Order this document by MC33219A/D The Motorola MC33219A 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 mute, transmit and receive attenuators, a background monitoring system for both the transmit and receive paths, and level detectors for each path. An AGC system reduces the receive gain on long lines where loop current and power are in short supply. A dial tone detector prevents fading of dial tone. A Chip Disable pin permits conserving power when the circuit is not in use. The volume control can be implemented with a potentiometer. The MC33219A can be operated from a power supply, or from the telephone line, requiring typically 3.2 mA. It can be used in conjunction with a variety of speech networks. Applications include not only speakerphones, but intercoms and other voice switched devices. The MC33219A is available in a 24 pin narrow body DIP, and a wide body SOIC package. • Supply Voltage Range: 2.7 to 6.5 V • • • • • • • • • • VOICE SWITCHED SPEAKERPHONE CIRCUIT SEMICONDUCTOR TECHNICAL DATA 24 1 P SUFFIX PLASTIC PACKAGE CASE 724 Attenuator Range: 53 dB 24 Background Noise Monitor for Each Path 2 Point Signal Sensing 1 DW SUFFIX PLASTIC PACKAGE CASE 751E Volume Control Range: Typically 40 dB Microphone and Receive Amplifiers Pinned Out for Flexibility Microphone Amplifier can be Muted Mute and Chip Disable are Logic Level Inputs Chip Deselect Pin Powers Down the Entire IC PIN CONNECTIONS Ambient Operating Temperature: –40 to + 85°C 24 Pin Narrow Body (300 mil) DIP and 24 Pin SOIC CP2 1 24 VCC XDI 2 23 TAO CPT 3 22 TAI TLI 4 21 MCO TLO 5 20 MCI VB 6 19 VLC CT 7 18 MUTE CD 8 17 RXI NC 9 16 RXO CPR 10 15 RAI RLI 11 14 RAO RLO 12 13 GND Simplified Block Diagram Transmit Out Microphone Mute VB Tx Attenuator VB BNM Attenuator Control BNM Vol Cont DTD CD VCC VB Speaker Speaker Amplifier (Top View) VB Rx Attenuator Reg. VB ORDERING INFORMATION MC33219A Receive In This device contains 384 active transistors. Device MC33219ADW MC33219AP Operating Temperature Range TA = – 40° to +85°C Package SOIC Plastic DIP Motorola, Inc. 1995 MOTOROLA ANALOG IC DEVICE DATA 1 MC33219A MAXIMUM RATINGS Rating Symbol Min Max Unit VCC – 0.5 7.0 Vdc Vin – 0.4 VCC + 0.4 Vdc TJ – +150 °C Tstg – 65 +150 °C Supply Voltage Any Input Maximum Junction Temperature Storage Temperature Range NOTE: Devices should not be operated at or outside these values. The “Recommended Operating Conditions” provide for actual device operation. RECOMMENDED OPERATING CONDITIONS Characteristic Symbol Min Typ Max Unit VCC 3.5 2.7 – – 6.5 3.5 Vdc Maximum Attenuator Input Signal Vin(max) – – 300 mVrms Volume Control Input (Pin 19) VINVLC VB – 1.1 – VB Vdc 0 2.0 – – 0.8 VCC Supply Voltage (Non–AGC Range) (AGC Range) Logic Input Voltage (Pins 8, 18) Low High VINL Vdc Operating Temperature Range TA – 40 – 85 °C VB Output Current (VCC = 5.0 V) IVB – See Figure 12 – mA Unit ELECTRICAL CHARACTERISTICS (TA = 25°C, VCC = 5.0 V, CD ≤ 0.8 V, unless noted. See Figure 2.) Characteristic Symbol Min Typ Max 2.0 – – 3.2 4.2 4.0 5.0 – – – 50 – 65 110 145 – 170 – – 2.1 – 0.9 2.2 3.0 – 2.3 – POWER SUPPLY Supply Current (Enabled, CD ≤ 0.8, VB Open) Idle Mode Tx Mode Rx Mode ICCE Supply Current (Disabled, CD = 2.0 V, VB Open) VCC = 3.0 V VCC = 5.0 V VCC = 6.5 V ICCD VB Output Voltage (IVB = 0, CD = 0) VCC = 2.7 V VCC = 5.0 V VCC = 6.5 V mA µA VB Vdc VB Output Resistance (IVB ≤ –1.0 mA) ROVB – 600 – Ω PSRR @ VB versus VCC, f = 1.0 kHz, CVB = 100 µF PSRR – 57 – dB – – – 150 0 – 100 – – – ATTENUATOR CONTROL CT Voltage (with Respect to VB) Rx Mode (VLC = VB) Idle Mode Tx Mode VCT – VB mV CT Source Current (Switching to Rx Mode) ICTR –110 –90 –70 µA CT Sink Current (Switching to Tx Mode) ICTT 35 50 65 µA CT Idle Current ICTI – 3.0 0 3.0 µA Dial Tone Detector Threshold (with Respect to VB at RAI) VDT – 40 – 20 – 8.0 mV VLC Input Current @ VLC = VB VLC = VB – 1.0 V IVLC – –8.0 0 –6.0 – –3.0 VLC Input Resistance RVLC – 167 – 2 µA kΩ MOTOROLA ANALOG IC DEVICE DATA MC33219A ELECTRICAL CHARACTERISTICS (TA = 25°C, VCC = 5.0 V, CD ≤ 0.8 V, unless noted. See Figure 2.) Characteristic Symbol Min Typ Max Unit ATTENUATORS Receive Attenuator Gain (f = 1.0 kHz) Full Volume Rx Mode Tx Mode Idle Mode Range (Rx to Tx Mode) dB GRX GRXT GRXI ∆GRX 3.0 – 49 – 28 50 6.7 – 46 – 25 53 9.0 – 43 – 22 56 Volume Control Range (Rx Mode Only, VLC Varied from VB to (VB – 1.0 V)) VCR 34 40 46 dB AGC Attenuation Range (VCC = 3.5 to 2.7 V, Receive Mode Only, VLC = VB) GAGC 20 26 36 dB GTX GTXR GTXI ∆GTX 3.0 – 49 –19 50 6.7 – 46 –16 53 9.0 – 43 –13 56 – – 2.5 0.7 – – – – – 120 0 –10 – – – – – – 0 – 8.0 70 – – – Transmit Attenuator Gain (f = 1.0 kHz) Tx Mode Rx Mode Idle Mode Range (Tx to Rx Mode) dB RAO, TAO Output Current Capability VCC ≥ 3.0 V VCC < 3.0 V IOATT RAO Offset Voltage with Respect to VB Rx Mode Idle Mode Tx Mode VRAO TAO Offset Voltage with Respect to VB Rx Mode Idle Mode Tx Mode VTAO mA peak mVdc mVdc RAI, TAI Input Impedance (Vin < 300 mVrms) RINATT – 100 – kΩ RAI, TAI Input Offset Voltage with Respect to VB VINATT – 0 – mVdc MCOVOS – – 9.0 – mVdc Input Bias Current (Pin 20) IMBIAS – – 30 – nA Open Loop Gain (f < 100 Hz) VVOLM – 70 – dB Gain Bandwidth GBWM – 1.5 – MHz Maximum Output Voltage Swing (1% THD) VOMAX – 4.1 – Vp–p Maximum Output Current Capability IOMCO – 2.0 – mA peak GMT 70 – 78 68 – – dB RXOVOS – – 1.0 – mVdc Input Bias Current (Pin 17) IRBIAS – – 30 – nA Open Loop Gain (f < 100 Hz) AVOLR – 70 – dB Gain Bandwidth GBWR – 1.5 – MHz Maximum Output Voltage Swing (1% THD) VOMAX – 4.1 – Vp–p Maximum Output Current Capability IORXO – 2.0 – mA peak MICROPHONE AMPLIFIER (Pins 20, 21) Output Offset with Respect to VB (RF = 300 kΩ) Muting (∆ Gain) – RF = 100 kΩ RF = 300 kΩ RECEIVE AMPLIFIER (Pins 16, 17) Output Offset with Respect to VB (RF = 10 kΩ) MOTOROLA ANALOG IC DEVICE DATA 3 MC33219A ELECTRICAL CHARACTERISTICS (TA = 25°C, VCC = 5.0 V, CD ≤ 0.8 V, unless noted. See Figure 2) Symbol Min Typ Max Unit Tx–Rx Switching Threshold (Pins 4, 11) ITH 0.8 1.0 1.2 µA CPR, CPT Output Resistance (for Pulldown) RCP – 5.0 – Ω ICPLK – – 0.2 – µA VCP – 1.9 – Vdc ILDOH – – 2.0 – mA Characteristic LEVEL DETECTORS AND BACKGROUND NOISE MONITORS CPR, CPT Leakage Current CPR, CPT Nominal DC Voltage (No Signal) TLO, RLO, CP2 Source Current (@ VB – 1.0 V) RLD – 500 – Ω ILDOL – 2.0 – µA Switching Threshold (See Text) VTHMT – 1.0–1.4 – Vdc Input Resistance (Vin = 0.85 V) RMT 70 115 160 kΩ Input Current (Vin = 5.0 V) IMT – 75 – µA tMT tENM – – 1.5 5.0 – – TLO, RLO, CP2 Output Resistance TLO, RLO, CP2 Sink Current (@ VB + 1.0 V) MUTE INPUT (Pin 18) µs Timing To Mute To Enable CD INPUT (Pin 8) Switching Threshold VTHCD – 1.5 – Vdc Input Resistance (Vin = 0.8 V) RCD 150 235 350 kΩ Input Current (Vin = 5.0 V) ICD – 40 – µA tCD tENC – – 5.0 See Figure 22 – – Microphone Amplifier + Tx Attenuator Distortion THDT – 0.05 3.0 % Receive Amplifier + Rx Attenuator Distortion THDR – 0.05 3.0 % µs Timing To Disable To Enable SYSTEM DISTORTION (See Figure 1) TYPICAL TEMPERATURE PERFORMANCE Characteristic –40°C 0°C 25°C 85°C Unit Power Supply Current Enabled, VB Open Disabled, VB Open 3.18 131 3.23 119 3.23 110 3.12 121 mA µA VB Output Voltage (IVB = 0) 2.09 2.17 2.22 2.31 Vdc CT Source Current Switching to Rx Mode –80 –87 –90 –90 µA CT Sink Current Switching to Tx Mode 43 47 50 51 µA Attenuator “On” Gain 6.9 6.8 6.7 6.6 dB Attenuator Range 53 53 53 53 dB Volume Control Range (Rx Mode Only, VLC Varied from VB to (VB – 1.0 V)) 36 39 40 41 dB AGC Attenuation Range 32 24 26 30 dB Temperature data is typical performance only, based on sample characterization, and does not provide guaranteed limits over temperature. 4 MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 1. System Distortion Test Vin 3.5 mV 1.0 kHz 3.0 k 300 k MCI MCO 20 21 TAI 22 Tx Attenuator VB TAO 23 Vout NOTE: Tx Attenuator forced to transmit mode. Vin 350 mV 1.0 kHz 10 k 10 k RXI RXO 17 16 VB RAI 15 Rx Attenuator RAO 14 Vout NOTE: Rx Attenuator forced to receive mode. MOTOROLA ANALOG IC DEVICE DATA 5 MC33219A PIN FUNCTION DESCRIPTION 6 Pin Symbol 1 CP2 A capacitor at this pin stores voltage representing the transmit background noise and speech levels for the background noise monitor. 2 XDI Input to the transmit background noise monitor. 3 CPT An RC sets the time constant for the transmit background noise monitor. 4 TLI Input to the transmit level detector. 5 TLO Output of the transmit level detector. 6 VB A mid–supply reference voltage, and analog ground for the amplifiers. This must be well bypassed for proper power supply rejection. 7 CT An RC sets the switching time between transmit, receive and idle modes. 8 CD Chip Disable (Logic Input). When low, the IC is active. When high, the entire IC is powered down and non–functional, except for VB. Input impedance is nominally 125 kΩ. 9 NC No internal connection. 10 CPR An RC sets the time constant for the receive background noise monitor. 11 RLI Input to the receive level detector. 12 RLO Output of the receive level detector. 13 GND Ground pin for the entire IC. 14 RAO Output of the receive attenuator. 15 RAI Input to the receive attenuator and the dial tone detector. Input impedance is nominally 100 kΩ. 16 RXO Output of the receive amplifier. 17 RXI Inverting input of the receive amplifier. Bias current flows out of the pin. 18 MUTE 19 VLC Volume control. When VLC = VB, maximum receive gain is set when in the receive mode. When VLC = VB – 1.0 V, receive gain is down ≈ 40 dB. No effect in the transmit or idle mode. Current flow is out of the pin. Input impedance is nominally 167 kΩ. 20 MCI Inverting input of the microphone amplifier. Bias current flows out of the pin. 21 MCO Output of the microphone amplifier. 22 TAI Input of the transmit attenuator. Input impedance is nominally 100 kΩ. 23 TAO Output of the transmit attenuator. 24 VCC Power Supply Pin. Operating Range is 2.7 V to 6.5 Vdc. Bypassing is required. Description Mute Input (Logic Input). A logic low sets normal operation. A logic high mutes the microphone amplifier only. Input impedance is nominally 67 kΩ. MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 2. MC33219A Block Diagram and Test Circuit From Microphone Transmit Output To 2–4 Wire Converter 0.47 300 k 5.1 k R1 3.0 k 0.1 47 1.0 TAO 23 TAI 22 20 MCI Mute XDI 2 Tx BNM VCC V B 18 CPT 3 CP2 1 Tx Attenuator VB VCC 100 k 0.1 MCO 21 Normal 4.7 k TLI 4 5 TLO VB 1.0 AGC Mute V Volume B VLC 19 Control (See 0.1 Figure 28) Attenuator Control Circuit Tx–Rx Comp. MC33219A 7 CT VB 15 15 k Disable Normal CD VCC 100 VTH Rx BNM Bias 24 6 VB Dial Tone Detector VB 8 17 RXI VB Rx Attenuator 10 13 GND 47 12 CPR 11 RLO RLI 1.0 14 15 16 RAO RAI RXO 5.1 k R2 VCC 0.1 100 10 k 100 k 10 k 0.1 MC34119 Speaker Amplifier Receive Input From 2–4 Wire Converter NOTES: 1. All capacitors are in µF unless otherwise noted. 2. Values shown are suggested initial values only. See Applications Information for circuit adjustments. MOTOROLA ANALOG IC DEVICE DATA 7 MC33219A Figure 4. Receive Attenuator versus Volume Control Figure 3. Attenuator Gain versus VCT (Pin 7) 10 10 ATTENUATOR GAIN (dB) 0 Receive Attenuator RECEIVE ATTENUATOR GAIN (dB) Transmit Attenuator –10 – 20 – 30 – 40 0 –10 VCC = 3.3 V VCC ≥ 3.5 V – 20 VCC ≤ 2.9 V – 30 – 40 Circuit in Receive Mode – 50 –100 – 50 50 0 100 – 50 – 1.4 150 Vout – VB, OUTPUT VOLTAGE (mV) 0 –10 – 20 – 30 – 40 TLI RLI XDI 50 0 – 50 2.9 3.3 3.1 3.5 –100 500 0 – 40 – 80 TLI RLI R XDI 500 C Vin @ 1.0 kHz 40 Vout 1.0 µF 2.0 µA – 160 –200 Vin = 100 mVrms 60 TLI RLI 5.1 k XDI 20 0 – 20 500 0.1 µF C 2.0 µA Vin 80 120 Vin, INPUT SIGNAL (mVrms) 8 TLO RLO CP2 Vout – VB, OUTPUT VOLTAGE (mV) Vout – VB, OUTPUT VOLTAGE (mV) 0 1.0 µF 100 R = 10 k, C = 0.047 µF R = 10 k, C = 0.1 µF – 20 – 120 Vout Figure 8. Level Detector AC Transfer Characteristics versus Frequency 60 20 TLO RLO CP2 Iin, DC INPUT CURRENT (µA) R = 5.1 k, C = 0.1 µF 0 0 – 0.2 2.0 µA Iin Figure 7. Level Detector AC Transfer Characteristics –100 – 0.4 100 VCC (V) – 60 – 0.6 150 Circuit in Receive Mode 100 – 0.8 200 10 RECEIVE ATTENUATOR GAIN (dB) –1.0 Figure 6. Level Detector DC Transfer Characteristics Figure 5. Receive Gain versus VCC – 50 2.7 –1.2 VLC VOLTAGE, WITH RESPECT TO VB (V) VCT – VB (mV) 160 200 100 300 1.0 k TLO RLO CP2 Vout 1.0 µF 10 k f, FREQUENCY (Hz) MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 9. CD Input Characteristics (Pin 8) Figure 10. Mute Input Characteristics (Pin 18) 120 INPUT CURRENT (µ A) INPUT CURRENT (µ A) 60 40 20 80 40 Valid for Vin ≤ VCC 0 0 1.0 2.0 3.0 4.0 5.0 Valid for Vin ≤ VCC 0 7.0 6.0 0 1.0 2.0 INPUT VOLTAGE (V) 3.0 4.0 6.0 5.0 7.0 INPUT VOLTAGE (V) Figure 11. Power Supply Current Figure 12. VB Output Characteristics 6.0 4.0 5.0 3.0 VCC = 6.5 V CD ≤ 0.8 V Idle Mode 3.0 VB (V) I CC (mA) 4.0 2.0 2.0 VCC = 5.0 V 1.0 145 µA 1.0 VCC = 4.0 V VCC = 3.0 V CD ≥ 2.0 V 0 0 1.0 2.0 3.0 4.0 5.0 0 6.5 0 – 0.5 –1.5 –2.0 IB, OUTPUT CURRENT (mA) VCC (V) Figure 13. VB Power Supply Rejection versus Frequency and VB Capacitor Figure 14. Receive Amp and Microphone Amp Output Swing 6.0 80 CVB = 1000 µF 60 CVB = 100 µF P–P OUTPUT SWING (V) 100 PSRR (dB) –1.0 40 CVB = 33 µF 4.0 THD ≤ 1.0% THD = 5.0 % 2.0 20 0 200 1.0 k f, FREQUENCY (Hz) MOTOROLA ANALOG IC DEVICE DATA 10 k 20 k 0 2.5 3.5 4.5 5.5 6.5 VCC (V) 9 MC33219A Figure 15. Microphone Amplifier Muting versus Feedback Resistor Figure 16. VLC Input Current (Pin 19) 80 –2.0 INPUT CURRENT ( µA) 0 ∆ GAIN, MUTING (dB) 100 60 40 2.7 V ≤ VCC ≤ 6.5 V 20 0 1.0 k 10 k 100 k –4.0 –6.0 –8.0 –10 – 1.4 300 k 2.7 V ≤ VCC ≤ 6.5 V –1.2 –1.0 Figure 17. Idle ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ Transmit Timing 200 mVrms, 1.0 kHz TAI Input 5.0 mVrms 1.0 s TAO Output – 0.8 – 0.6 – 0.4 – 0.2 0 VLC VOLTAGE, WITH RESPECT TO VB (V) RF, FEEDBACK RESISTOR (Ω) 37 mVrms 85 ms 420 mVrms ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ 30 ms 270 mV 36 mV CPT 360 ms Idle CT 100 mV Tx 225 ms Time Constant TLO 170 mV 120 mV NOTE: Refer to Figure 2 for component values. Timing and output amplitudes shown are nominal, and are for the indicated input signal and component values. Actual timing and outputs will vary with the application. 10 MOTOROLA ANALOG IC DEVICE DATA MC33219A ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ Figure 18. Idle Receive Timing 200 mVrms, 1.0 kHz RAI Input 5.0 mVrms 1.0 s RAO Output 420 mVrms 85 ms ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ ÎÎÎÎÎÎ 270 mV 30 ms CPR 450 ms CT Rx 150 mV Idle 225 ms Time Constant 100 mV RLO NOTE: Refer to Figure 2 for component values. Timing and output amplitudes shown are nominal, and are for the indicated input signal and component values. Actual timing and outputs will vary with the application. MOTOROLA ANALOG IC DEVICE DATA 11 MC33219A Figure 19. Transmit Receive Timing (Short Cycle Timing) ÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎ ÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎ 200 mVrms, 1.0 kHz TAI Input ≈ 300 ms ≈ 300 ms 200 mVrms, 1.0 kHz RAI Input 200 mV TLO RLO 200 mV Rx CT TAO Output RAO Output 93 ms Idle 72 ms ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎ 250 mV Tx ÎÎ ÎÎ ÎÎ ÎÎ ÎÎ 18 ms 42 ms 430 mVrms ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎ ÎÎÎ ÎÎÎ ÎÎÎ 430 mVrms NOTE: 1. External component values are those shown in Figure 2. 2. Timing and output amplitudes shown are nominal, and are for the indicated input signal and component values. Actual timing and outputs will vary with the application. 12 MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 20. Transmit Receive Timing (Long Cycle Timing) ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ 200 mVrms, 1.0 kHz TAI Input ≈ 1.0 s 200 mVrms, 1.0 kHz RAI Input ≈ 1.0 s TLO 200 mV RLO 200 mV 72 ms Rx CT ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ Idle 250 mV Tx 130 ms TAO Output 225 ms Time Constant t1 RAO Output 32 mVrms 40 ms 430 mVrms 430 mVrms NOTE: 1. External component values are those shown in Figure 2. 2. Timing and output amplitudes shown are nominal, and are for the indicated input signal and component values. Actual timing and outputs will vary with the application. 3. Time t1 depends on the ratio of the on–off amplitude of the signal at TAI. MOTOROLA ANALOG IC DEVICE DATA 13 MC33219A Figure 21. Transmit Receive Timing (Long Cycle Timing) ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ 200 mVrms, 1.0 kHz TAI Input ≈ 1.0 s 200 mVrms, 1.0 kHz RAI Input ≈ 1.0 s TLO 200 mV RLO 200 mV 32 ms Rx ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎ CT Idle Tx 250 mV 90 ms TAO Output 100 ms Time Constant t1 RAO Output 32 mVrms 20 ms 430 mVrms 430 mVrms NOTE: 1. External component values are those shown in Figure 2, except the capacitor at CT is 6.8 µF. 2. Timing and output amplitudes shown are nominal, and are for the indicated input signal and component values. Actual timing and outputs will vary with the application. 3. Time t1 depends on the ratio of the on–off amplitude of the signal at TAI. 14 MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 22. Chip Disable Timing CD Input (Pin 8) ÎÎÎÎ ÎÎÎÎ ÎÎÎÎ ÎÎÎÎ tOFF ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ 5.0 µs Output at RAO, TAO t1 NOTE: Enable time t1 depends on the length of tOFF according to the following chart: t1 tOFF ≤ 50 ms 100 ms 500 ms 5.0 s to 60% to 100% – 5.0 µs 64 ms 80 ms 5.0 µs 14 ms 72 ms 100 ms Figure 23. Mute Timing Mute Input (Pin 18) ÎÎÎÎ ÎÎÎÎ ÎÎÎÎ ÎÎÎÎ 1.5 µs Output at MCO MOTOROLA ANALOG IC DEVICE DATA 5.0 µs ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ 15 MC33219A FUNCTIONAL DESCRIPTION Introduction The fundamental difference between the operation of a speakerphone and a telephone handset is that of half–duplex versus full–duplex. The handset is full duplex, meaning conversation can occur in both directions (transmit and receive) simultaneously. This is possible due to both the low sound level at the receiver, and the fact that the acoustic coupling from the earpiece to the mouthpiece is almost non–existent (the receiver is normally held against a person’s ear). The loop gain from the receiver to the microphone and through the circuit is well below that needed to sustain oscillations. A speakerphone, on the other hand, has higher gain levels in both the transmit and receive paths, and attempting to converse full duplex results in oscillatory problems due to the loop that exists within the speakerphone circuit. The loop is formed by the hybrid, the acoustic coupling (speaker to microphone), and the transmit and receive paths (between the hybrid and the speaker/microphone). The only practical and economical method used to date 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 circuit which can detect who is talking (in reality, who is talking louder), 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 detect this, and switch the circuit appropriately. By providing speech level detectors, the circuit operates in a “hands–free” mode, eliminating the need for a “push–to–talk” switch. The MC33219A provides the necessary circuitry to perform a voice switched, half duplex, speakerphone function. The IC includes transmit and receive attenuators, pre–amplifiers, level detectors and background noise monitors for each path. An attenuator control circuit automatically adjusts the gain of the transmit and receive attenuators based on the relative strengths of the voice signals present, the volume control, and the supply voltage (when low). The detection sensitivity and timing are externally controllable. Please refer to the Block Diagram (Figure 2) when reading the following sections. Transmit and Receive Attenuators The transmit and receive attenuators are complementary, performing a log–antilog function. When one is at maximum gain (≈ 6.7 dB), the other is at maximum attenuation (≈ –46 dB); they are never both fully on or fully off. Both attenuators are controlled by a single output from the Attenuator Control Circuit which ensures the sum of their 16 gains will remain constant at a typical value of – 40 dB. Their purpose is to provide the half–duplex operation required in a speakerphone. The attenuators are non–inverting, and have a usable bandwidth of 50 kHz. The input impedance of each attenuator (TXI and RXI) is nominally 100 kΩ (see Figure 24), and the input signal should be limited to 300 mVrms (850 mV p–p) to prevent distortion. That maximum recommended input signal is independent of the volume control setting. Both the input and output are biased at ≈ VB. The output impedance is <10 Ω until the output current limit (see specs) is reached. Figure 24. Attenuator Input Stage VB TAI (RAI) 10 k 90 k VB The attenuators are controlled by the single output of the Attenuator Control Circuit, which is measurable at CT (Pin 7). When the circuit detects speech signals directing it to the receive mode (by means of the level detectors described below), an internal current source of 90 µA will charge the CT capacitor to a voltage positive with respect to VB (see Figure 25). At the maximum volume control setting, this voltage will be approximately 150 mV, and the receive attenuator will have a gain of 6.7 dB. When the circuit detects speech signals directing it to the transmit mode, an internal current source of 50 µA will take the capacitor to approximately – 100 mV with respect to VB (the transmit attenuator will have a gain of 6.7 dB). When there is no speech present in either path, the current sources are shut off, and the voltage at CT will decay to be equal to VB. This is the idle mode, and the attenuators’ gains are nearly halfway between their fully ON and fully OFF positions (– 25 dB for the Rx attenuator, –16 dB for the Tx attenuator). Monitoring the CT voltage (with respect to VB) is the most direct method of monitoring the circuit’s mode, and its response. The inputs to the Attenuator Control Section are six: The Tx–Rx comparator operated by the level detectors, two background noise monitors, the volume control, the dialtone detector, and the AGC circuit. These six functions are described as follows. MOTOROLA ANALOG IC DEVICE DATA MC33219A Figure 25. CT Attenuator Control Circuit VB RT MC33219A To Attenuators Voltage Clamps CT CT I1 90 µA Tx Control Circuit I2 50 µA Rx AGC Level Detectors There are two identical level detectors: one on the receive side and one on the transmit side (refer to Figure 26). 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. Refer to the graphs of Figures 6, 7 and 8 for their DC and AC transfer characteristics. The sensitivity of each level detector is determined by the external resistor and capacitor at their input (TLI and RLI). The 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 quick rise time (determined by the capacitor and an internal 500 Ω resistor), and a slow decay time set by an internal current source and the capacitor. The capacitors on the two outputs should have the same value (±10%) to prevent timing problems. Referring to Figure 2, the outputs of the two level detectors drive the Tx–Rx comparator. The comparator’s output state depends on whether the transmit or receive speech signal is stronger, as sensed by the level detectors. The Attenuator Control Circuit uses this signal, along with the background noise monitors, to determine which mode to set. Figure 26. Level Detector Signal Input C R TLI (RLI) 500 Ω VB 2.0 µA External Component Values are Application Dependent. MOTOROLA ANALOG IC DEVICE DATA TLO (RLO) 1.0 µF Background Monitors TX–Rx Comp. Vol. Control Dial Tone Det. 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). There are two background noise monitors: one for the receive path and one for the transmit path. Refering to Figure 27, each is operated on by a level detector, which provides a DC voltage representative of the combined speech and noise level. However, the peaks, valleys, and bursts, which are characteristic of speech, will cause the DC voltage (at CP2 or RLO) to increase relatively quickly, causing the output of the next amplifier to also rise quickly. If that increase exceeds the 36 mV offset, and at a speed faster than the time constant at CPT (CPR), the output of the last comparator will change, indicating the presence of speech to the attenuator control circuit. This will keep the circuit in either the transmit or the receive mode, depending on which side has the stronger signals. When a new continuous signal is applied, the time constant at CPT (CPR) determines how long it takes the circuit to decide that the new sound is continuous, and is therefore background noise. The system requires that the average speech signal be stronger than the background noise level (by 6.0–7.0 dB) for proper speech detection. When only background noise is present in both paths, the output of the monitors will indicate the absence of speech, allowing the circuit to go to the idle mode. AGC Circuit In the receive mode only, the AGC circuit decreases the gain of the receive attenuator when the supply voltage at VCC falls below 3.5 V, according to the graph of Figure 5. The gain of the transmit path changes in a complementary manner. The purpose of this feature is to reduce the power (and current) used by the speaker when the speakerphone is powered by the phone line, and is connected to a long telephone line, where the available power is limited. Reducing the speaker power controls the voltage sag at VCC, reduces clipping and distortion at the speaker output, and prevents possible erratic operation. 17 MC33219A Figure 27. Background Noise Monitor CPT (CPR) 100 k Background Noise Monitor Signal Input C R 500 Ω XDI (RLI) VCC CP2 (RLO) 47 µF VB 36 mV 2.0 µA 1.0 µF External Component Values are Application Dependent. To Attenuator Control Circuit 31.7 k 18.6 k VB Volume Control The volume control input at VLC (Pin 19) is sensed as a voltage with respect to VB. The volume control affects the attenuators in the receive mode only. It has no effect in the idle or transmit modes. By varying the voltage at the VLC pin (Pin 19), the volume control varies the gain of the attenuators. Maximum receive attenuator gain (6.7 dB) occurs when VLC = VB. As VLC is reduced below VB, the gain of the receive attenuator is reduced, and the transmit attenuator gain increases in a complementary manner. The usable range of the VLC pin is ≈ 1.1 V for VCC ≥ 3.5 V, providing a range of ≈ 40 dB (see Figure 4). At VCC < 3.5 V, the range is reduced due to the lower VB voltage, and the AGC function. The configuration of the external volume control potentiometer circuit depends on whether the VCC supply voltage is regulated or if it varies, such as in a phone line powered circuit (see Figure 28). If the supply voltage is regulated, the circuit on the left can be used. The value of the lower resistor (R1) depends on the value of VCC, so that Pin 19 can be varied from VB to ≈ 1.1 V below VB. In a phone line powered circuit, the value of VCC, and consequently VB, will vary with line length and with the amount of sound at the speaker. In this case, the circuit on the right side of Figure 28 must be used to provide a fixed reference voltage for the potentiometer. With this circuit, the volume setting will not vary when VCC is ≥ 3.5 V. As VCC falls below 3.5 V, the zener diode will drop out of regulation, but the AGC circuit will ensure that instabilities do not occur. The bias current at VLC flows out of the pin and depends on the voltage at the pin (see Figure 16). The capacitor from VLC to VB helps reduce any effects of ripple or noise on VB. Figure 28. Volume Control Regulated Supply Unregulated Supply VB VB VCC 6.5 V 6.0 V 5.0 V 4.0 V 18 R1 86 k 72 k 50 k 25 k 50 k R1 To VLC (Pin 19) LM385-1.2 0.1 Volume Control 3160 0.1 50 k Volume Control To VLC (Pin 19) Dial Tone Detector When the speakerphone is initially taken off–hook, the dial tone signal will switch the circuit to the receive mode. However, since the dial tone is a continuous signal, the MC33219A would consider it as background noise rather than speech, and would therefore switch from receive to idle, causing the dial tone sound level to fade. The dial tone detector prevents the fading by disabling the background noise monitor. The dial tone detector is a comparator with one side connected to the receive attenuator input (RAI), and the other input connected to VB with a – 20 mV offset (see Figure 29). If the circuit is in the receive mode and the incoming signal has peaks greater than 20 mV (14 mV rms), the comparator’s output will change, disabling the receive idle mode. The receive attenuator will then be at a setting determined solely by the volume control. NOTE: The dial tone detector is not a frequency discriminating circuit. Figure 29. Dial Tone Detector To Rx Attenuator RAI To Attenuator Control Circuit 20 mV VB Microphone Amplifier, Mute The microphone amplifier (Pins 20, 21) has the non–inverting input internally connected to VB, 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 70 dB (f < 100 Hz), and the gain–bandwidth is typically 1.5 MHz. The maximum p–p output swing, for 1.0% or less distortion, is shown in Figure 14. The output impedance is <10 Ω until current limiting is reached (typically 2.0 mA peak). The input bias current at MCI is typically 30 nA out of the pin. The mute function (Pin 18), when activated, will reduce the gain of the amplifier by shorting the external feedback resistor (RMF in Figure 30). The amplifier is not disabled in this mode; MCO remains a low impedance output, and MCI remains a virtual ground at VB. The amount of muting (the MOTOROLA ANALOG IC DEVICE DATA MC33219A change in gain) depends on the value of the external feedback resistor, according to the graph of Figure 15. Muting occurs as the mute input pin is taken from ≈ 1.0 V to ≈ 1.4 V. The voltage on this pin must be ≤ 0.8 V for normal operation, and ≥ 2.0 V for muting. See Figure 10 for input current requirements. The input must be kept within the range of VCC and GND. If the input is taken more than 0.4 V above V CC or below GND excessive currents will flow, and the device’s operation will be distorted. If the mute function is not used, the pin should be grounded. Figure 30. Microphone Amplifier and Mute RMF From Microphone VB RMI MCO MCI VCC Mute 50 k 50 k Receive Amplifier The receive amplifier (Pins 16, 17) has the non–inverting input internally connected to VB, 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 70 dB (f < 100 Hz), and the gain–bandwidth is typically 1.5 MHz. The maximum p–p output swing for 1.0% or less distortion is shown in Figure 14. The output impedance is <10 Ω until current limiting is reached (typically 2.0 mA peak). The input bias current at RXI is typically 30 nA out of the pin. MOTOROLA ANALOG IC DEVICE DATA Power Supply, VB and Chip Disable The power supply voltage at Pin 24 is to be between 3.5 and 6.5 V for normal operation, and down to 2.7 V with the AGC in effect (see AGC section). The supply current required is typically 3.2 mA in the idle mode, and ≈ 4.0 mA in the transmit and receive modes. Figure 11 shows the supply current for both the normal and disabled modes. The output voltage at VB (Pin 6) is approximately equal to (VCC – 0.7)/2, and provides an AC ground for the internal amplifiers and the system. The output impedance at VB is approximately 600 Ω, and in conjunction with the external capacitor at VB forms a low pass filter for power supply noise rejection. The choice of the VB capacitor size is application dependent based on whether the circuit is powered by the telephone line or a regulated supply. See Figure 13 for PSRR information. Since VB biases the microphone and receive amplifiers, the amount of supply rejection at their outputs is a function of the rejection at VB, as well as the gains of the amplifiers. The amount of current which can be sourced out of the VB pin depends on the VCC voltage (see Figure 12). Drawing current in excess of that shown in Figure 12 will cause VB to drop low enough to disrupt the circuit’s operation. This pin can sink ≈ 100 µA when enabled, and 0 µA when disabled. The Chip Disable (Pin 8) permits powering down the IC for power conservation. With CD between 0 and 0.8 V, normal operation is in effect. With CD between 2.0 V and VCC, the IC is powered down, and the supply current drops to about 110 µA (at VCC = 5.0 V, see Figure 11). When CD is high, the microphone and receive amplifiers, the level detectors, and the two attenuators are disabled (their outputs go to a high impedance). The background noise monitors are disabled, and Pins 3 and 10 will go to VCC. The VB output, however, remains active, except that it cannot sink any current. The CD input must be kept within the range of VCC and GND. See Figure 9 for input current requirements. If the input is taken more than 0.4 V above VCC or below GND excessive currents will flow, and the device’s operation will be distorted. If the disable function is not used, the pin should be connected to ground. 19 MC33219A APPLICATIONS INFORMATION Switching and Response Time Theory The switching time of the MC33219A circuit is dominated first by the components at CT (Pin 7, see Figure 2), and second by the capacitors at the level detector outputs (RLO, TLO). The transition time to receive or to transmit mode from either idle or the other mode is determined by the capacitor at CT, along with the internal current sources (refer to Figure 25). The switching time is: DV C T DT I When switching from idle to receive, ∆V = 150 mV, I = 90 µA, the CT capacitor is 15 µF, and ∆T calculates to ≈ 25 ms. When switching from idle to transmit, ∆V = 100 mV, I = 50 µA, the CT capacitor is 15 µF, and ∆T calculates to ≈ 30 ms. When the circuit switches to idle, the internal current sources are shut off, and the time constant is determined by the CT capacitor and RT, the external resistor (see Figure 25). With CT = 15 µF, and RT = 15 kΩ, the time constant is ≈ 225 ms, giving a total switching time of ≈ 0.68 s (for 95% change). The switching period to idle begins when both speakers have stopped talking. The switching time back to the original mode will depend on how soon that speaker begins speaking again. The sooner the speaking starts during the “decay to idle” period, the quicker the switching time, since a smaller voltage excursion is required. That switching time is determined by the internal current sources as described above. When the circuit switches directly from receive to transmit (or vice versa), the total switching time depends not only on the components and currents at the CT pin, but also on the response of the level detectors, the relative amplitude of the two speech signals, and the mode of the circuit, since the two level detectors are connected differently to the two attenuators. The rise time of the level detector’s outputs (RLO, TLO) is not significant since it is so short. The decay time, however, provides a significant part of the “hold time” necessary to hold the circuit (in transmit or receive) during the normal pauses in speech. The capacitors at the two outputs must be equal value (±10%) to prevent problems in timing and level response. The components at the inputs of the level detectors (RLI, TLI) do not affect the switching time, but rather affect the relative signal levels required to switch the circuit, as well as the frequency response of the detectors. They must be adjusted for proper switching response as described later in this section. + Switching and Response Time Measurements Using burst of 1.0 kHz sine waves to force the circuit to switch among its modes, the timing results were measured and are indicated in Figures 17–21. a) In Figure 17, when a signal is applied to the transmit attenuator only (normally via the microphone and the microphone amplifier), the transmit background noise monitor immediately indicates the “presence of speech” as evidenced by the fact that CPT begins rising. The slope of the rising CPT signal is determined by the external resistor and capacitor on that pin. Even though the transmit 20 attenuator is initially in the idle mode (–16 dB), there is sufficient signal at its output to cause TLO to increase. The attenuator control circuit then forces the circuit to the transmit mode, evidenced by the change at the CT pin. The attenuator output signal is then 6.7 dB above the input. With the steady sine wave applied to the transmit input, the circuit will stay in the transmit mode until the CPT pin gets to within 36 mV of its final value. At that point, the internal comparator (see Figure 27) switches, indicating to the attenuator control circuit that the signal is not speech, but rather it is a steady background noise. The circuit now begins to decay to idle, as evidenced by the change at CT and TLO, and the change in amplitude at TAO. When the input signal at TAI is removed (or reduced), the CPT pin drops quickly, allowing the circuit to quickly respond to any new speech which may appear afterwards. The voltage at CT decays according to the time constant of its external components, if not already at idle. The voltage change at CP2, CPT, and TAO depends on the input signal’s amplitude and the components at XDI and TLI. The change at CT is internally fixed at the level shown. The timing numbers shown depend both on the signal amplitudes and the components at the CT and CPT pins. b) Figure 18 indicates what happens when the same signal is applied to the receive side only. RLO and CPR react similarly to TLO and CPT. However, the circuit does not switch to idle when CPR finishes transitioning since the dial tone detector disables the background noise monitor, allowing the circuit to stay in the receive mode as long as there is a signal present. If the input signal amplitude had been less than the dial tone detector’s threshold, the circuit response would have been similar to that shown in Figure 17. The voltage change at CT depends on the setting of the volume control (Pin 19). The 150 mV represent maximum volume setting. c) Figure 19 indicates the circuit response when transmit and receive signals are alternately applied, with relatively short cycle times (300 ms each) so that neither attenuator will begin to go to idle during its “on” time. Figure 20 indicates the circuit response with longer cycle times (1.0 s each), where the transmit side is allowed to go to idle. Figure 21 is the same as Figure 20, except the capacitor at CT has been reduced from 15 µF to 6.8 µF, providing a quicker switching time. The reactions at the various pins are shown. The response times at TAO and RAO are different, and typically slightly longer than what is shown in Figures 17 and 18 due to: – the larger transition required at the CT pin, – the greater difference in the levels at RLO and TLO due to the positions of the attenuators as well as their decay time, and – response time of the background noise monitors. The timing responses shown in these three figures are representative for those input signal amplitudes and burst durations. Actual response time will vary for different signal conditions. NOTE: While it may seem desirable to decrease the switching time between modes by reducing the capacitor at CT, this should be done with caution for two reasons: 1) If the switching time is too short, the circuit response may appear to be “too quick” to the user, who may consider its operation erratic. The recommended values in this data sheet, along with the accompanying timings, provide what MOTOROLA ANALOG IC DEVICE DATA MC33219A properties are just as important (just as equally important) as the electronics. One of the major issues involved in a speakerphone design is the acoustic coupling of the speaker to the microphone, which must be minimized. This parameter is dependent entirely on the design of the enclosure, the mounting of the speaker and the microphone, and their characteristics. 2) Ensure the speaker is optimally mounted. This fact alone can make a difference of several dB in the sound level from the speaker, as well as the sound quality. The speaker manufacturer should be consulted for this information. 3) Do not breadboard the circuit with the microphone and speaker hanging out in midair. It will not work. The speaker and microphone must be in a suitable enclosure, preferably one resembling the end product. If this is not feasible, temporarily use some other properly designed enclosure, such as one of the many speakerphones on the market. 4) Do not breadboard the circuit on a wirewrapped board or a plug–in prototyping board. Use a PC board, preferably with a ground plane. Proper filtering of the supply voltage at the VCC pin is essential. 5) The speakerphone must be tested with the intended hybrid and connected to a phone line or phone line simulator. The performance of the hybrid is just as important as the enclosure and the speakerphone IC. 6) When testing the speakerphone, be conscious of the environment. If the speakerphone is in a room with large windows and tile floors, it will sound different than if it is in a carpeted room with drapes. Additionally, be conscious of the background noise in a room. 7) When testing the speakerphone on a phone line, make sure the person at the other end of the phone line is not in the same room as the speakerphone. experience has shown to be a “comfortable response” by the circuit. 2) The distortion in the receive attenuator will increase as the C T capacitor value is decreased. The extra THD will be most noticeable at the lower frequencies and at the lower ampitudes. Table 1 provides a guideline for this issue. ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ Table 1. THD versus CT Capacitor CT Capacitor Idle – Rx Transition Input @ RAI Freq. 25 ms 20 mVrms 300 Hz 1.2% 1.0 KHz 0.25% 300 Hz 0.5% 1.0 KHz 0.2% 300 Hz 5.0% 1.0 KHz 0.7% 300 Hz 1.3% 1.0 KHz 0.35% 300 Hz 11% 1.0 KHz 1.8% 300 Hz 2.6% 1.0 KHz 0.7 % 15 µF 100 mVrms 6.8 µF 12 ms 20 mVrms 100 mVrms 3.0 µF 5.0 ms 20 mVrms 100 mVrms THD @ RAO Considerations in the Design of a Speakerphone The design and adjustment of a speakerphone involves human interface issues as well as proper signal levels. Because of this fact, it is not practical to do all of the design mathematically. Certain parts of the design must be done by trial and error, most notably the switching response and the “How does it sound?” part of the testing. Among the recommendations for a successful design are: 1) Design the enclosure concurrently with the electronics. Do not leave the case design to the end as its Design Procedure A recommended sequence follows in Figure 31, assuming the end product enclosure is available, with the intended production microphone and speaker installed, and the PC boards or temporary substitutes installed. Figure 31. Basic Block Diagram for Design Purposes VM MCI Mike Amp MCO TAI TAO Tx Attenuator V1 R1 Microphone I1 TLI Tip Acoustic (G ) Coupling AC Control GST Hybrid Ring RLI I2 R2 RAO Speaker Speaker Amp MOTOROLA ANALOG IC DEVICE DATA Rx Attenuator RAI V2 RXO RXI 21 MC33219A 1) Design the hybrid, ensuring proper interface with the phone line for both DC and AC characteristics. The return loss must be adjusted to comply with the appropriate regulatory agency. The sidetone should then be adjusted according to the intent of the product. If the product is a speakerphone only (without a handset), the sidetone gain (GST) should be adjusted for maximum loss. If a handset is part of the end product, the sidetone must be adjusted for the minimum acceptable sidetone levels in the handset. Generally, for the speakerphone interface, 10–20 dB sidetone loss is preferred for GST. 2) Check the acoustic coupling of the enclosure (GAC in Figure 31). With a steady sound coming out of the speaker, measure the rms voltage on the speaker terminals and the rms voltage out of the microphone. Experience has shown that the loss should be at least 40 dB, preferably 50 dB. This should be checked over the frequency range of 20 Hz to 10 kHz. 3) Adjust the transmit path for proper signal levels, based on the lowest speech levels as well as the loudest. Based on the typical levels from commonly available microphones, a gain of about 35–45 dB is required from the microphone terminals to Tip and Ring. Most of that gain should be in the microphone amplifier to make best use of the transmit attenuator, but the maximum input level at TAI must not be exceeded. If a signal generator is used instead of a microphone for testing, the circuit can be locked into the transmit mode by grounding CPT (Pin 3). Frequency response can generally be tailored with capacitors at the microphone amplifier. 4) Adjust the receive path for proper signal levels based on the lowest speech levels as well as the loudest. A gain of about 30 dB is required from Tip and Ring to the speaker terminals for most applications (at maximum volume). Most of that gain should be in the receive amplifier (at RXI, RXO) to make best use of the receive attenuator, but the maximum input level at RAI must not be exceeded. If a signal generator is used for signal injection during testing, the circuit can be locked into the receive mode by grounding CPR (Pin 10), although this is usually not necessary since the dial tone detector will keep the circuit in the receive mode. Frequency response can generally be tailored with capacitors at the receive amplifier. 5) Check that the loop gain (i.e., the receive path gain + acoustic coupling gain + transmit path gain + sidetone gain) is less than 0 dB over all frequencies. If not, “singing” will occur: a steady oscillation at some audible frequency. 6) a) The final step is to adjust the resistors at the level detector inputs (RLI and TLI) for proper switching response (the switchpoint occurs when I1 = I2). This has to be the last step, as the resistor values depend on all of the above adjustments, which are based on the mechanical, as well as the electrical, characteristics of the system. NOTE: An extreme case of level detector misadjustment can result in “motorboating”. In this condition, with a receive signal applied, sound from the speaker enters the microphone, and causes the circuit to switch to the transmit mode. This causes the speaker sound to stop (as well as the sound into the microphone), allowing the circuit to switch back to the receive mode. This sequence is then repeated, usually, at a rate of a few Hz. The first thing to check is the acoustic coupling, and then the level detectors. b) Starting with the recommended values for R1 and R2 (in Figure 2), hold a normal conversation with someone on another phone. If the resistor values are not optimum, one of the talkers will dominate, and the other will have difficulty 22 getting through. If, for example, the person at the speakerphone is dominant, the transmit path is overly sensitive, and the receive path is not sensitive enough. In this case, R1 (at TLI) should be increased, or R2 (at RLI) decreased, or both. Their exact value is not critical at this point, only their relative value. Keeping R1 and R2 in the range of 2.0–20 k, adjust them until a suitable switching response is found. c) Then have the person at the other end of the phone line speak loud continuously, or connect to a recording which is somewhat strong. Monitor the state of the circuit (by measuring the CT versus VB pins, and by listening carefully to the speaker) to check that the sound out of the speaker is not attempting to switch the circuit to the transmit side (through acoustic coupling). If it is, increase R1 (at TLI) in small steps just enough to stop the switching (this desensitizes the transmit side). If R1 has been changed a large amount, it may be necessary to readjust R2 for switching response. If this cannot be achieved in a reasonable manner, the acoustic coupling is too strong. d) Next, have the person at the speakerphone speak somewhat loudly, and again monitor the state of the circuit, primarily by having the person at the other end listen carefully for fading. If there is obvious fading of the sound, increase R2 so as to desensitize the receive side. Increase R2 just enough to stop the fading. If this cannot be achieved in a reasonable manner, the sidetone coupling is too strong. e) If necessary, readjust R1 and R2 a small amount relative to each other, to further optimize the switching response. Transmit/Receive Detection Priority Although the MC33219A was designed to have an idle mode such that the transmit side has a small priority (the idle mode position is closer to the full transmit side), the idle mode position can be moved with respect to the transmit or the receive side. With this done, the ability to gain control of the circuit by each talker will be changed. By connecting a resistor from CT (Pin 7) to ground, the circuit will be biased more towards the transmit side. The resistor value is calculated from: R + RT ƪ ƫ DV * 1 V B where R is the added resistor, RT is the resistor normally between Pins 6 and 7 (typically 15 kΩ), and ∆V is the desired change in the CT voltage at idle. By connecting a resistor from CT (Pin 7) to VCC, the circuit will be biased towards the receive side. The resistor value is calculated from: R + RT ƪ V –V CC B DV ƫ *1 R, RT, and ∆V are the same as above. Switching response and the switching time will be somewhat affected in each case due to the different voltage excursions required to get to transmit and receive from idle. For practical considerations, the ∆V shift should not exceed 50 mV. Disabling the Idle Mode For testing or circuit analysis purposes, the transmit or receive attenuators can be set to the ON position, even with steady signals applied, by disabling the background noise monitors. Grounding the CPR pin will disable the receive background noise monitor, thereby indicating the “presence MOTOROLA ANALOG IC DEVICE DATA MC33219A of speech” to the attenuator control block. Grounding CPT does the same for the transmit path. Additionally, the receive background noise monitor is automatically disabled by the dial tone detector whenever the receive signal exceeds the detector’s threshold. Dial Tone Detector Threshold The threshold for the dial tone detector is internally set at ≈ 20 mV (14 mVrms) below VB (see Figure 29). That threshold can be adjusted if desired by changing the bias at RAI. The method used depends on how the input of the receive attenuator is connected to other circuitry. a) If the attenuator input (RAI) is DC coupled to the receive amplifier (Pins 15 to 16 as in Figure 2), or to some other amplifier in the system, then the threshold is changed by forcing a small offset on that amplifier. As shown in Figure 32, connect a resistor (RTO) from the summing node to either ground or VCC, depending on whether the dial tone detector threshold is to be increased or decreased. RF and RI are the resistors normally used to set the gain of that amplifier. Figure 33. Adjusting Dial Tone Detector Threshold (AC Coupled) Audio Signal Input Attenuator 56 k RTO 100 k RAI 3.0 k VB DTD VB To Control Circuit VB 20 mV To Increase The Threshold Audio Signal Input VB Figure 32. Adjusting Dial Tone Detector Threshold (DC Coupled) VCC or GND Audio Signal Input VCC Attenuator 3.0 k RTO RI RTO RF 100 k RAI VB 56 k RXI RAI RXO DTD To Control Circuit VB 20 mV VB 100 k VB VB 20 mV Attenuator To Decrease The Threshold To Attentuator Control Circuit To increase the threshold, use the first circuit in Figure 33. The voltage at the top of the 3.0 k resistor is between 90 and 180 mV above V B (depending on V CC). RTO and the 100 k input impedance form a voltage divider to create the desired offset at RAI. RTO is calculated from: Adding RTO and connecting it to ground will shift RXO and RAI upward, thereby increasing the dial tone detector threshold. In this case, RTO is calculated from: RTO + VB DV RF VB is the voltage at Pin 6, and ∆V is the amount that the detector’s threshold is increased. For example, if VB = 2.2 V, and RF = 10 k, and the threshold is to be increased by 20 mV, RTO calculates to 1.1 MΩ. Connecting RTO to VCC will shift RXO downward, thereby decreasing the dial tone detector threshold. In this case, RTO is calculated from: + – V ) RF B DV For example, if VCC = 5.0 V, VB = 2.2 V, and RF = 10 k and the threshold is to be decreased by 10 mV, RTO calculates to 2.8 MΩ. b) If the receive attenuator input is AC coupled to the receive amplifier or to other circuitry, then the offset is set at RAI. The circuits in Figure 33 are suggested for changing the threshold. RTO (V CC MOTOROLA ANALOG IC DEVICE DATA RTO + ƪ ((V CC – V ) B DV 0.05) ƫ – 1 (100 k) For example, if VCC = 5.0 V, and the threshold is to be increased by 20 mV (∆V), RTO calculates to ≈ 600 kΩ. If the threshold is to be decreased, use the second circuit in Figure 33. RTO is calculated from: RTO + ƪ (V B 0.05) DV ƫ – 1 (100 k) RFI Interference Potential radio frequency interference (RFI) problems should be addressed early in the electrical and mechanical design of the speakerphone. RFI may enter the circuit through Tip and Ring, through the microphone wiring to the microphone amplifier (which should be short), or through any of the PC board traces. The most sensitive pins on the MC33219A are the inputs to the level detectors (RLI, TLI, XDI) since, when there is no speech present, the inputs are high impedance and these op amps are in a near open–loop condition. The board traces to these pins should be kept 23 MC33219A short, and the resistor and capacitor for each of these pins should be physically close to the pins. All other input pins should also be considered sensitive to RFI signals. In The Final Analysis ... Proper operation of a speakerphone is a combination of proper mechanical (acoustic) design in addition to proper electronic design.The acoustics of the enclosure must be considered early in the design of a speakerphone. In general, electronics cannot compensate for poor acoustics, low speaker quality, low microphone quality, or any combination of these items. Proper acoustic separation of the speaker and microphone is essential. The physical location of the microphone, along with the characteristics of the selected microphone, will play a large role in the quality of the transmitted sound. The microphone and speaker 24 vendors can usually provide additional information on the use of their products. In the final analysis, the circuit will have to be fine–tuned to match the acoustics of the enclosure, the specific hybrid, and the specific speaker and microphone selected. The components shown in this data sheet should be considered as starting points only. The gains of the transmit and receive paths are easily adjusted at the microphone and receive amplifiers, respectively. The switching response can then be fine tuned by varying (in small steps) the components at the level detector inputs (TLI, RLI) until satisfactory operation is obtained for both long and short lines. For additional information on speakerphone design please refer to The Bell System Technical Journal, Volume XXXIX (March 1960, No. 2). MOTOROLA ANALOG IC DEVICE DATA MC33219A GLOSSARY A t t en u at i o n – A d ec r eas e i n m agnitude o f a communication signal, usually expressed in dB. Bandwidth – The range of information carrying frequencies of a communication system. Battery – The voltage which provides the loop current to the telephone from the CO. The name is derived from the fact that COs have always used batteries, in conjunction with AC power, to provide this voltage. C–Message Filter – A frequency weighting which evaluates the effects of noise on a typical subscriber’s system. Central Office – Abbreviated CO, it is a main telephone office, usually within of a few miles of its subscribers, that houses switching gear for interconnection within its exchange area, and to the rest of the telephone system. A CO can handle up to 10,000 subscriber numbers. CO – See Central Office. CODEC – Coder/Decoder – In the Central Office, it converts the transmit signal to digital, and converts the digital receive signal to analog. dB – A power or voltage measurement unit, referred to another power or voltage. It is generally computed as: 10 x log (P1/P2) for power measurements, and 20 x log(V1/V2) for voltage measurements. dBm – An indication of signal power. 1.0 mW across 600 Ω, or 0.775 Vrms, is defined as 0 dBm. Any other voltage level is converted to dBm by: dBm = 20 x log (Vrms/0.775), or dBm = [20 x log (Vrms)] + 2.22. d B m p – I ndic at es d B m m eas ur ement u s ing a psophometric weighting filter. dBrn – Indicates a dBm measurement relative to 1.0 pW power level into 600 Ω. Generally used for noise measurements, 0 dBrn = – 90 dBm. dBrnC – Indicates a dBrn measurement using a C–message weighting filter. DTMF – Dual Tone MultiFrequency. It is the “tone dialing” system based on outputting two non–harmonic related frequencies simultaneously to identify the number dialed. Eight frequencies have been assigned to the four rows and four columns of a keypad. Four Wire Circuit – The portion of a telephone, or central office, which operates on two pairs of wires. One pair is for the Transmit path, and one pair is for the Receive path. Full Duplex – A transmission system which permits communication in both directions simultaneously. The standard handset telephone system is full duplex. Gain – The change in signal amplitude (increase or decrease) after passing through an amplifier or other circuit stage. Usually expressed in dB, an increase is a positive number and a decrease is a negative number. Half Duplex – A transmission system which permits communication in one direction at a time. CB radios, with “push–to–talk” switches, and voice activated speakerphones are half duplex. Hookswitch – A switch within the telephone which connects the telephone circuit to the subscriber loop. The name is derived from old telephones where the switch was activated by lifting the receiver off and onto a hook on the side of the phone. MOTOROLA ANALOG IC DEVICE DATA Hybrid – A two–to–four wire converter. Idle Channel Noise – Residual background noise when transmit and receive signals are absent. Line Card – The printed circuit board and circuitry in the CO or PBX which connects to the subscriber’s phone line. A line card may hold circuitry for one subscriber or a number of subscribers. Longitudinal Balance – The ability of the telephone circuit to reject longitudinal signals on Tip and Ring. Longitudinal Signals – Common mode signals. Loop – The loop formed by the two subscriber wires (Tip and Ring) connected to the telephone at one end, and the central office (or PBX) at the other end. Generally it is a floating system, not referred to ground, or AC power. Loop Current – The DC current which flows through the subscriber loop. It is typically provided by the central office or PBX, and ranges from 20–120 mA. Mute – Reducing the level of an audio signal, generally so that it is inaudible. Partial muting is used in some applications. OFF Hook – The condition when the telephone is connected to the phone system, permitting the loop current to flow. The central office detects the DC current as an indication that the phone is busy. ON Hook – The condition when the telephone is disconnected from the phone system, and no DC loop current flows. The central office regards an ON hook phone as available for ringing. PABX – Private Automatic Branch Exchange. In effect, a miniature central office; it is a customer owned switching system servicing the phones within a facility, such as an office building. A portion of the PABX connects to the Bell (or other local) telephone system. Power Supply Rejection Ratio – The ability of a circuit to reject outputting noise or ripple, which is present on the power supply lines. PSRR is usually expressed in dB. Protection, Primary – Usually consisting of carbon blocks or gas discharge tubes, it absorbs the bulk of a lightning induced transient on the phone line by clamping the voltages to less than ±1500 V. Protection, Secondary – Usually located within the telephone, it protects the phone circuit from transient surges. Typically, it must be capable of clamping a ±1.5 kV surge of 1.0 ms duration. Pulse Dialing – A dialing system whereby the loop current is interrupted a number of times in quick succession. The number of interruptions corresponds to the number dialed, and the interruption rate is typically 10 per second. The old rotary phones and many new pushbutton phones use pulse dialing. Receive Path – Within the telephone, it is the speech path from the phone line (Tip and Ring) towards the receiver or speaker. REN – Ringer Equivalence Number. An indication of the impedance (or loading factor) of a telephone bell or ringer circuit. An REN of 1.0 equals ≈ 8.0 kΩ. The Bell system typically permits a maximum of 5.0 REN (1.6 kΩ) on an individual subscriber line. A minimum REN of 0.2 (40 kΩ) is required by the Bell system. 25 MC33219A Return Loss – Expressed in dB, it is a measure of how well the telephone’s AC impedance matches the line’s AC characteristic impedance. With a perfect match, there is no reflected signal, and therefore infinite return loss. It is calculated from: RL + 20 ) ZCKT) ) * Z LINE CKT (Z log (Z LINE Ring – One of the two wires connecting the central office to a telephone. The name is derived from the ring portion of the plugs used by operators (in older equipment) to make the connection. Ring is traditionally negative with respect to Tip. Sidetone Rejection – The rejection (in dB) of the reflected signal in the receive path resulting from a transmit signal applied to the phone and phone line. SLIC – Subscriber Line Interface Circuit. It is the circuitry within the CO or PBX which connects to the user’s phone line. Subscriber – The customer at the telephone end of the line. Subscriber Line – The system consisting of the user’s telephone, the interconnecting wires, and the central office equipment dedicated to that subscriber (also referred to as a loop). Tip – One of the two wires connecting the central office to a telephone. The name is derived from the tip of the plugs used by operators (in older equipment) to make the connection. Tip is traditionally positive with respect to Ring. Transmit Path – Within the telephone it is the speech path from the microphone towards the phone line (Tip and Ring). Two Wire Circuit – Refers to the two wires connecting the central office to the subscriber’s telephone. Commonly referred to as Tip and Ring, the two wires carry both transmit and receive signals in a differential manner. Two–to–Four Wire Converter – A circuit which has four wires (on one side): two (signal and ground) for the outgoing signal and two for the incoming signal. The outgoing signal is sent out differentially on the two wire side, and incoming differential signals received on the two wire side are directed to the receive path of the four wire side. Additional circuit within cancels the reflected outgoing signal to keep it separate from the incoming signal. Voiceband – That portion of the audio frequency range used for transmission across the telephone system. Typically it is 300–3400 Hz. Suggested Vendors Microphones Primo Microphones Inc. Bensenville, IL 60106 1–800–76–PRIMO Telecom Transformers Microtran Co., Inc. Valley Stream, NY 11528 516–561–6050 Various models – ask for catalog and Application Bulletin F232 Stancor Products Logansport, IN 46947 219–722–2244 Various models – ask for catalog PREM Magnetics, Inc. McHenry, IL 60050 815–385–2700 Various models – ask for catalog Motorola does not endorse or warrant the suppliers referenced. 26 MOTOROLA ANALOG IC DEVICE DATA MC33219A OUTLINE DIMENSIONS P SUFFIX PLASTIC PACKAGE CASE 724–03 –A– 24 13 1 12 NOTES: 1. CHAMFERED CONTOUR OPTIONAL. 2. DIMENSION L TO CENTER OF LEADS WHEN FORMED PARALLEL. 3. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 4. CONTROLLING DIMENSION: INCH. –B– L C –T– NOTE 1 K SEATING PLANE E G M N J 24 PL 0.25 (0.010) F D 24 PL 0.25 (0.010) M T A M T B M M DIM A B C D E F G J K L M N MILLIMETERS MIN MAX 32.13 31.25 6.85 6.35 4.44 3.69 0.51 0.38 1.27 BSC 1.52 1.02 2.54 BSC 0.30 0.18 3.55 2.80 7.62 BSC 15° 0° 0.51 1.01 INCHES MIN MAX 1.230 1.265 0.250 0.270 0.145 0.175 0.015 0.020 0.050 BSC 0.040 0.060 0.100 BSC 0.007 0.012 0.110 0.140 0.300 BSC 15° 0° 0.020 0.040 DW SUFFIX PLASTIC PACKAGE CASE 751E–04 –A– 24 13 –B– P 12 PL 0.010 (0.25) 1 M B M 12 D J 24 PL 0.010 (0.25) M T A S B S F R X 45° C –T– SEATING PLANE G 22 PL MOTOROLA ANALOG IC DEVICE DATA K M NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DIMENSIONS A AND B DO NOT INCLUDE MOLD PROTRUSION. 4. MAXIMUM MOLD PROTRUSION 0.15 (0.006) PER SIDE. 5. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.13 (0.005) TOTAL IN EXCESS OF D DIMENSION AT MAXIMUM MATERIAL CONDITION. DIM A B C D F G J K M P R MILLIMETERS MIN MAX 15.25 15.54 7.40 7.60 2.35 2.65 0.35 0.49 0.41 0.90 1.27 BSC 0.23 0.32 0.13 0.29 0° 8° 10.05 10.55 0.25 0.75 INCHES MIN MAX 0.601 0.612 0.292 0.299 0.093 0.104 0.014 0.019 0.016 0.035 0.050 BSC 0.009 0.013 0.005 0.011 0° 8° 0.395 0.415 0.010 0.029 27 MC33219A Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters can and do vary in different applications. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. Motorola does not convey any license under its patent rights nor the rights of others. Motorola products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Motorola product could create a situation where personal injury or death may occur. Should Buyer purchase or use Motorola products for any such unintended or unauthorized application, Buyer shall indemnify and hold Motorola and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Motorola was negligent regarding the design or manufacture of the part. Motorola and are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal Opportunity/Affirmative Action Employer. Literature Distribution Centers: USA/EUROPE: Motorola Literature Distribution; P.O. Box 20912; Phoenix, Arizona 85036. JAPAN: Nippon Motorola Ltd.; 4–32–1, Nishi–Gotanda, Shinagawa–ku, Tokyo 141, Japan. ASIA PACIFIC: Motorola Semiconductors H.K. Ltd.; Silicon Harbour Center, No. 2 Dai King Street, Tai Po Industrial Estate, Tai Po, N.T., Hong Kong. 28 ◊ CODELINE TO BE PLACED HERE *MC33219A/D* MC33219A/D MOTOROLA ANALOG IC DEVICE DATA