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| technical data 201 3 , january , ver. 0 2 voice switched speakerphone circuit the IL34118 voice switched speakerphone circuit incorporates the necessary amplifiers, attenuators, level detectors, and control algorithm to form the heart of a high quality hands - free speakerphone system. included are a microphone amplifier with adjustable gain and mute control, transmit and receive attenuators which operate in a complementary manner, level detectors at both input and output of both at tenuators, and background noise monitors for both the transmit and receive channels. a dial tone detector prevents the dial tone from being attenuated by the receive background noise monitor circuit. also included are two line driver amplifiers which can b e used to form a hybrid network in conjunction with an external coupling transformer. a high pass filter can be used to filter out 60 hz noise in the re c eive channel, or for other filtering functions. a chip disable pin permits powering down the entire cir cuit to conserve power on long loops where loop current is at a minimum. the IL34118 may be operated from a power supply, or it can be powered from the telephone line, requiring typically 5.0 ma. the IL34118 can be interfaced directly to tip and ring (thro ugh a coupling transformer) for stand - alone operation, or it can be used in conjunction with a handset speech network and or other features of a feature phone. futures ? improved attenuator gain range: 52 db be tween transmit and receive ? low voltage operation for line - powered applications (3.0 - 6.5 v) ? 4 point signal sensing for improved sensitivity ? background noise monitors for both transmit and receive paths ? microphone amplifier gain set by external resistors - m ute function included ? chip disable for active standby operation ? on board filter pinned - out for user de f ined function ? dial tone detector to inhibit receive idle mode during dial tone presence IL34118 IL34118n plastic IL34118d w /d w t soic pin assignment ordering information device operating temperature range package pa c king il 34118 n t a = - 20 ? to 70 ? c dip 2 8 tube il 34118 d w sop 2 8 tube il 34118 d w t sop 2 8 tape & reel
IL34118 201 3 , january , ver. 0 2 simplified block diagram functional desc ription introduction the fundamental difference between the operation of a speakerphone and a handset is that of half - duplex versus full - duplex. the handset is full duplex since conversation can occur in both directions (transmit and receive) simultaneo us l y. a speakerphone has higher gain levels in both paths, and attempting to converse full duplex results in oscillatory problems due to the loop that exists within the system. the loop is formed by the receive and transmit paths, the hybrid, and the acous tic coupling (speaker to microphone). the only practical and economical solution used to data is to design the speakerphone to function in a half duplex mode - i.e., only one person speaks at a time, while the other listens. to achieve this requires a circ uit which can detect who is talking, switch on the appropriate path (transmit or receive), and switch off (attenuate) the other path. in this way, the loop gain is maintained less than unity. when the talkers exchange function, the circuit must quickly det ect this, and switch the circuit appropriately. by providing speech level detectors, the circuit operates in a hand - free mode, eliminating the need for a push - to - talk switch. the handset, by the way, has the same loop as the speakerphone. but since the gains are considerably lower, and since the acoustic coupling from the earpiece to the mouthpiece is almost non - existent (the receiver is normally held against a persons ear), oscillations dont occur. the IL34118 provides the necessary level detectors , attenuators, and switching control for a properly operating speakerphone. the detection sensitivity and timing are externally controllable. additionally, the IL34118 provides background noise monitors which make the circuit insensitive to room and line n oise, hybrid amplifiers for interfacing to tip and ring, the microphone amplifier, and other associated functions. attenuators the transmit and receive attenuators are complementary in function, i.e., when one is at maximum gain (+6.0 db), the other is a t maximum attenuation ( - 46 db), and vice versa. they are never both fully on or both fully off. the sum of their gains remains constant (within a nominal error band of ? 0.1 db) at a typical value of - 40 db. their purpose is to control the transmit and rece ive paths to provide the half - duplex operation required in a speakerphone. the attenuators are non - inverting, and have a - 3.0 db (from max gain) frequency of ? 100 khz. the input impedance of each attenuator (txi and rxi) is nominally 10 k ? (see figure 1), and the input signal should be limited to 350 mvrms (990 mvp - p) to prevent distortion. that maximum IL34118 201 3 , january , ver. 0 2 recommended input signal is independent of the volume control setting. the diode clamp on the inputs limits the input swing, and therefore the maximum neg ative output swing. this is the reason for v rxol and v txol specification being defined as they are in the electrical characteristics. the output impedance is <10 ? until the output current limit (typically 2.5 ma) is reached. figure 1. attenuator input st age the attenuators are controlled by the single output of the control block, which is measurable at the c t pin (pin 14). when the c t pin is at +240 millivolts with respect to v b , the circuit is in the receive mode (receive attenuato r is at +6.0 db). when the c t pin is at - 240 millivolts with respect to v b , the circuit is in the transmit mode (transmit attenuator is at +6.0 db). the circuit is in an idle mode when the c t voltage is equal to v b , causing the attenuators gains to be h alfway between their fully on and fully off positions ( - 20 db each). monitoring the c t voltage (with respect to v b ) is the most direct method of monitoring the circuits mode. the inputs to the control block are seven: 2 from the comparators operated by th e level detectors, 2 from the background noise monitors, the volume control, the dial - tone detector, and the agc circuit. these seven inputs are described below. level detectors there are four level detectors - two on the receive side and two on the tran smit side. refer to figure 2 - the terms in parentheses form one system, and the other terms form the second system figure 2. level detectors each level detector is a high gain amplifier with back - to - back diodes in the feedback path , resulting in non - linear gain, which permits operation over a wide dynamic range of speech levels. the sensitivity of each level detector is determined by the external resistor and capacitor at each input (tli1, tli2, rli1, and rli2). each output charges an external capacitor through a diode and limiting resistor, thus providing a dc representation of the input ac signal level. the outputs have a q uick rise time (determined by the capacitor and an internal 350 ? resistor), and a slow decay time set by an internal current source and the capacitor. the capacitors on the four outputs should have the same value ( ? 10%) to prevent timing problems . referring to figure 8, on the receive side, one level detector (rli1) is at the receive input receiving the same signal as at tip and ring, and IL34118 201 3 , january , ver. 0 2 the other (rli2) is at the output of the speaker amplifier. on the transmit side, one level detector (tli2) is at the output of the microphone amplifier, while the other (tli1) is at the hybrid output. outputs rlo1 and tlo1 feed a comparator, the output of which goes to the attenuator control block. likewise, outputs rlo2 and tlo2 feed a second comparator which also goes to the attenuator control block. the truth table for the effects of the level detectors on the control blo ck is given in the section describing the control block. background noise monitors the purpose of the background noise monitors is to distinguish 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 one for the transmit path. refer r ing to figure 2, the receive background noise monitor is operated on by the rli1 - rlo1 level detector, while the transmit background noise monitor is operated on by th e tli2 - tlo2 level detector. they monitor the background noise by storing a dc voltage representative of the respective noise levels in capacitors at cpr and cpt. the voltages at these pins have slow rise times (determined by the external rc), but fast deca y times. if the signal at rli1 (or tli2) changes slowly, the voltage at cpr (or cpt) will remain more positive than the voltage at the non - inverting input of the monitors output comparator. when speech is present, the voltage on the non - inverting input of the comparator will rise quicker 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 attenuator control block. the 36 mv offset at the comparators input keeps the comparator from changing state unless the speech level exceeds the background noise by ? 4.0 db. the time constant of the external rc ( ? 4.7 seconds) determines the response time to background noise variations volume control the volume control input at vl c (pin 13) is sensed as a voltage with respect to v b . the volume control affects the attenuators only in the receive mode. it has no effect in the idle or transmit modes. when in the receive mode, the gain of the receive attenuator will be +6.0 db, and the gain of the transmit attenuator will be - 46 db only when vlc is equal to v b . as vlc is reduced below v b , the gain of the receive attenuator is reduced, and the gain of the transmit attenuator is increased such that their sum remains constant. changing t he voltage at vlc changes the voltage at c t (see the attenuator control block section), which in turn controls the attenuators. the volume control setting does not affect the maximum attenuator input signal at which notice able distortion occurs. the bias current at vlc is typically 60 na out of the pin, and does not vary significantly with the vlc voltage or with v cc . dial tone detector the dial tone detector is a comparator with one side connected to the receive input (rxi) and the other input connected to v b with a 15 mv offset (see figure 3). if the circuit is in the receive mode, and the incoming signal is greater than 15 mv (10 mvrms), the comparators output will change, disabling the receive idle mode. the receive attenuator will then be at a setti ng determined solely by the volume control. the purpose of this circuit is to prevent the dial tone (which would be considered as continuous noise) from fading away as the circuit would have the tendency to swi t ch to the idle mode. by disabling the receive idle mode, the dial tone remains at the normally expected full level. figure 3. dial tone detector ag c the ag c circuit affects the circuit only in the receive mode, and only when the supply voltage (v cc ) is less than 3.5 volts. as v c c falls below 3.5 volts, the gain of the receive attenuator is reduced. the transmit path attenuation changes such that the sum of the transmit and receive gains remains constant. the purpose of this feature is to reduce the power (and current) used by the speaker when a line - powered speakerphone is connected to a long line, where the available power is limited. by reducing the speaker power, the voltage sag at v cc is controlled, preventing possible erratic operation. IL34118 201 3 , january , ver. 0 2 attenuator control block the attenuat or control block has the seven inputs described above: - the output of the comparator operated by rlo2 and tlo2 (microphone/speaker side) - designated c1. - the output of the comparator operated by rlo1 and tlo1 (tip/ring) side) - designated c2. - the outp ut of the transmit background noise monitor - designated c3. - the output of the receive background noise monitor - designated c4. - the volume control. - the dial tone detector. - the agc circuit. the single output of the control block controls the two at tenuators. the effect of c1 - c4 is as follows: inputs output c1 c2 c3 c4 mode tx tx 1 x transmit tx rx y y fast idle rx tx y y fast idle rx rx x 1 receive tx tx 0 x slow idle tx rx 0 0 slow idle rx tx 0 0 slow idle rx rx x 0 slow idle x = dont ca re; y = c3 and c4 are not both 0 a definition of the above terms: 1) transmit means the transmit attenuator is fully on (+6.0 db), and the receive attenuator is at max. attenuation ( - 46 db). 2) receive means both attenuators are controlled by the volume con trol. at max. volume, the receive attenuator is fully on (6.0 db), and the transmit attenuator is at max. attenuation ( - 46 db). 3) fast idle means both transmit and receive speech are present in approximately equal levels. the attenuators are quickly switc hed (30 ms) to idle until one speech level dominates the other. 4) slow idle means speech has ceased in both transmit and receive path. the attenuators are then slowly switched (1 second) to the idle mode. 5) switching to the full transmit or receive modes fro m any other mode is at the fast rate (30 ms). a summary of the truth table is as follows: 1) the circuit will switch to transmit if: a) both transmit level detectors sense higher signal levels relative to the respective receive level detectors (tli1 versus r li1, tli2 versus rli2), and b) the transmit background noise monitor indicates the presence of speech. 2) the circuit will switch to receive if: a) both receive level detectors sense higher signal levels relative to the respective transmit level detectors, an d b) the receive background noise monitor indicates the presence of speech. 3) the circuit will switch to the fast idle mode if the level detectors disagree on the relative strengths of the signal levels, and at least one of the background noise monitors indi cates speech. for example, referring to the expanded logic diagram (figure 8), if there is sufficient signal at the microphone amp output (tli2) to override the speaker signal (rli2), and there is sufficient signal at the receive input (rli1) to override t he signal at the hybrid output (tli1), and either or both background monitors indicate speech, then the circuit will be in the fast idle mode. two conditions which can cause the fast idle mode to occur are a) when both talkers are attempting to gain contro l of the system by talking at the same time, and b) when one talker is in a very noisy environment, forcing the other talker to continually override that noise level. in general, the fast idle mode will occur infrequently. 4) the circuit will switch to the sl ow idle mode when a) both talkers are quiet (no speech present), or b) when one talkers speech level is continuously overriden by noise at the other speakers location. the time required to switch the circuit between transmit, receive, fast idle and slow idle is determined in part by the components at the c t pin (pin 14). a schematic of the c t circuitry is shown in figure 4 and operates as follows: - r t is typically 120 k ? , and c t typically 5.0 ? f. - to switch to the receive mode, i 1 is turned on (i 2 is o ff), charging the external capacitor to +240 mv above v b . (an internal clamp prevents further charging of the capacitor.) - to switch to the transmit mode, i 2 is turned on (i 1 is off) bringing down the voltage on the capacitor to - 240 mv with respect to v b . - to switch to idle quickly (fast idle), the current sources are turned off, and the internal 2.0 k ? resistor is switched in, discharging the capacitor to v b with a time constant = 2.0 k ? x c t . - to switch to idle slowly (slow idle), the current sources are turned off, the switch at the 2.0 k ? resistor is open, and the capacitor discharges to v b through the external resistor r t with a time constant = r t x c t . IL34118 201 3 , january , ver. 0 2 figure 4. ct attenuator control block circuit microphone amplifier the mic rophone amplifier (pin 10, 11) has the non - inverting input internally connected to v b , while the inverting input and the output are pinned out. unlike most op - amps, the amplifier has an all - npn output stage, which maximizes phase margin and gain - bandwidth. this feature ensures stability at gains less than unity, as well as with a wide range of reactive loads. the open loop gain is typically 80 db (f<100 hz), and the gain - bandwidth is typically 1.0 mhz. the maximum p - p output swing is typically 1.0 volt less than v cc with an output impedance of <10 ? until cur r ent limiting is reached (typically 1.5 ma). input bias current at mci is typically 40 na out of the pin. figure 5. microphone amplifier and mute the muting function (pin 12), wh en activated, will reduce the gain of the amplifier to = - 39 db (will rmi = 5.1 k ? ) by shorting the output to the inverting input (see figure 5). the mute input has a threshold of 1.5 volt, and the voltage at this pin must be kept within the range of groun d and v cc . if the mute function is not used, the pin should be grounded. hybrid amplifiers the two hybrid amplifiers (at hto+, hto - , and hti), in conjunction with an external transformer, provide the two - to - four wire converter for interfacing to the tel ephone line. the gain of the first amplifier (hti to hto - ) is set by external resistors (gain = - r hf /r hi in figure 8), and its output drives the second amplifier, the gain of which is internally set at - 1.0. unlike most op - amps, the amplifiers have an all - npn output stage, which maximizes phase margin and gain - bandwidth. this feature ensures stability at gains less than unity, as well as with a wide range of reactive loads. the open loop gain of the first amplifier is typically 80 db, and the gain bandwidt h of each amplifier is ? 1.0 mhz. the maximum p - p output swing of each amplifier is typically 1.2 volts less than v cc with an output impedance of <10 ? until current limiting is reached (typically 8.0 ma). the output current capability is guaranteed to be a minimum of 5.0 ma. the bias current at hti is typically 30 na out of the pin. the connections to the coupling transformer are shown in the expanded logic diagram (figure 8). the block labeled zbal is the balancing network necessary to match the line imped ance. filter the operation of the filter circuit is determined by the external components. the circuit within the IL34118, from pins fi to fo is a buffer with a high input impedance (>1.0 m ? ), and a low output impedance (<50 ? ). the configuration of the external components determines whether the circuit is a high - pass filter (as shown in figure 8), a low - pass filter, or a band - pass filter. figure 6. high pass filter as a high pass filter, with the components shown in figure 6 the filter will keep out 60 hz (and 120 hz) hum which can be picked up by the external telephone lines. IL34118 201 3 , january , ver. 0 2 as a low pass filter (figure 7), it can be used to roll off the high and frequencies in the receive circuit, which aids protecting against acoustic feedback prob lems. with an appropriate choice of an input coupling capacitor to the low pass filter, a band pass filter is formed. figure 7. low pass filter power supply, v b , and chip disable the power supply voltage at v cc (pin 4) is to be betwee n 3.5 and 6.5 volts for normal operation, with reduced operation possible down to 2.8 volts. the output voltage at v b (pin 15) is ? (v cc - 0.7)/2, and provides the ac ground for the system. the output impedance at v b is ? 400 ? , and in conjunction with the e xternal capacitor at v b , forms a low pass filter for power supply rejection. since v b biases the microphone and hybrid amplifiers, the amount of supply rejection at their outputs is directly related to the rejection at v b , as well as their respective gains . the chip disable (pin 3) permits powering down the ic to conserve power and/or for muting purposes. with cd ? 0.8 volts, normal operation is in effect. with cd ? 2.0 volts and ? v cc , the ic is powered down. in the powered down mode, the microphone and the hyb rid amplifiers are disabled, and their outputs go to a high impedance state. additionally, the bias is removed from the filter (pins 1, 2), the attenuators (pins 8, 9, 21, 22), or from pins 13, 14, and 15 (the attenuators are disabled, however, and will no t pass a signal). the input impedance at cd is typically 90 k ? , has a threshold of ? 1.5 volts, and the voltage at this pin must be kept within the range of ground and v cc . if cd is not used, the pin should be grounded. pin description pin no designation description 1 fo filter output. output impedance is less than 50 ? . 2 fi filter input. input impedance is greater than 1.0 m ? . 3 cd chip disable. a logic low (<0.8 v) sets normal operation. a logic high (>2.0 v) disables the ic to conserve power. input i mpedance is nominally 90 k ? . 4 v cc a supply voltage of +2.8 to +6.5 volts is required, at ? 5.0 ma. as v cc falls from 3.5 to 2.8 volts, an agc circuit reduces the receive attenuator gain by ? 25 db (when in the receive mode). 5 hto+ output of the second h ybrid amplifier. the gain is internally set at - 1.0 to provide a differential output, in conjunction with hto - , to the hybrid transformer. 6 hto - output of the first hybrid amplifier. the gain of the amp is set by external resistors. 7 hti input and summ ing node for the first hybrid amplifier. dc level is ? v b. 8 txo output of the transmit attenuator. dc level is approximately v b . 9 txi input to the transmit attenuator. max. signal level is 350 mvrms. input impedance is ? 10 k ? . 10 mco output of the micr ophone amplifier. the gain of the amplifier is set by external resistors. 11 mci input and summing node of the microphone amplifier. dc level is ? v b . (continued) IL34118 201 3 , january , ver. 0 2 pin description pin no designation description 12 mut mute input. a logic low (<0.8 v) sets normal operation. a logic high (>2.0 v) mutes the microphone amplifier without affecting the rest of the circuit. input impedance is nominally 90 ? . 13 vlc volume control input. when vlc = v b , the receive attenuator is at maximum gain when in the rece ive mode. when vlc = 0.3 v b , the receive gain is down 35 db. does not affect the transmit mode. 14 c t an rc this pin sets the response time for the circuit to switch modes. 15 v b an output voltage ? v cc /2. this voltage is a system ac ground, and biases t he volume control. a filter cap is required. 16 cpt an rc at this pin sets the time constant for the transmit background monitor. 17 tli2 input to the transmit level detector on the mike speaker side. 18 tlo2 output of the transmit level detector on the mike/speaker side, and input to the transmit background monitor. 19 rlo2 output of the receive level detector on the mike/speaker side. 20 rli2 input to the receive level detector on the mike/speaker side. 21 rxi input to the receive attenuator and dia l tone detector. max input level is 350 mv rms. input impedance is ? 10 k ? . 22 rxo output of the receive attenuator. dc level is approximately v b . 23 tli1 input to the transmit level detector on the line side. 24 tlo1 output of the transmit level detecto r on the line side. 25 rlo1 output of the receive level detector on the line side, and input to the receive background monitor. 26 rli1 input the receive level detector on the line side. 27 cpr an rc at this pin sets the time constant for the receive ba ckground monitor. 28 gnd ground pin for the entire ic. maximum ratings * symbol parameter value unit v cc supply voltage (pin 14) - 1.0 to +7.0 v v in input voltage at cd(pin 3), mut (pin 12) - 1.0 tov cc +1.0 v v v in input voltage at vlc (pin 13) - 1.0 to v cc +0.5 v v v in input voltage at txi(pin 9), rxi (pin 21), fi (pin 2) - 0.5 tov cc +0.5 v v ptot power dissipation tamb = 60 ? c, so28 520 mw tstg storage temperature range - 65 to +150 ? c * stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. these are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. exposure to absolute - maximum - rate d conditions for extended periods may affect device reliability. IL34118 201 3 , january , ver. 0 2 recommended operating conditions symbol parameter min max unit v cc supply voltage (pin 4) 3.5 6.5 v v in input voltage at cd (pin 3), mut (pin12) 0 v cc v i vb v b current (pin 15) 500 ? a v in input voltage at vlc (pin 13) 0.3 x v b v b v v in attenuator input signal voltage (pins 9, 21) 0 350 mvrms g microphone amplifier, hybrid amplifier gain 0 40 db i l load current rxo, txo pins 8,22) mco (pin 10) hto - , hto+ (pins 6,5) 0 0 0 2.0 1.0 5.0 m a t a operating temperature - 25 +70 ? c this device contains protection circuitry to guard against damage due to high static voltages or electric fields. however, precautions must be taken to avoid applications of any voltage higher than maximum rated volt ages to this high - impedance circuit. for proper operation, v in and v out should be constrained to the range gnd ? (v in or v out ) ? v cc . unused inputs must always be tied to an appropriate logic voltage level (e.g., either gnd or v cc ). unused outputs must be left open. electrical characteristics (t a = - 25 to +70 ? c, v cc = 5.0 v, cd = 0.8 v, unless noted) symbol parameter test conditions guaranteed limits unit min max power supply i cc v cc su pply current v cc =6.5 v, cd =0.8 v v cc =6.5 v, cd =2.0 v - - 10 1.0 ma r cd cd input resistance v cc = v cd = 6.5 v 37.5 - kk ? v cdh cd input high voltage v cc = v cd = 6.5 v 2.0 v cc v v cdl cd input low voltage v cc = v cd = 6.5 v 0 0.8 v v b v b output voltage 1.35 3.0 v attenuator (vlc = v b , unless noted) g rx g r x ? g rx1 * ? g rx2 * g rx1 ? g rx3 * receive attenuator gain ( f =1.0 khz) rx mode, rxi=150 mvrms, (v cc =5.0 v) rx mode, rxi=150 mvrms (v cc =3.5 v) gain change - v cc =3.5 v versus v cc =5.0 v agc gain change - v cc =2.8 v versus v cc =5.0 v idle mode, rxi=150mvrms ra nge (rx to tx mode) 1.5 1.5 - 0.5 - - 25 49 10.0 10.0 +0.5 - 15 - 15 54 db v cr * volume control range rx mode, 0.3v b IL34118 201 3 , january , ver. 0 2 electrical characteristics (t a = - 25 to +70 ? c, v cc = 5.0 v , cd = 0.8 v, unless noted) symbol parameter test conditions guaranteed limits unit min max hybrid amplifiers h vos hto - offset v hto - - v b , feedback r= 51 k ? v b - 25 v b +25 mv hb vos hto - to hto+ offset feedback r= 51 k ? v b - 37 v b +37 mv a volh open loop gain hti to hto - , f = 100 hz, v hti = 20 mv 57 - db a vclh closed loop gain hto - to hto+ - 2.8 2.2 db v ht - h hto - high voltage i o ut = - 5.0 ma, v hti =v b - 1.0 v 2.8 - v v ht - l hto - low voltage i out =5.0 ma, v hti =v b +1.5 v - 375 mv v ht+h hto+ high voltage i out = - 5.0 ma,v hti =v b +1.5 v 2.8 - v v ht+l hto+ low voltage i out =5.0 ma, v hti =v b - 1.0 v - 562 mv level detectors and background nois e monitors i th * transmit - rece i ve switching threshold ratio of current at rli1 + rli2 to 20 ? a at tli1 + tli2 to switch from tx to rx 0.8 1.2 filter fo vos voltage offset at fo v fo - v b , 220 k ? from v b to fi v b - 250 v b +25 mv i fo fo sink current v b = v fo , v fi = 0 v 112 500 ? a note. 1. all currents into a device pin are positive, those out of a pin are negative. algebraic convention rather than magnitude is used to define limits. * @25 ? c IL34118 201 3 , january , ver. 0 2 figure 8. expanded logic diagram technical data 201 3 , january , ver. 0 2 figure 9. IL34118 application circuit (basic line powered speakerphone) 220pf 51k 1.0 k 0.2 0.1 0.1 5.1 k 10 9 8 10 k 5.1 k 5.1 k txo tli1 0.1 0.1 820 300 0.05 hti hto- hto+ r r 5 0.01 hook switch tip ring dis- able 1000 f (note 3) ? 1n4733 5.1 v 4 3 24 27 25 28 fi 1 fo rli1 26 13 dtd agc 20 22 21 vlc volume control 1) these two resistors depend on the specific microphone selected. 2) component values shown are recommendations only, and will vary in different applications. 3) this capacitor must be physically adjacent to pin 4 of the IL34118. 4) bnm - background noise monitor; dtd = dial tone detector. 5) recommended transformer: stancor ttpc-13, microtran t5115. 6) capacitor values are in f unless otherwise noted. ? rli2 220 f ? 5.0 f ? 47 f ? 120 k rlo2 19 16 cpt 18 mut tlo2 12 mute 2.0 f ? 100 k 2.0 f ? 14 15 rxo rxi + 1 220 k 56 k 9.1 k 5.1 k 200 pf 110 k 10 k 0.05 0.1 4 3 1 6 7 il34119 IL34118 8 5 25 speaker (300 mw) ? r r 20 k 10 k 0.05 0.1 cd tlo1 2.0 f ? 2.0 f ? 100 k 47 f ? 4700pf 4700pf cpr rlo1 gnd 2 filter 23 7 6 txi attenuator attenuator attenuator control bnm bnm 17 tli2 11 + + + + + + + + + + - - - - - - - - - - 5.1 k 0.02 180 k (note1) mike 620 20 f ? 220 f ? v c c v b v b v b r h i v b v b v b v b v b v b v b v b v c c v c c c t v b v c c v c c v c c v b r m i r m f r h f IL34118 201 3 , january , ver. 0 2 n suffix plastic dip (ms - 001ab) symbol min max a 35.10 39.70 b 12.32 14.73 c 6.35 d 0.36 0.56 f 0.77 1.78 g h j 0 ? ? k 2.92 5.08 notes: l 15.24 15.87 1. ???? dimensions a, b do not include mold flash or protrusions. m 0.20 0.38 maximum mold flash or protrusions 0.25?mm (0.010) per side. n 0.38 d suffix soic (ms - 059ad) symbol min max a 17.70 18.50 b 7.40 7.60 c 2.35 3.05 d 0.35 0.50 f 0.40 1.27 g h notes: j 0 ? ? 1. ???? dimensions a and b do not include mold flash or protrusion. k 0.05 0.35 2. ???? maximum mold flash or protrusion 0.15?mm (0.006) per side m 0.14 0.32 for a; for b ? 0.25?mm (0.010) per side. p 10.00 10.65 r 0.25 0.75 1.27 11.43 dimension, mm dimension, mm 2.54 15.24 a b c k c m j f m p h g d r x 45 seating plane 0.25 (0.010) m t -t- 1 28 14 15 l h m j a b f g d seating plane n k 0.25 (0.010) m t -t- c 1 28 14 15 |
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