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| BL34018 1. GENERAL DESCRIPTION The BL34018 Speakerphone integrated circuit Incorporates the necessary amplifiers attenuators and control functions to produce a high quality hands free speakerphone system Include are a microphone amplifier power audio amplifier for the speaker a transmit and receive attenuatorsa monitoring system for background sound leveland an attenuation control system which responds to the relative transmit and receive levels as well as the background levelAlso included are all necessary regulated voltages for both internal and external circuitry allowing line-powered operation (no additional power supplies required)A chip select pin allows the chip to be powered down when not in useA volume control function may be implemented with an external potentiometerBL34018 applications include speakerphones for household and business useintercom systemsautomotive telephonesand others 2. FEATURE Voice switched speakerphone circuit. All necessary level detection and attenuation controls for a hand-free telephone included. Background noise level monitoring with long time constant. Background sound level compensation for transmit and receive levels as well as the background level. Wide operating dynamic range through signal compression. On-chip supply and reference voltage regulation. Power audio amplifier for typical 100mW output (into 25 ohms) with peak limiting for speaker to minimize distortion. Chip Select pin for active/stand by operation. Linear Volume Control Function. 3. BLOCK DIAGRAM http://www.belling.com.cn -1Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 4. PIN CONFIGURATIONS Pin 1 2 Name RR RTX Description A resistor to ground provides a reference current for the transmit and receive attenuators. A resistor to ground determines the nominal gain of the transmit attenuator. The transmit channel gain is inversely proportional to the RTX resistance. Input to the transmit attenuator. Input resistance is nominally 5.0 k ohms. Output of the transmit attenuator. The TXO output signal drives the input of the transmit level detector, as well as the external circuit which drives the telephone line. Input of the transmit level detector. An external resistor ac coupled to the TLI pin sets the detection level. Decreasing this resistor increases the sensitivity to transmit channel signals. Output of the transmit level detector. The external resistor and capacitor set the time the comparator will hold the system in the transmit mode after speech ceases. Input of the receive level detector. An external resistor ac coupled to the RLI pin sets the detection level. Decreasing this resistor increases the sensitivity to receive channel signals. Output of the receive level detector. The external resistor and capacitor set the time the comparator will hold the system in the receive mode after speech ceases. Microphone amplifier input. Input impedance is nominally 10 k ohms and the dc bias voltage is approximately equal to VB. Microphone amplifier output. The mic amp gain is internally set at 34 dB (50V/V). A parallel resistor and capacitor connected between this pin and VCC holds a voltage corresponding to the background noise level. The transmit detector compares the CP1 voltage with the speech signal from CP2. A capacitor at this pin peak detects the speech signals for comparison with the background noise level held at CP1. Input to the transmit detector system. The microphone amplifier output is ac coupled to the XDI pin through an external resistor. High current ground pin for the speaker amp output stage. The SKG voltage should be within 10 mV of the ground voltage at Pin 22. Speaker amplifier output. The SKO pin will source and sink up to 100 mA when ac coupled to the speaker. The speaker amp gain is internally set at 34 dB (50V/V). Input dc supply voltage. V+ can be powered from Tip and Ring if an ac decoupling inductor is used to prevent loading ac line signals. The required V+ voltage is 6.0 to 11 V (7.5 V nominal) at 7.0 mA. A capacitor from this pin to VB stabilizes the speaker amp gain control loop and 3 4 TXI TXO 5 TLI 6 7 TLO RLI 8 9 RLO MCI 10 11 MCO CP1 12 CP2 13 14 XDI SKG 15 16 SKO V+ 17 AGC http://www.belling.com.cn -2Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 additionally controls the attack and decay time of this circuit. The gain control loop limits the speaker amp input to prevent clipping at SKO. The internal resistance at the AGC pin is nominally 110 k ohms. 18 CS Digital chip select input. When at a logic "0" (<0.7 V) the VCC regulator is enabled. When at a logic "1" (>1.6 V), the chip is in the standby mode drawing 0.5 mA. An open CS pin is a logic "0". Input impedance is nominally 140 k ohms. The input voltage should not exceed 11 V. 19 20 SKI VCC Input to the speaker amplifier. Input impedance is normally 20 k ohms. A 5.4 V regulated output which powers all circuits except the speaker amplifier output stage. VCC can be used to power external circuitry such as a microprocessor( 3.0 mA max). A filter capacitor is required. The BL34018 can be powered by a separate regulated supply by connecting V+ and VCC to a voltage between 4.5 V and 6.5 V while maintaining CS at a logic "1". 21 VB An output voltage equal to approximately VCC/2 which serves as an analog ground for the speakerphone system. Up to 1.5 mA of external load current may be sourced from VB. Output impedance is 250 ohms. A filter capacitor is required. Ground pin for the IC (except the speaker amplifier). Gnd 22 23 XDC Transmit detector output. A resistor and capacitor at this pin hold the system in the transmit mode during pauses between words and phrases. When the XDC pin voltage decays to ground the attenuators switch from the transmit mode to the idle mode. The internal resistor at XDC is nominally 2.6 k ohms. Volume control input. Connecting this pin to the slider of a variable resistor provides receive mode volume control. The VLC pin voltage should be less than or equal to VB. Attenuator control filter. A capacitor connected to this pin reduces noise transients as the attenuator control switches levels of attenuation. Output of the receive attenuator. Normally this pin is ac coupled to the input of the speaker amplifier. Input of the receive attenuator. Input impedance is nominally 5.0 k ohms. A resistor to ground determines the nominal gain of the receive attenuator. The receive channel gain is directly proportional to the RRX resistance. 24 VLC 25 ACF 26 27 28 RXO RXI RRX http://www.belling.com.cn -3Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 5. ELECTRICAL CHARACTERISTICS (Refer to Figure 1) ABSOLUTE MAXIMUM RATINGS (voltages referred to Pin 22) (TA = 25C) Parameter V+ Terminal Voltage (Pin 16) Value +12, -1.0 +12, -1.0 +3.0, -1.0 VCC, -1.0 -65 to +150 Units V V V V C CS (Pin 18) Speaker Amp Ground (Pin 14) VLC (Pin 24) Storage Temperature "Maximum Ratings"are those values beyong which the safety of the device cannot be guaranteed, They are not meant to imply that the devices should be operated at these limits. The "Electrical Characteristics" tables provide conditions for actual device operation. RECOMMENDED OPERATING CONDITIONS Parameter V+ Terminal Voltage (Pin 16) Value +6.0 to +11 0 to +11 0 to 3.0 0.55VB to VB 0 to 250 0 to 5.0 -10 to +10 -20 to +60 Units V V mA V mVrms mVrms mVdc C CS (Pin 18) ICC (Pin 20) VLC (Pin 24) Receive Signal (Pin 27) Microphone Signal (Pin 9) Speaker Amp Ground (Pin 14) Ambient Temperature ELECTRICAL CHARACTERISTICS Parameter SUPPLY VOLTAGES V+ Supply Current V+ = 11V, Pin 18 = 0.7V V+ = 11V, Pin 18 = 1.6V VCC Voltage ( V+ = 7.5V) Line Regulation (6.5V< V+ <11V) Symbol IV+ Pin 16 Min Typ Max Units --VCC VCC LN 20 4.9 -- --5.4 65 9.0 800 5.9 150 mA uA Vdc mV http://www.belling.com.cn -4Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 Output Resistance (ICC = 3.0 mA) Dropout Voltage ( V+ = 5.0 V) VB Voltage (V+ = 7.5V) Output Resistance ( IB = 1.7 mA) ATTENUATORS Receive Attenuator Gain (@1.0 kHz) RX Mode, Pin 24 = VB; Pin 27 = 250 mVrms Range ( RX to TX Modes) Idle Mode, Pin 27 = 250 mVrms RXO Voltage ( RX Mode) Delta RXO Voltage (Switch from RX to TX Mode) RXO Sink Current (RX Mode) RXO Source Current (RX Mode) RXI Input Impedance Volume Control Range ( RX Attenuator Gain, RX Mode, 0.6VB < Pin 24 < VB) Transmit Attenuator Gain (@1.0 kHz) TX Mode, Pin 3 = 250 mVrms Range ( TX to RX Mode) Idle Mode, Pin 3 = 250 mVrms TXO Voltage ( TX Mode) Delta TXO Voltage (Switch from TX to RX Mode) TXO Sink Current (TX Mode) TXO Source Current (TX Mode) TXI Input Impedance ACF Voltage (VCC - Pin 25 Voltage) RX Mode Tx Mode Idle Mode SPEAKER AMPLIFIER Speaker Amp Gain (Pin19 = 20mVrms) SKI Input Impedance SKO Voltage ( Pin 19 = Cap Coupled to GND) SKO High Voltage (Pin 19 = 0.1V, -100 mA load at Pin 15) GSPK RSKI VSKO VSKOH 15, 9 33 15 2.4 5.5 34 22 3.0 -35 37 3.6 -dB k Vdc Vdc GRX GRX GRXI VRXO VRXO IRXOL IRXOH RRXI VCR GTX GTX GTXI VTXO VTXO ITXOL ITXOH RTXI VACF 20, 25 75 1.0 3.5 3, 4 26, 27 2.0 40 -20 1.8 -75 1.0 3.5 24.5 4.0 40 -16.5 1.8 -6.0 44 -16 2.3 ---5.0 -6.0 44 -13 2.3 ---5.0 150 6.0 75 10 48 -12 3.2 100 -3.0 8.0 32.5 8.0 48 -8.5 3.2 100 -3.0 8.0 ---dB dB dB Vdc mV uA mA k dB dB dB dB Vdc mV uA mA k mV mV mV ROVCC VCCSAT VB ROVB 21 --2.5 -6.0 80 2.9 250 20 300 3.3 -ohm mV Vdc ohm ---- http://www.belling.com.cn -5Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 SKO Low Voltage ( Pin 19 = -0.1V, +100 mA load at Pin 15) MICROPHONE AMPLIFIER Mike Amp Gain (Pin 9 = 10mVrms , 1.0 kHz) Mike Amp Input Resistance LOGAMPS RLO Leakage Current (Pin 8 = VB + 1.0V) TLO Leakage Current (Pin 6 = VB + 1.0V) Transmit -Receive Switching Threshold ILKRLO ILKTLO ITH 8 6 5,7 25 --0.8 ---2.0 2.0 1.2 uA uA GMCI RMCI 9, 10 32.5 6.5 34 10 35 16 dB k VSKOL --600 mV ( Ratio of ITLI to IRLI - at 20 uA - to switch TX-RX Comparator) TRANSMIT DETECTOR XDC Voltage -- Idle Mode -- TX Mode CP2 Current Source DISTORTION RX Mode - RXI to SKO (Pin 27 = 10mVrms ,1.0kHz) TX Mode - MCI to TXO (Pin 9 = 5.0mVrms ,1.0kHz) NOTES: 1. 2. V+ = 7.5V, CS = 0.7V except where noted. TXD ICP2 VXDC 23 --- 0 4.0 10 --13 Vdc Vdc uA % % 12 5.0 RXD 27, 15 4,9 -- 1.5 -- -- 2.0 -- RX Mode : Pin 7 = -100 uA, Pin 5 = +100 uA, except where noted. TX Mode : Pin 5,13 = -100 uA, Pin 7 = +100 uA, Pin 11 = 0V. Idle Mode: Pin 5 = -100 uA, Pin 7, 13 = +100 uA. 3. Current into a pin designated as +; current out of a pin designated as - . 4. Voltages referred to Pin 22. TA = +25C. TEMPERATURE CHARACTERISTICS (-20 to 60C) Parameter Pin Typical Change Units %/C %/C %/C dB/c V+ Supply Current (V+ = 11V, Pin 18 = 0.7V) V+ Supply Current (V+ = 11V, Pin 18 = 1.6V) VCC Voltage ( V+ = 7.5V) Attenuator Gain ( Max and Min Settings) 16 16 20 -0.2 -0.4 +0.1 0.003 http://www.belling.com.cn -6Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 Delta RXO, TXO Voltages Speaker Amp Gain Microphone Amp Gain Microphone Amp Input Resistance Tx - Rx Switching Threshold (@ 20 uA) 4,26 15,19 9,10 9 5,7 0.24 0.003 0.001 +0.4 0.2 %/C dB/c dB/c %/c nA/c 6. DESIGN GUIDELINES(REF TO FIG. 1) ATTENUATORS The transmit and receive attenuators are complementary in function, i.e., when one is at maximum gain the other is at maximun attenuation, and vice versa. They are never both on or both off. Their main purpose is to control the transmit and receive paths to provide the half-duplex operation required of a speakerphone. The attenuators are controlled safely by the voltage at the ACF pin. The ACF voltage is provided by the Attenuator Control block, which receives 3 inputs:a) the TX - RX Comparator, b) the Transmit Detector Comparator, and c) the Volume Control. The response of the attenuators is based on the difference of the ACF voltage from VCC (referred to as Vacf). If Vacf is approximately 6mV the transmit attenuator is fully on and the receive attenuator is fully off( transmit mode). If Vacf is approximately 150mV the circuit is in the receive mode. If Vacf is approximately 75mV, the circuit is in the idle mode, and the two attenuators are at gain settings approximately half way (in dB) between their fully on and fully off positions. The maximum gain and attenuation values are determined by the three external resistors RR, RTX, and RRX. RR affects both attenuators according to its value RELATIVE to RTX and RRX. RTX affects the gain and attenuation of only the transmit attenuator, while RRX affects the gain and attenuation of only the receive attenuator. A value of 30 k is recommended for RR as a starting point, and then RTX and RRX selected to suit the particular design goals. The input impedance of the attenuators (at TXI and RXI) is typically 5.0 k, and the maximum input signal which will not cause output distortion is 250 mVrms(707 mVP-P). The 4300 ohm resistor and 0.01 uF capacitor at RXO (in Figure 1) filters out high frequency components in the receive path. This helps minimize high frequency acoustic feedback problems. The filter's insertion loss is 1.5 dB at 1.0 kHz. The outputs of the attenuators are inverted from their inputs. Referring to the attenuator control block, the Vacf voltage at its output is determined by three inputs. The relationship of the inputs and ouput is summarized in the following truth table: Tx - Rx Comp Transmit Transmit Receive Receive Transmit Det Comp Transmit Idle Transmit Idle No Effect No Effect Affects Vacf Affects Vacf 6.0 mV 75 mV 50 - 150 mV 50 - 150 mV Transmit Idle Receive Receive Volume Control Vacf Mode http://www.belling.com.cn -7Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 As can be seen from the truth table, the Tx-Rx comparator dominates. The Transmit Detector Comparator is effective only in the transmit mode, and the Volume Control is effective only in the receive mode. The Tx-Rx comparator is in the transmit position when there is sufficient transmit signal present over and above any receive signal. The Transmit Detector Comparator then determines whether the transmit signal is a result of background noise ( a relatively stable signal) or speech which consists of bursts. If the signal is due to background noise, the attenuators will be put into the idle mode (Vacf = 75 mV). If the signal consists of speech, the attenuators will be switched to the transmit mode (Vacf = 6.0 mV.) A further explanation of this function will be found in the section on the transmit detector circuit. The Tx-Rx comparator is in the receive position when there is sufficient receive signal to overcome the background noise AND any speech signals. The Vacf will now be 150 mV IF the volume control is at the maximum position, i.e. VLC (Pin 24) = VB. If VLC is less than VB, the gain of the receive attenuator, and the attenuation of the transmit attenuator, will vary in a complementary manner. At the minimum recommended operating level (VLC = 0.55VB) the gain of the tranmit attenuator is actually greater than that of the receive atttenuator, although it is at receive mode. The effect of varying VLC is to vary Vacf, with a resulting variation in the gains of the attenuators. The capacitor at ACF (Pin 25) smooths the transition between operating modes. This keeps down any "clicks" in the speaker or transmit signal when the ACF voltage switches. The gain separation of the two attenuators can be reduced from the typical 45 dB by adding a resistor between Pins 20(VCC ) and 25(ACF). The effect is a reduction of the maximum Vacf voltage in the receive mode, while not affecting Vacf in the transmit mode. LOGAMPS (Transmit and Receive Level Detectors) The log amps monitor the levels of the transmit and receive signals, so as to tell the Tx-Rx comparator which mode should be in effect. The input signals are applied to the amplifiers (at TLI and RLI) through AC coupling capacitors and current limiting resistors. The value of these components determines the sensitivity of the respective amplifiers, and has an effect on the switching times between tranmit and receive modes. The feedback elements for the amplifiers are back-to-back diodes which provide a logarithmic gain curve. The outputs of the amplifiers are rectified, having a quick rise and a slow decay time. The rise time is determined primarily by the external capacitor and an internal 500 ohm resistor, and is on the order of a fraction of 1 ms. The decay time is determined by the external resistor and capacitor, and is on the order of a fraction of 1 s. The switching time is not fixed, but depends on the relative values of the transmit and receive signals, as well as these external components. The Tx-Rx comparator responds to the voltages at TLO and RLO, which in turn are functions of the currents sourced out of TLI and RLI, respectively. If an offset at the comparator input is desired, e.g., to prevent noise from switching the system, or to give preference to either the transmit or receive channel, this may be achieved by biasing the appropriate input (TLI or RLI). A resistor to ground will cause a DC current to flow out of that input, thus forcing the output of that http://www.belling.com.cn -8Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 amplifier to be biased slightly higher than normal. This amplifier then becomes the preferred one in the system operation. Resistor values from 500 k to 10 M ohms are recommended for this purpose. SPEAKER AMPLIFIER The speaker amplifier has a fixed gain of 34 dB (50V/V), and is noninverting. The input impedance is nominally 22 k as long as the output signal is below that required to activate the Peak Limiter. Since the output current capability is 100 mA, the output swing is limited to 5.0VPP while load is 25 ohms. The output impedance depends on the output signal level and is relatively low as long as the signal level is not near the maximum limits. At 3 VPP, it is < 0.5 ohms, and at 4.5 VPP, it is < 3 ohms. The output is short circuit protected at approximately 300 mA. When the amplifier is overdriven, the peak limiter causes a portion of the input signal to be shunted to ground, in order to maintain a constant output level. The effect is that of a gain reduction caused by a reduction of the input impedance (at SKI) to a value not less than 2.0 k. The capacitor at Pin 17 (AGC) determines the response time of the peak limiter circuit. When a large input signal is applied to SKI, the voltage at AGC will drop quickly as a current source is applied to the external capacitor. When the large input signal is reduced, the current source is turned off, and an internal 110 k resister discharges the capacitor so the voltage at AGC can return to its normal value (1.9 Vdc). The capacitor additionally stabilizes the peak limiting feedback loop. If there is a need to mute the speaker amplifier without disabling the rest of the circuit, this may be accomplished by connecting a resistor from the AGC pin to ground. A 100 k resister will reduce the gain by 34 dB (0 dB from SKI to SKO), and a 10 k resister will reduce the gain by almost 50 dB. TRANSMIT DETECTOR CIRCUIT The transmit detector circuit, also known as the background noise monitor, distinguishes speech (which consists of bursts) from the background noise ( a relatively constant signal). It does this by storing a voltage level, representative of the average background noise, in the capacitor at CP1( Pin 11). The resistor and capacitor at this pin have a time constant of approximately 5 seconds(in Figure 1). The voltage at Pin 11 is applied to the inverting input of the Transmit Detector Comparator. In the absence of speech signals, the noninverting input receives the same voltage level minus an offset of 36 mV. In this condition, the output of the comparator will be low, the output transistor turned off, and the voltage at XDC (Pin 23) will be at ground. If the Tx-Rx comparator is in the transmit position, the attenuators will be in the idle mode ( Vacf = 75 mV). When speech is presented to the microphone, the signal burst appearing at XDI reaches the noninverting input of the transmit detector comparator before the voltage at the inverting input can change, causing the output to switch high, driving the voltage at XDC up to approximately 4 V. This high level causes the attenuator control block to switch the attenuators from the idle mode to the transmit mode (assuming the Tx-Rx comparator is in the transmit mode). The series resistor and capacitor at XDI (Pin 13) determine the sensitivity of the transmit detector circuit. Increasing the resistor, or lowering the capacitor, will reduce the response at CP2 and CP1. http://www.belling.com.cn -9Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 The response at CP2, CP1, XDC to a varying signal at the microphone is as follows: 1. CP2 ( Pin 12) follows the peaks of the speech signals, and decays at a rate determined by the 10 uA current source and the capacitor at CP2. 2. CP1 (Pin 11) increases at a rate determined by the RC at this pin after CP2 has made a positive transition. It will follow the decay pattern of CP2. 3. The noninverting input of the Transmit Detector Comparator follows CP2, gained up by 2.7, and reduced by an offset 36 mV. This voltage, compared to CP1, determines the output of the comparator. 4. XDC (Pin 23) will rise quickly to 4 Vdc in response to a positive transition at CP2, but will decay at a rate determined by the RC at this pin. When XDC is above 3.25 Vdc, the circuit will be in the transmit mode. As it decays towards ground, the attenuators are taken to idle mode. MICROPHONE AMPLIFIER The microphone amplifier is noninverting, has an internal gain of 34 dB(50 V/V), and a nominal input impedance of 10 k. The output impedance is typically < 15 ohms. The maximum p-p voltage swing available at the output is approximately 2.0 V less than VCC, which is substantially more than what is required in most applications. The input at MCI(Pin 9) should be ac coupled to the microphone so as to not upset the bias voltage. Generally, microphone sensitivity may be adjusted by varying the 2 k microphone bias resistor, rather than by attempting to varying the gain of the amplifier. POWER SUPPLY The voltage supply at V+ (Pin 16) should be in the range of 6.0 to 11 V, although the circuit will operate down to 4.0 V. The voltage can be supplied either from Tip and Ring, or from a separate supply. It is imperative that the V+ supply be a good ac ground for stability reasons. If it is not well filtered (by a 1000 uF capacitor AT THE IC), any variation at V+ caused by the required speaker current flowing through this pin can cause a low frequency oscillation. The result is usually that the circuit will cut the speaker signal on and off at the rate of a few hertz. VCC VCC (Pin 22) is a regulated output voltage of 5.4 0.5 V. Regulation will be maintained as long as V+ is (typically) 80 mV greater than the regulated value of VCC. Up to 3 mA can be sourced from this supply for external use. The output impedance is < 20 ohms. The 47 uF capacitor connecting to this pin is essential for stability reasons. The capacitor must be located adjacent to the IC.If the circuit is deselected, the VCC will go to 0 V. VB VB is a regulated output voltage with a nominal value of 2.90.4 V. It is derived from VCC and tracks it, holding a value of approximately 54% of VCC. 1.5 mA can be sourced from this supply at a typically output impedance of 250 ohms. The 47 uF capacitor connecting to this pin is essential for stability reasons. The capacitor must be ocated adjacent to the IC. If the circuit is deselected, the VB will go to 0 V. CHIP SELECT The CS pin (Pin 18) allows the chip to be powered down anytime its functions are not http://www.belling.com.cn - 10 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 required. A logic "1" level in the range of 1.6 V to 11 V deselects the chip. The input resistance at Pin 18 is > 75 k. The VCC and VB regulated voltages go to 0.0 when the chip is deselected. Leaving Pin 18 open is equivalent to a Logic "0" (chip enabled). http://www.belling.com.cn - 11 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 http://www.belling.com.cn - 12 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 http://www.belling.com.cn - 13 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 SWITCHING TIME The switching times of the speakerphone circuit depends not only on the various external components, but also on the operating conditions of the circuit at the time a change is to take effect. For example, the switching time from idle to transmit is generally quicker than the switching time from receive to transmit ( or transmit to receive). The components which most significantly affect the timing between the transmit and receive modes are those at Pins 5 (transmit turn-on), 6 (transmit turn-off), 7 (receive turn-on), and 8 (receive turn-off). These four timing functions are not independent, but interactive since the Tx-Rx comparator operates on a RELATIVE Tx-Rx comparison, rather than on absolute values. The components at Pins 11, 12, 13 and 23 affect the timing from the transmit mode to the idle mode. Timing from the idle mode to transmit mode is relatively quick ( due to the quick charging of the various capacitors), and is not greatly affected by the component values. Pins 5-8 do not affect the idle-to-transmit timing since the Tx-Rx comparator must already be in the transmit mode for this to occur. The following table provides a summary of the effect on the switching time of the various components, including the volume control: Components RC @ Pin 5 RC @ Pin 6 RC @ Pin 7 RC @ Pin 8 RC @ Pin 11 C @ Pin 12 RC @ Pin 13 RC @ Pin 23 V@ Pin 24 C@ Pin 25 Tx to Rx Moderate Significant Significant Moderate No Effect No Effect No Effect No Effect No Effect Moderate Rx to Tx Significant Moderate Moderate Significant Slight Slight Slight Slight Moderate Moderate Tx to Idle No Effect No Effect No Effect No Effect Moderate Significant Slight Significant No Effect Slight http://www.belling.com.cn - 14 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 Additionally, the following should be noted: 1) The RCs at Pins 5 and 7 have a dual function in that they affect the sensitivity of the respective log amplifiers, or in other words, how loud the speech must be in circuit. 2) The RC at Pin 13 also has a dual function in that it determines the sensitivity of circuit. 3) The volume control affects the switching speed, and the relative response to transmit signals, in the following manner: When the circuit is in the increases the signal at receive mode, reducing the volume control setting signal low volume settings. TXO, and consequently the signal to the TLI pin. Therefore a given the transmit detector order to get control of the speakerphone at TXI will switch the circuit into the transmit mode quicker at APPLICATIONS INFORMATION The BL34018 speakerphone IC is designed to provide the function additionally required when a speakerphone is added to a standard telephone. The IC provides the necessary relative level detection and comparison of the speech signals provided by the talkers at the speakerphone(near end speaker) and at the distant telephone(far end speaker). The BL34018 is designed for use with an electorate type microphone a 25 ohms speaker, and has an output power capability of 100mW.All external components surrounding this device are passive, however, this IC does require additional circuitry to interface the TIp and Ring telephone lines. Two suggested circuits are shown in the data sheet. Fig 16 depicts a configuration which does not include a handset, dialer, or ringer. The only controls are S1(to make the connection to the line),S2(a "privacy" switch),and the volume control. It is meant to be used in parallel with a normal telephone which has dialing and ringing functions. Fig 17 depicts a means of providing logic level signal that indicate which mode of operation the BL34018 is in. Comparator A indicates whether the circuit is in receive or transmit mode and comparator B indicates(when in transmit/idle mode) whether the circuit is in the transmit or idle mode. The LM393 dual comparator is chosen because of its low current requirement (<1.0mA), low voltage requirement (as low as 2.0volts), and low cost . http://www.belling.com.cn - 15 Total 16 Pages 8/15/2006 Wrote by 2006 BL34018 http://www.belling.com.cn - 16 Total 16 Pages 8/15/2006 Wrote by 2006 |
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