VGEN = 11 Vrms EA[0:4] = 15 IL = 14 mA, I303 = 0 IL = 14 mA Zear = 68 nF + 100Ω EA[0:4] = 11 Zear = 100Ω EA[0:4] = 31 IL = 14 mA Zear = 68 nF + 100Ω EA[0:4] = 15 Z = 600Ω Each output against GND IL = 6.5 mA, IMP = 1 mA IM = 300 mA VGEN = 200 mV EA[0:4] = 21, ENMIC = ETX = I101 = 0 Ro 20 10 Iout GR –19 +17 dB Receiving amplification GR ∆GRF ∆GR ∆GR EP ∆GR –1 14.7 –1 0 15.7 1 16.7 0 ±0.5 ±0.5 3 dB dB dB dB dB Vrms dB Frequency response Gain change with current Gain deviation Ear protection differential MUTE suppression (earpiece disconnect from matrix) Output voltage d < 2% differential Maximum output current d < 2% Receiving noise psophometrically weighted Sidetone suppression Output resistance 60 0.775 Vrms mAp –79 –76 dBmp dB Ω 4 Gain at low operating current (receive only) GR –2 0 2 dB Note: 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 30 U4091BM-R 4872A–CORD–08/05 U4091BM-R 18. Electrical Characteristics (Continued) f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters Distortion at low operating current Adjustment step: earpiece amplifier Adjustment step: AGARX Gain for DTMF signal AC impedance Test Conditions IL = 6.5 mA, IMP = 1 mA IM = 300 µA, EA[0:4] = 15, ENMIC = ETX = I101 = 0 DEA[0:4] = 1 for EA[0:4] = 2 to 31 DAGARX[0:2] = 1 AMPB → RECO1/2 EA[0:4] = 1 IMPH = 0 IMPH = 1 Sum level, 600Ω, DTMFM[0:2] = 4 Sum level, 600Ω, DTMFM[0:2] = 5 Sum level, 600Ω, DTMFM[0:2] = 6 AGATX[0:2] = 1 600 W, DTMFF4 = 0 DTMFF4 = 1 Zimpl Zimph 595 980 Symbol Min. Typ. Max. Unit dR 5 % 0.8 0.8 1 1 –10 625 1030 1.2 1.2 dB dB dB 655 1080 Ω Ω DTMF, IL = 14 mA, ETX = I201 = 1, AGATX[0:2] = 7, DTMFM[0:2] = 4, DTMFF[0:4] = 0 DTMF level at line (mid gain) DTMF level at line (low gain) –5.1 –7.6 –3.6 –6.1 –2.1 –4.6 dBm dBm DTMF level at line (high gain) –5.2 2 3 –3.7 2.5 3.5 –2.2 3 4 dBm dBm dBm Pre-emphasis Speaker Amplifier, Differential Mode AMPB → SAO1/2 ENSACL = ENSA = ENSAO = ENAM = I4O2 = 1, SA[0:4] = 31, ERX = ETX = ENMIC = ENSTBAL = I1O1 = I3O3 = 1 Minimum line current for operation ENAM = I4O2 = 0 SE = 0, I3O2 = 1 IMP 1 mA, VGEN = 300 mV VAMPB = 3 mV, IL = 15 mA, SA[0:4] = 31 SA[0:4] = 0 DSA[0:4] = –1 Load resistance: RLS = 50Ω VAMPB = 40 mV, SE = 1 IL = 15 mA IL = 20 mA Load resistance: RL = 50Ω VAMPB = 60 mV, SE = 0 VB = 5V IL > 15 mA IL = 15 mA Tamb = –10°C to +60°C ILmin 11 mA Gain from AMPB to SAO Adjustment step speaker amplifier GSA 36 1.15 37 –5.5 1.35 38 1.55 dB dB Output power single ended PSA PSA PSA 3 7 20 mW mW Maximum output power differential 150 mW Output noise (input AMPB open) psophometrically weighted Gain deviation Note: nSA ∆GSA 240 mVpsoph dB ±1 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 31 4872A–CORD–08/05 18. Electrical Characteristics (Continued) f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters Mute suppression Gain change with current Gain change with frequency Attack time of anti-clipping Release time of anti-clipping Adjustment step of charge current Adjustment step of discharge current Charge current Pin SAO2 Discharge current pin SAO2 ENSAO = 0, SE = 1 DLSCUR[0:1] = 1 ENSAO = 0, SE = 0 DLSCUR[0:1] = 1 ENSAO = 0, SE = 1 LSCUR[0:1] = 3 ENSAO = 0, SE = 0 LSCUR[0:1] = 3 ICHA IDIS Test Conditions IL = 15 mA, VL = 0 dBm, VAMPB = 4 mV I4O2 = 0 IL = 15 mA to 100 mA IL = 15 mA f = 1 kHz to 3.4 kHz 20 dB overdrive Symbol Min. Typ. Max. Unit VSAO ∆GSA ∆GSA tr tf –480 320 –1.45 0.95 –1 2 170 –400 400 –1.2 1.2 –56 1 0 dBm dB dB ms ms –320 480 –0.95 1.45 µA µA mA mA Microphone Amplifier, VB = 5V, VMIC = 2 mV, VMIC3 = 2 mV, ENMIC = ENAM = I1O4 = 1, MICHF = 0 MICG[0:1] = 0 Gain MIC amp.: MIC1/2 →AMREC MICG[0:1] = 1 MICG[0:1] = 2 MICG[0:1] = 3 MIC3 to AMREC Input suppression: MIC3 to MIC1/2 MIC1/2 to MIC3 Settling time offset cancellers Settling time offset cancellers in speed-up mode MICHF = 1, MICG[0:1] = 3 MICG[0:1] = 0, MICHF = 0 MICHF = 1 5 τ , FOFFC = 0 5 τ , FOFFC = 1 17.4 23.2 29.1 35.0 35.0 60 60 9 1.8 12 2.4 18.1 23.7 29.8 35.7 35.7 18.8 24.6 30.5 36.4 36.5 dB dB dB dB dB dB dB ms ms AGC for Answering Machine, AMPB to AMREC, ENAM = ENAGC = I4O5 = I5O4 = 1 Nominal gain Maximum output level Attack time Release time Switching Matrix, VL = 0, VB = 5V, ENAM = I4O4 = 1, VAMPB = 0.6 Vrms Input impedance AMPB Gain AMPB to AMREC Maximum input level AMPB Maximum output level AMREC Note: I4O5 = I5O4 = 1, I4O4 = 0 I4O4 = 1 50 –0.7 60 –0.3 70 +0.1 600 VB – 600 mV kΩ dB mV VPP VAMPB = 5 mV VAMPB = 50 mV, d< 5% 20 dB overdrive 23.5 240 25.5 300 1 45 27.5 360 dB mVp ms ms 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 32 U4091BM-R 4872A–CORD–08/05 U4091BM-R 18. Electrical Characteristics (Continued) f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters Offset Mute switching matrix Test Conditions I4O4: 1 to 0 I4O4 = 0 Symbol Min. Typ. Max. Unit ∆VAMREC 60 ±30 mV dB Power-on Reset VL = 0, VMP = 3.3V, VB = 5V, U4091 in Power-down Mode Power-on reset by ES VB high, VMP threshold Power-on reset by ES VMP high, VB threshold Low-voltage Interrupt VL = 0, VMP = 3.3V, VB = 0V VMP decreasing Power-off Reset VL = 0, VMP = 3.3V, VB = 0V Low-voltage reset Difference voltage between lowvoltage interrupt and reset Logical Part VMP = 3.3V, VB = 5V Output impedance at OSCOUT Pins SCL, SDA (input mode) Input leakage current Pins INT, SDA (output mode) Low level High level 0 < Vi < VMP Output low (resistance to GND) 0.6 0.8 × VMP –1 150 230 0.9 1.2 0.2 × VMP +1 350 kΩ V V µA Ω Decrease VMP until RESET returns to low VLVI – VLVR VLVR 2.35 100 2.45 150 2.55 V mV Decrease VMP until INT returns to high VLVI 2.5 2.6 2.7 V VB = 4V, ES = 4V, raise VMP until RESET goes to low VMP = 3V, ES = 4V, raise VB until RESET goes to low VMPon VBon 2.65 2.75 3.2 2.85 V V Switch for Additional Impedance (Pin IMPSW) VMP = 3.3V, VB = 3V Switch-off leakage current Resistance to GND Maximum current 0 < Vi < VMP IMPSW = 0 IMPSW = 1 IMPSW = 1 –5 –0.5 50 5 80 5 µA Ω mA AFS (Acoustic Feedback Suppression), IL = 14 mA, VGEN = 300 mV, ERX = ETX = ENMIC = ENSTBAL = I1O1 = I3O3 = 1, SL[0:1] = 0, LF[0:3] = 1, P[0:4] = 31, AGARX[0:2] = 0 Adjustment range of attenuation Attenuation of transmit gain Attenuation of speaker amplifier Note: IL ≥ 15 mA IL ≥ 15 mA, IINLDT = 0 µA IINLDR = 10 µA IL ≥ 15 mA, IINLDT = 10 µA IINLDR = 0 µA ∆GT GSA 0 47 47 50 50 50 53 53 dB dB dB 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 33 4872A–CORD–08/05 18. Electrical Characteristics (Continued) f = 1 kHz, 0 dBm = 775 mVrms, IVMIC = 0.3 mA, IMP = 3 mA, RDC = 1.3 MΩ, Tamb = 25°C, Zear = 68 nF + 100Ω, RLS = 50Ω, ZM = 68 nF, resonator: f = 3.58 MHz, all bits in reset condition, unless otherwise specified. Parameters Test Conditions IL = 14 mA, RDC = 680 kΩ IMP = 3 mA IL = 100 mA, RDC = inf., IMP = 0 mA IL = 14 mA, RDC = 1.3 MΩ IM = 700 A IB = +20 mA, IL = 0 mA VRING = 20.6V ENSA = ENSAO = SE = 1 VRING: high to low Threshold Adjustment steps threshold Input impedance Maximum input voltage Serial Bus SCL, SDA, AS, VMP = 3.3V, RSDA = RSCL = RINT = 12 kΩ Input voltage HIGH LOW Output voltage Acknowledge LOW Clock frequency Rise time SDA, SCL Fall time SDA, SCL Period of SCL HIGH LOW Setup Time Start condition Data Stop condition Time space(1) Hold Time Start condition DATA Note: thSTA thDAT 4.0 0 µs µs tsSTA tsDAT tsSTOP twSTA 4.7 250 4.7 4.7 µs ns µs µs HIGH LOW SDA, SCL, INT SDA ISDA = 3 mA SCL ViBUS 3.0 0 VDD 1.5 0.4 100 1 300 4.0 4.7 V V V kHz µs ns µs µs Low to high, RINGTH [0:3] = 0 Low to high, RINGTH [0:3] = 15 DRINGTH = 1 VRING = 30V VRINGmax 6.0 19 0.8 4.6 30 6.7 21 1 5.8 Symbol Min. Typ. Max. Unit Supply Voltages, VMIC = 25 mV, Tamb = –10°C to + 60°C VMP VMPS VMIC VB VMP VMPS VMIC VB 1.5 5.5 3.1 3.3 3.5 5.5 4 6.3 V V V V Ringing Power Converter, IMP = 1 mA, IM = 0, RIMPA = 500 kΩ Maximum output power PSA 15 7.4 7.4 23 1.2 7.0 mW V V V V kΩ V VO fSCL tr tf tH tL 1. This is a period of time the bus requires from the end of a data transmission and before a new transmission can be started 34 U4091BM-R 4872A–CORD–08/05 4872A–CORD–08/05 19. Test Circuits Figure 19-1. Basic Test Circuit sin PWL V V 3.58 MHz 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 + + V A PWL V + 44 43 42 41 40 U4091BM 1 V CIND RCD V 50Ω V V V 10Ω 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 + + sin sin U4091BM-R 35 Figure 19-2. Test Circuit for Ringing 36 PWL PWL 3.58 MHz + + 40 39 38 37 36 35 34 33 32 31 30 27 28 29 26 25 24 23 U4091BM-R U4091BM 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 BC 556 22 2.2 mH 68 nF V 50Ω 44 43 42 41 1 2 3 4 SD103A VB V VB 4872A–CORD–08/05 U4091BM-R 20. Bus Timing Figure 20-1. Bus Timing Diagram SDA twSTA t r SCL t f thSTA P S thSTA t L t hDAT P = Stop, S = Start tH tsSTA thDAT tsSTOP P 21. Ordering Information Extended Type Number U4091BM-RFNGY U4091BM-RFNG3Y T4091R-DDB Package SSO44 SSO44 Die Remarks Tube Taped and reeled Die on foil 22. Package Information Package SSO44 Dimensions in mm 18.05 17.80 9.15 8.65 7.50 7.30 2.35 0.3 0.8 16.8 44 23 0.25 0.10 0.25 10.50 10.20 technical drawings according to DIN specifications 1 22 37 4872A–CORD–08/05 A tmel Corporation 2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600 Atmel Operations Memory 2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 436-4314 RF/Automotive Theresienstrasse 2 Postfach 3535 74025 Heilbronn, Germany Tel: (49) 71-31-67-0 Fax: (49) 71-31-67-2340 1150 East Cheyenne Mtn. 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Blvd. Colorado Springs, CO 80906, USA Tel: 1(719) 576-3300 Fax: 1(719) 540-1759 Scottish Enterprise Technology Park Maxwell Building East Kilbride G75 0QR, Scotland Tel: (44) 1355-803-000 Fax: (44) 1355-242-743 Japan 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581 Literature Requests www.atmel.com/literature Disclaimer: T he information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN ATMEL’S TERMS AND CONDITIONS OF SALE LOCATED ON ATMEL’S WEB SITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE, SPECIAL OR INCIDENTAL DAMAGES (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF PROFITS, BUSINESS INTERRUPTION, OR LOSS OF INFORMATION) ARISING OUT OF THE USE OR INABILITY TO USE THIS DOCUMENT, EVEN IF ATMEL HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. A tmel makes no representations or warranties with respect to the accuracy or completeness of the contents of this document and reserves the right to make changes to specifications and product descriptions at any time without notice. Atmel does not make any commitment to update the information contained herein. Unless specifically provided otherwise, Atmel products are not suitable for, and shall not be used in, automotive applications. Atmel’s products are not intended, authorized, or warranted for use as components in applications intended to support or sustain life. © Atmel Corporation 2005 . A ll rights reserved. Atmel ®, logo and combinations thereof, Everywhere You Are ® a nd others, are registered trademarks or trademarks of Atmel Corporation or its subsidiaries. Other terms and product names may be trademarks of others. Printed on recycled paper. 4872A–CORD–08/05
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