ML33111 Low Voltage Compander Silicon Monolithic Integrated Circuit Legacy Device: Motorola MC33111 The ML33111 contains two variable gain circuits configured for compressing and expanding the dynamic range of an audio signal. One circuit is configured as an expander, and the other is configured as a compressor. Each circuit has a full wave rectifier to provide average value information to a variable gain cell located in either the input stage or the feedback path. An internal temperature stable bandgap reference provides the necessary precision voltages. Included in the ML33111 are controls for muting each section independently, and for pass through of both. Two uncommitted op amps are available for peripheral functions. The ML33111 will operate from a supply voltage of 3.0 V to 7.0 V, and over a temperature range of TA –40° to +85°C. It is designed to accommodate a 60 dB dynamic range; from –40 dB to +20 dB referenced to 100 mVrms. Applications include cordless telephone, CBs, walkie-talkies, and most voice RF links, and any application where an improvement in the signal to noise ratio is desired. Other applications include speakerphones and voice activated intercoms, dictating machines, etc. • • • • • • • • • • Operating Supply Voltage: 3.0 V to 7.0 V Output Voltage Swing = 2.8 Vp-p with VCC = 3.0 V No Precision External Components Required 60 dB Dynamic Range Compressed to 30 dB, Re-expandable to 60 dB Unity Gain Level set at 100 mVrms Attack and Decay Times Adjustable Mute and passthrough Controls Two Uncommitted Op Amps Temperature Compensated Reference Available in Standard DIP and Surface Mount Packages 16 1 P DIP 16 = EP PLASTIC PACKAGE CASE 648 16 1 SO 16 = -5P PLASTIC PACKAGE CASE 751B (SO-16) CROSS REFERENCE/ORDERING INFORMATION PACKAGE MOTOROLA LANSDALE P DIP 16 MC33111P ML33111EP SO 16 MC33111D ML33111-5P Note: Lansdale lead free (Pb) product, as it becomes available, will be identified by a part number prefix change from ML to MLE. TRUTH TABLE Simplified Block Diagram Expander Input 20 k 0.5 14 ML33111 11 1.0 µF Compressor 3 Input ∆ Gain 40 k Rectifier 5 7.5 k PT Function 0 1 X 0 0 X 1 0 0 X X 1 Normal Comp. Mute Expander Mute Passthrough Compressor 2 Output Bias & Reference Generator 40 k Rectifier 10 9 Page 1 of 12 EM Vb ∆ Gain V+ Microphone Expander 15 Output Vb 10 k 0.5 1.0 µF 15 k CM Vb Mute/ Passthrough Logic Vb 7 16 VCC 1 4 12 8 CM EM PT 6 www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. PIN FUNCTION DESCRIPTION Name Pin Description Ground 1 Connect to a clean power supply ground. Compressor Output 2 Output of the compressor section. Compressor Input 3 Compressor input. The input impedance is nominally 10 kΩ. Nominal signal range is 1.0 mVrms to 1.0 Vrms in normal mode, and up to 0.8 Vrms in passthrough mode. Must be capacitor coupled to the signal source. Compressor Mute 4 A logic high mutes the compressor. A logic low permits normal operation and passthrough. Compressor Filter 5 Connect an external capacitor to filter the full wave rectifier’s output. This capacitor affects attack and decay times, and low frequency accuracy. Amplifier #1 6, 7 Inverting input (7) and output (6) of an op amp internally referenced to Vb. Passthrough 8 Amplifier #2 9, 10 Inverting input (9) and output (10) of an op amp internally referenced to Vb. Expander Filter 11 Connect an external capacitor to filter the full wave rectifier’s output. This capacitor affects attack and decay times, and low frequency accuracy. Expander Mute 12 A logic high mutes the expander. A logic low permits normal operation and passthrough. No Connect 13 This pin is not internally connected to anything. Expander Input 14 Expander input. The input impedance is nominally 10.9 kΩ. Nominal signal range is 10 mVrms to 316 mVrms in normal mode, and up to 1.0 Vrms in passthrough mode. Must be capacitor coupled to the signal source. Expander Output 15 Output of the expander section. VCC 16 Power supply. Connect to a power supply voltage in the range of 3.0 V to 7.0 V. Bypass capacitor should be provided at this pin. A logic high sets the gain of both expander and compressor to ≈ 0 dB, independent of input level. TRANSFER FUNCTIONS Compressor Compression Rectifier 20 dB 10 k Vout Vb 0 dB 15 k 100 mV 31.6 mV 10 mV – 20 dB 10 mV 0.3162 x V in – 40 dB Expander Vin 316 mV –10 dB – 30 dB V out 1.0 V 10 dB ∆ Gain Vin Expansion 40 k Vb Vout ∆ Gain Rectifier 1.0 mV Vout = 10 x Vin2 (Voltages are rms) MAXIMUM RATINGS Rating Symbol Value Unit VCC Supply Voltage (Pin 16 – Pin 1) VCC – 0.5, +12 Vdc High Input Voltage (Pins 3, 4, 8, 12, 14) VIH VCC + 0.5 Vdc Low Input Voltage (Pins 3, 4, 8, 12, 14) VIL – 0.5 Vdc Output Source Current (Pins 2, 6, 10, 15) IO+ Self-limiting mA Output Sink Current (Pins 2, 6, 10, 15) IO– Self-limiting mA Storage Temperature Tstg – 65, +150 °C NOTE: Devices should not be operated at these limits. The “Recommended Operating Conditions” provides for actual device operation. Page 2 of 12 www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. RECOMMENDED OPERATING CONDITIONS Characteristic VCC Supply Voltage Symbol Min Typ Max Unit VCC 3.0 — 7.0 Vdc 0 0 0 0 0 — — — — — 1.3 0.8 0.32 1.3 1.0 Vrms Input Signal Voltage Range (3.0 V < VCC < 7.0 V) Compressor — Normal and Mute Mode — Passthrough Mode Expander — Normal Mode — Mute Mode — Passthrough Mode Vin Frequency Range (± 1.0 dB accuracy) Fin 0.300 — 10 kHz Logic Input Voltage Range (Pins 4, 8, 12) Vin 0 — VCC Vdc Operating Ambient Temperature TA – 40 — + 85 °C NOTE: All limits are not necessarily functional concurrently. ELECTRICAL CHARACTERISTICS (VCC = 3.6 V, f = 1.0 kHz, TA = + 25°C, unless noted.) Characteristic Symbol Min Typ Max Unit 0 dB Gain (Vin = 100 mVrms) GOC –1.5 0 1.5 dB Gain tracking relative to GOC Vin = 1.0 Vrms Vin = 1.0 mVrms GTC 9.0 – 21 10 – 20 11 –19 COMPRESSOR (Pin 4 = Low unless noted) dB Passthrough Gain (Pin 8 = High, Pin 4 = Low, Vin = 1.0 Vrms) GPTC – 2.0 0 1.0 dB Muting (∆ Gain) with Pin 4 = High (Vin = 1.0 Vrms) GMTC 55 67 — dB Max. Output Swing @ Pin 2 (3.0 V < VCC < 7.0 V) Normal Mode Passthrough Mode Vout — — 1.1 2.3 — — Peak Output Current (3.0 ≤ VCC ≤ 7.0 V, Normal or Passthrough Modes, Vin = Max) IPK — ± 4.0 — mA Total Harmonic Distortion (Vin = 100 mVrms) THD — 0.2 1.0 % — — — 37 64 72 — — — Vp-p Power Supply Rejection @ 1.0 KHz Vin (Pin 3) = 0 Vin (Pin 3) = 10 mVrms Vin (Pin 3) = 1.0 Vrms PSRR Attack Time (Capacitor @ Pin 5 = 1.0 µF, per EIA-553) Decay Time (Capacitor @ Pin 5 = 1.0 µF, per EIA-553) tAT(C) tD(C) — — 3.0 14 — — ms Rin 8.0 10 14 kΩ VbIAS 1.4 – 20 Vb 1.6 1.6 2.0 Vdc mVdc 0 dB Gain (Vin = 100 mVrms) GOE –1.5 0 1.5 dB Gain Tracking Relative to GOE Vin = 316 mVrms Vin = 10 mVrms GTE 19 – 41 20 – 40 21 – 39 Input Impedance at Pin 3 DC Bias Level (Pin 2) Output DC Shift (Vin Changed from 0 to 100 mVrms) dB EXPANDER (Pin 12 = Low, unless noted) dB Passthrough Gain (Pin 8 = High, Pin 12 = Low, Vin = 1.0 Vrms) GPTE –1.0 0 2.0 Muting (∆ Gain) with Pin 12 = High (Vin = 0.316 Vrms) GMTE 60 76 — Max. Output Swing @ Pin 15 (3.0 V < VCC , 7.0 V) Normal Mode Passthrough Mode Vout Peak Output Current VCC = 3.0 V, Vout ≤ 2.4 Vp-p VCC = 3.0 V, Vout = 2.7 Vp-p VCC ≥ 3.6 V, Vout ≤ 2.8 Vp-p IPK Total Harmonic Distortion (Vin = 100 mVrms) THD Page 3 of 12 www.lansdale.com dB dB Vp-p — — 2.8 2.8 — — — — — ± 3.5 ±1.0 ± 4.0 — — — — 0.2 1.0 mA % Issue A ML33111 LANSDALE Semiconductor, Inc. ELECTRICAL CHARACTERISTICS (VCC = 3.6 V, f = 1.0 kHz, TA = + 25°C, unless noted.) Characteristic Symbol Min Typ Max — — — 74 76 62 — — — Unit EXPANDER (Pin 12 = Low, unless noted) Power Supply Rejection @ 1.0 kHz Vin (Pin 14) = 0 Vin (Pin 14) = 10 mVrms Vin (Pin 14) = 316 mVrms PSRR Attack Time (Capacitor @ Pin 11 = 1.0 µF, per EIA-553) Decay Time (Capacitor @ Pin 11 = 1.0 µF, per EIA-553) tAT(E) tD(E) — — 3.0 14 — — ms Rin 8.0 10.9 14 kΩ VbIAS 1.4 – 20 Vb 1.0 1.6 20 Vdc mVdc Switching Threshold (3.0 < VCC < 7.0 V) VST — 1.3 — Vdc Input Current @ Vin = 0 V @ Vin = 3.6 V Rin — — 0 55 — — tCMLH tCMHL tEMLH tEMHL tPCLH tPCHL tPELH tPEHL — — — — — — — — 2.0 3.0 2.0 3.0 2.0 5.0 6.0 7.0 — — — — — — — — Open Loop Gain AVOL — 100 — dB Gain Bandwidth BW — 300 — kHz Input Bias Current @ Pins 7, 9 IIB — 8.0 — nA Max Output Swing @ Pins 6, 10 (3.0 V < VCC < 7.0 V) Vout — 2.8 — Vp-p Peak Output Current VCC = 3.0 V, Vout ≤ 2.4 Vp-p VCC = 3.0 V, Vout = 2.6 Vp-p VCC ≥ 3.6 V, Vout ≤ 2.8 Vp-p IPK — — — ± 3.0 ± 2.0 ± 3.7 — — — Total Harmonic Distortion (Vout = 1.0 Vrms, Unity Gain) THD — 0.02 0.2 — — 1.5 1.7 2.0 — — 1.5 — Input Impedance at Pin 14 DC Bias Level (Pin 15) Output DC Shift (Vin changed from 0 to 100 mVrms) dB LOGIC INPUTS (Pins 4, 8, 12) Timing (Vin @ Pins 3 and 14 = 300 mVrms, See Figures 1, 2) Comp. Mute (Pin 4) to Comp. Output Low-to-High High-to-Low Exp. Mute (Pin 12) to Exp. Output Low-to-High High-to-Low Passthrough (Pin 8) to Comp. Output Low-to-High High-to-Low Passthrough (Pin 8) to Exp. Output Low-to-High High-to-Low µA µs OP AMPS (Pins 6, 7, 9, 10) mA % MISCELLANEOUS Power Supply Current @ VCC = 3.6 V @ VCC = 7.0 V ICC Reference Voltage Vb Channel Separation Expander to Compressor (Pin 14 = 316 mVrms @ 1.0 kHz and Pin 3 = 0 mVrms) (Pin 14 = 100 mVrms (300 Hz < f < 20 kHz), Pin 3 = 100 mVrms @ 1.2 kHz) Compressor to Expander (Pin 3 = 1.0 Vrms @ 1.0 kHz and Pin 14 = 0 mVrms) (Pin 3 = 100 mVrms (300 Hz < f < 20 kHz), Pin 14 = 100 mVrms @ 1.2 kHz) CS Page 4 of 12 www.lansdale.com mA Vdc dB 40 70 — — 96 — 60 100 — — 97 — Issue A ML33111 LANSDALE Semiconductor, Inc. TEMPERATURE PERFORMANCE (Typical performance based on device characterization, not guaranteed.) – 40°C +25°C + 85°C Power Supply Current @ VCC = 3.6 V @ VCC = 7.0 V 1.2 mA 1.4 mA 1.5 mA 1.7 mA 1.6 mA 1.9 mA Reference Voltage (Vb) 1.495 V 1.5 V 1.505 V 0 dB Gain (Vin = 100 mVrms) — Compressor 0.08 dB 0 dB – 0.04 dB 0 dB Gain (Vin = 100 mVrms) — Expander 0.04 dB 0 dB – 0.03 dB Total Harmonic Distortion (Vin = 100 mVrms) — Compressor 0.3% 0.2% 0.2% Total Harmonic Distortion (Vin = 100 mVrms) — Expander 0.3% 0.2% 0.16% Gain Tracking Relative to 0 dB Gain — Compressor Vin = 1.0 Vrms Vin = 1.0 mVrms 10.8 dB –19.95 dB 10 dB – 20 dB 10 dB – 20.1 dB Gain Tracking Relative to 0 dB Gain — Expander Vin = 316 mVrms Vin = 10 mVrms 18.6 dB – 40.2 dB 20 dB – 40 dB 19.95 dB – 39.9 dB Muting (∆ Gain) with Pin 4 = High (Vin = 1.0 Vrms) — Compressor 68 dB 67 dB 66 dB Muting (∆ Gain) with Pin 12 = High (Vin = 0.316 Vrms) — Expander 76 dB 76 dB 75 dB Characteristic Figure 1. Mute Timing Compressor or Expander Mute Input tEMLH tCMLH tCMHL tEMHL Compressor or Expander Output Figure 2. Passthrough Timing Passthrough Input Compressor Output Expander Output Page 5 of 12 www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. Figure 4. Transfer Characteristics Figure 3. Transfer Characteristics 20 Vout , OUTPUT VOLTAGE (dB) Vout , OUTPUT VOLTAGE (mVrms) 1000 100 Compressor 10 Expander 0 Compressor – 20 Expander 0 dB = 100 mVrms 1.0 1.0 10 100 – 40 – 40 1000 – 20 Vin, INPUT VOLTAGE (mVrms) Figure 5. Frequency Response (Compressor) 10 Vin = 1.0 mVrms OUTPUT RELATIVE TO INPUT (dB) OUTPUT RELATIVE TO INPUT (dB) 15 Vin = 10 mVrms 5.0 0 Vin = 100 mVrms – 5.0 –10 –15 100 Vin = 1.0 Vrms 1000 20 Figure 6. Frequency Response (Expander) 15 25 20 0 Vin, INPUT VOLTAGE (dB) 10k 100k Vin = 316 mVrms 5.0 Vin = 100 mVrms 0 – 5.0 Vin = 31.6 mVrms –15 Vin = 10 mVrms – 25 – 35 100 1000 10k 100k f, FREQUENCY (Hz) f, FREQUENCY (Hz) Figure 7. Attack and Decay Times (Compressor) Figure 8. Attack and Decay Times (Expander) V1 V2 Output (Pin 15) Output (Pin 2) 90 mV V2 Input (Pin 3) 100 mV 360 mV 200 mV Input (Pin 14) Attack Time = Time to 1.5 x V1 from input increase. Decay Time = Time to 0.75 x V2 from input decrease. Test per EIA-553. Page 6 of 12 V1 Attack Time = Time to 0.57 x V1 from input increase. Decay Time = Time to 1.5 x V2 from input decrease. Test per EIA-553. www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. Figure 10. Attack and Decay Times (Expander) 100 80 80 Decay Time 60 t, TIME (ms) t, TIME (ms) Figure 9. Attack and Decay Times (Compressor) 100 40 60 20 20 Attack Time 0 0 1.0 2.0 3.0 4.0 0 0 5.0 2.0 3.0 4.0 5.0 Figure 11. Compressor Gain Tracking versus Temperature Figure 12. Expander Gain Tracking versus Temperature 2.0 GAIN DRIFT VS +25° C (dB) GAIN DRIFT VS +25° C (dB) 1.0 C, CAPACITANCE AT PIN 11 (µF) 0 Shaded area depicts typical drift range 1.0 mVrms ≤ Vin ≤ 1.0 Vrms – 20 0 20 40 60 85 1.0 0 –1.0 Shaded area depicts typical drift range 10 mVrms ≤ Vin ≤ 316 mVrms – 2.0 – 40 TA, AMBIENT TEMPERATURE (°C) – 20 0 20 40 60 85 TA, AMBIENT TEMPERATURE (°C) Figure 13. THD versus Temperature Figure 14. Logic Inputs’ Current 120 1.0 100 I in , INPUT CURRENT ( µA) TOTAL HARMONIC DISTORTION (%) Attack Time C, CAPACITANCE AT PIN 5 (µF) 1.0 –1.0 – 40 Decay Time 40 0.5 Compressor Expander 0 – 40 – 20 0 20 40 60 85 80 60 40 0 0 TA, AMBIENT TEMPERATURE (°C) Page 7 of 12 Pins 4, 8, 12 Vin ≤ VCC 20 2.0 4.0 6.0 7.0 Vin, INPUT VOLTAGE (V) www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. FUNCTIONAL DESCRIPTION Introduction The ML33111 compander (COMpressor and exPANDER) is composed of two variable gain circuits which provide compression and expansion of a signal’s dynamic range. The compressor will take a signal with a 60 dB dynamic range (1.0 mV to 1.0 Vrms), and reduce that to a 30 dB dynamic range (10 mV to 316 mV) by attenuating strong signals, while amplifying low level signals. The expander does the opposite in that the 30 dB signal range is increased to a dynamic range of 60 dB by amplifying strong signals and attenuating low level signals. The 0 dB level is internally set at 100 mVrms — that is the signal level which is neither amplified nor attenuated. Both circuits contain the necessary precision full wave rectifier, variable gain cell, and temperature compensated references required for accurate and stable performance. Both the compressor and expander can be muted independently by the use of Pins 4 and 12, respectively. A minimum of 55 dB of muting is guaranteed for the compressor, and 60 dB for the expander. A passthrough function (Pin 8) is provided which sets both sections to unity gain, regardless of input level. Two uncommitted op amps are provided which can be used for perpherial functions. Each is internally biased at Vb (≈ +1.5 V), and has a bandwidth of ≈300 kHz. NOTE: All dB values mentioned in this data sheet, unless otherwise noted, are referenced to 100 mVrms. Figure 15. Compressor 5 1.0 µF 40 k Rectifier ICONTROL Iref ∆ Gain VCC 7.5 k Input 3 2 10 k Vb Compressor The compressor is a noninverting amplifier with a fixed input resistor and a variable gain cell in its feedback path as shown in Figure 15. The amplifier output is sampled by the precision rectifier which, in turn, supplies a DC signal (ICONTROL), representative of the rectifier’s AC signal, to the variable gain cell. The reference current (IREF) is an internally generated precision current. The effective impedance of the variable gain cell varies with the ratio of the two currents, and decreases as ICONTROL increases, thereby providing compression. The output is related to the input by the following equation (Vin and Vout are rms volts): V out 0.3162 x V in In terms of dB levels, the relationship is: Vo(dB) = 0.5 x Vi(dB) where 0 dB = 100 mVrms (See Figures 3 and 4). (1) (2) The input and output are internally biased at Vb (≈ +1.5 V), and must therefore be capacitor coupled to external circuitry. Pin 3 input impedance is nominally 10 kΩ (±20%), and the Page 8 of 12 Output maximum functional input signal is listed in the Recommended Operating Conditions table. Bias currents required by the op amp and the variable gain cell are internally supplied. Due to clamp diodes at the input (to VCC and ground), the input signal must be maintained between the supply rails. If the input signal goes more than 0.5 V above VCC or below ground, excessive currents will flow, and distortion will show up at the output and possibly in other parts of the circuit. When AC signals are not present at the input, the variable gain cell will attempt to set a very high gain to comply with Equation 2. An internal clamp limits the maximum gain to ≈26 dB to prevent instabilities. The output of the rectifier is filtered by the capacitor at Pin 5, which, in conjunction with an internal 20 k resistor, provides the time constant for the attack and decay times.The attack and decay times listed in the Electrical Characteristics were determined using the test procedure defined in EIA-553. Figure 9 indicates how the times vary with the capacitor value. If the attack and decay times are decreased using a smaller capacitor, performance at low frequencies will degrade. www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. Figure 16. Expander 11 40 k 1.0 µF Rectifier VCC Input 14 20 k ICONTROL 15 k 15 ∆ Gain Vb Output Iref Expander The expander is an noninverting amplifier with a fixed feedback resistor and a variable gain cell in its input path as shown in Figure 16. The input signal is sampled by the precision rectifier which, in turn, supplies a DC signal (ICONTROL), representative of the AC input signal, to the variable gain cell. The reference current (IREF) is an internally generated precision current. The effective impedance of the variable gain cell varies with the ratio of the two currents, and decreases as ICONTROL increases, thereby providing expansion. The output is related to the input by the following equation (Vin and Vout are rms volts): Vout = 10 x (Vin)2 In terms of dB levels, the relationship is: Vo(dB) = 2.0 x Vi(dB) where 0 dB = 100 mVrms (See Figures 3 and 4). flows into the pin. The outputs can typically supply a maximum of 3.7 mA load current (see Electrical Characteristics). NOTE: If an op amp is unused, its output MUST be tied to its input (Pin 6 to 7 and/or 9 to 10). Leaving an input open can affect other portions of the IC. Logic Inputs The three inputs (Pins 4, 8, 12) provide for muting and passthrough functions for the compressor and expander according to the following truth table: (3) CM (Pin 4) EM (Pin 12) PT (Pin 8) (4) 0 0 0 Normal Operation The input and output are internally biased at Vb (≈ +1.5 V), and must therefore be capacitor coupled to external circuitry. The input impedance at Pin 14 is nominally 10.9 kΩ (±20%), and the maximum functional input signal is listed in the Recommended Operating Conditions table. Bias currents required by the op amp and the variable gain cell are internally supplied. Due to clamp diodes at the input (to VCC and ground), the input signal must be maintained between the supply rails. If the input signal goes more than 0.5 V above VCC or below ground, excessive currents will flow, and distortion will show up at the output, and possibly in other parts of the circuit. The output of the rectifier is filtered by the capacitor at Pin 11, which, in conjunction with an internal 20 k resistor, provides the time constant for the attack and decay times. The attack and decay times listed in the Electrical Characteristics were determined using the test procedure defined in EIA-553. Figure 10 indicates how the times vary with the capacitor value. If the attack and decay times are decreased by using a smaller capacitor, performance at low frequencies will degrade. Function 1 X X Compressor Mute X 1 X Expander Mute 0 0 1 Passthrough The logic section permits the compressor and expander to be muted independently. The Passthrough control affects both sections simultaneously, but only if the Mute inputs are at a logic level 0. If both the Passthrough and a Mute input are asserted, the Mute will override the Passthrough. The logic controls do not affect the two uncommitted op amps in any way. Figure 17 depicts a typical logic input stage configuration, and Figure 14 indicates the typical input current. The inputs’ threshold is ≈ +1.3 V, independent of VCC. An open input is equivalent to a logic low, but good design practices dictate that inputs should never be left open. The inputs must be kept within the range of VCC and GND. If an input is taken more than 0.5 V above VCC or below GND excessive currents will flow, and the device’s operation will be distorted. Figure 17. Logic Input Stage Op Amps The two op amps (at Pins 6, 7, 9, and 10) are identical and can be used for peripheral functions, such as a microphone amplifier, buffer, filter, etc. They have an open loop gain of ≈100 dB, and a bandwidth of ≈ 300 kHz. The noninverting inputs are internally biased at Vb (≈ +1.5 V). The inverting inputs (Pins 7, 9) require a bias current of ≈ 8.0 nA, which Page 9 of 12 www.lansdale.com VCC Pins 4, 8, 12 50 k 50 k Issue A ML33111 LANSDALE Semiconductor, Inc. Power Supply The ML33111 requires a supply voltage between 3.0 V and 7.0 V, and a nominal current of ≈ 1.6 mA. The supply voltage should be well filtered and free of ripple. A minimum of 4.7 µF in parallel with a 0.01 µF capacitor is recommended for filtering and RF bypass. Vb is an internally generated reference set at ≈ +1.5 V, and is used internally as an AC ground. It is not available directly at any pins, but can be obtained as a buffered reference from either op amp by connecting the op amp as a follower. LEGACY APPLICATIONS INFORMATION Typical Application Circuit Figure 18 indicates a typical implementation of the ML33111 compander. The following points apply: a) The values shown adjacent to some components are based on the expected use of the IC: —The input capacitors (Pins 3 and 14) provide a 3.0 dB rolloff of ≈ 30 Hz, a decade below the nominal voiceband. — The rectifier capacitors provide attack and decay times as indicated in the Electrical Tables. b) The values for the unlabeled components are application dependent: — The components around the op amps depend on their use. — The value of the capacitors at the compressor and expander outputs depend on the circuit to which they are connected. c) If either the compressor or expander is not used, its input must not be left open. It can be connected to ground either through a capacitor, or directly to ground. d) The two op amps can be used for any purpose which suits the application. The indicated use of the one op amp as a micro phone amplifier is only an example. e) If an op amp is not used, its output and input must be connected together. Do not leave Pin 7 or Pin 9 open. f) The logic inputs (Pins 4, 8, 12) are TTL/CMOS compatible. The logic high voltage must not exceed the VCC voltage on the ML33111. Any unused input should be connected to ground and not left open. Figure 18. Typical Application Expander Input 0.47 1.0 µF 14 20 k ML33111 15 k 11 ∆ Gain 40 k 15 Expander Output 2 Compressor Output Vb Rectifier Compressor Input 10 k 3 Vb 0.47 1.0 µF 7.5 k ∆ Gain 5 16 Bias & Reference Generator 40 k Rectifier 4.7/ 0.01 1 VCC V+ 10 Microphone 9 4 Vb Vb 7 Signal-To-Noise Improvement Among the basic reasons for the original development of compander type circuits was to improve the signal-to-noise ratio of long distance communications circuits, and of voice circuits which are transmitted over RF links (CBs, walkie-talkies, cordless phones, etc.). Since much of the interfering noise heard at the receiving end of a transmission is due to noise picked up, for example, in the airway portion of the RF link, the compressor was developed to increase the low-level signals at the transmitting end. Then any noise picked up in the RF link would be a smaller percentage of the transmitted signal Page 10 of 12 Mute/ Passthrough Logic 6 CM 12 EM 8 PT µP or Other Control Circuit (See Text For Component Values) level. At the receiving end, the signal is then expanded back to its original level, retaining the same high signal-to-noise ratio. While the above explanation indicates it is not necessary to attenuate strong signals (at the transmitting end), a benefit of doing this is the reduced dynamic range which must be handled by the system transmitter and receiver. The ML33111 was designed for a two-to-one compression and expansion, i.e. a 60 dB dynamic signal is compressed to a 30 dB dynamic range, transmitted to the receiving end, and then expanded back to a 60 dB dynamic range. www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. Legacy Applications Information The ML33111 compander is not limited to RF or long distance telephony applications. It can be used in any system requiring either an improved signal-to-noise ratio, or a reduced dynamic range. Such applications include telephones, speakerphones, tape recorders, wireless microphones, digital recording, and many others. Power Supplies, Grounding The PC board layout, and the quality of the power supplies and the ground system at the IC are very important in order to obtain proper operation. Noise, from any source, coming into the device on VCC or ground, can cause a distorted output, or incorrect gain levels. VCC must be decoupled to the appropriate ground at the IC (within 1” max.) with a 4.7 µF capacitor and a 0.01 µF ceramic. A tantalum capacitor is recommended for the larger value if very high frequency noise is present, since electrolytic capacitors simply have too much inductance at those frequencies. The quality of the power supply voltage should be checked at the IC with a high frequency scope. Noise spikes (always present if digital circuits are near this IC) can easily exceed 400 mV, and if they get into the IC, the output can have noise or distortion. Noise can be reduced by inserting resistors and/or inductors between the supply and the IC. If switching power supplies are used, there will be spikes of 0.5 V or greater at frequencies of 50 kHz – 1.0 MHz. These spikes are generally more difficult to reduce because of their greater energy content. In extreme cases, a 3-terminal regulator (e.g., MC78L05ACP), with appropriate high fre- quency filtering, should be used and dedicated to the analog portion of the circuit. The ripple content of the supply should not allow its magnitude to exceed the values in the Recommended Operating Conditions table. The PC board tracks supplying VCC and ground to the ML33111 should preferably not be at the tail end of the bus distribution, after passing through a maze of digital circuitry. The analog circuitry containing the ML33111 should be close to the power supply, or the connector where the supply voltages enter the board. If VCC is supplying considerable current to other parts of the board, then it is preferable to have dedicated lines directly to the ML33111 and associated circuitry. PC Board Layout Although this device is intended for use in the audio frequency range, the various amplifiers have a bandwidth of ≈300 kHz, and can therefore oscillate at frequencies outside the voiceband should there be excessive stray capacitance or other unintended feedback loops. A solid ground plane is strongly recommended to minimize coupling of any digital noise into the analog section. Use of wire wrapped boards should definitely be avoided. Since many applications of the ML33111 compander involve voice transmission over RF links, care must be taken in the design of the product to keep RF signals out of the ML33111 and associated circuitry. This involves proper layout of the PC boards and the physical arrangement of the boards, shielding, proper RF ground, etc. DEFINITIONS Attack Time — The settling time for a circuit after its input signal has been increased. Attenuation — A decrease in magnitude of a communication signal, usually expressed in dB. Bandwidth — The range of information carrying frequencies of a communication system. Channel Separation — The ability of one circuit to reject outputting signals which are being processed by another circuit. Also referred to as crosstalk rejection, it is usually expressed in dB. Compander — A contraction of the words compressor and expander. A compander is composed of two circuits, one of each kind. Compressor — A circuit which compresses, or reduces, the dynamic range of a signal by attenuating strong signals and amplifying low level signals. 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 signals, and 20 x log (V1/V2) for voltage signals. dBm — An indication of signal power. 1.0 mW across 600 Ω, or 0.775 Vrms, is typically defined as 0 dBm for telecom applications. Any voltage level is converted to dBm by: dBm = 20 x log (Vrms/0.775), or dBm = [20 x log (Vrms)] + 2.22. dBrn — Indicates a dBm measurement relative to 1.0 pW power level into 600 Ω. Generally used for noise measurements, 0 dBm = –90 dBm. Page 11 of 12 dBrnC— Indicates a dBrn measurement using a C-message weighting filter. Decay Time— The settling time for a circuit after its input signal has been decreased. Expander— A circuit which expands, or increases the dynamic range of a signal by amplifying strong signals and attenuating low level signals. 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. Mute— Reducing the level of an audio signal, generally so that it is inaudible. Partial muting is used in some applications. Passthrough— Bypassing the compression and/or expansion function by setting the gain to a fixed value (usually unity). This is usually employed when data, rather than voice, is to be transmitted without attenuation. 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. Signal to Noise Ratio— The ratio of the desired signal to unwanted signals (noise) within a defined frequency range. The larger the number, the better. Voiceband— That portion of the audio frequency range used for transmission in the telephone system. Typically it is 300-3400 Hz. Zero dB Point— The signal level which has its amplitude unchanged by a compressor or expander. www.lansdale.com Issue A ML33111 LANSDALE Semiconductor, Inc. OUTLINE DIMENSIONS P DIP 16 = EP (ML33111EP) PLASTIC PACKAGE CASE 648-08 -A16 9 1 8 NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: INCH. 3. DIMENSION L TO CENTER OF LEADS WHEN FORMED PARALLEL. 4. DIMENSION B DOES NOT INCLUDE MOLD FLASH. 5. ROUNDED CORNERS OPTIONAL. B F C DIM A B C D F G H J K L M S L S SEATING PLANE -TK H G D 16 PL 0.25 (0.010) M M J T A M SO 16 = -5P (ML33111-5P) PLASTIC PACKAGE CASE 751B-05 16 9 -B- P 8 PL 0.25 (0.010) 8 M B M G K F R X 45° C -TSEATING PLANE M D 16 PL 0.25 (0.010) M T B S A MILLIMETERS 0.740 0.770 0.250 0.270 0.145 0.175 0.015 0.021 0.040 0.070 0.100 BSC 0.050 BSC 0.008 0.015 0.110 0.130 0.295 0.305 0° 10° 0.020 0.040 18.80 19.55 6.85 6.35 4.44 3.69 0.53 0.39 1.77 1.02 2.54 BSC 1.27 BSC 0.38 0.21 3.30 2.80 7.74 7.50 10° 0° 0.51 1.01 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 0.127 (0.005) TOTAL IN EXCESS OF THE D DIMENSION AT MAXIMUM MATERIAL CONDITION. -A- 1 INCHES J DIM A B C D F G J K M P R MILLIMETERS INCHES 9.80 10.00 4.00 3.80 1.75 1.35 0.49 0.35 1.25 0.40 1.27 BSC 0.25 0.19 0.25 0.10 7° 0° 6.20 5.80 0.50 0.25 0.386 0.393 0.150 0.157 0.054 0.068 0.014 0.019 0.016 0.049 0.050 BSC 0.008 0.009 0.004 0.009 7° 0° 0.229 0.244 0.010 0.019 S Lansdale Semiconductor reserves the right to make changes without further notice to any products herein to improve reliability, function or design. Lansdale does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others. “Typical” parameters which may be provided in Lansdale data sheets and/or specifications can vary in different applications, and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by the customer’s technical experts. Lansdale Semiconductor is a registered trademark of Lansdale Semiconductor, Inc. Page 12 of 12 www.lansdale.com Issue A