TECNICAL DATA Tone Ringer IL2411N/D The IL2411 is a bipolar integrated circuit designed for telephone bell replacement. Designed for Telephone Bell Replacement Low Current Drain Adjustable 2-frequency Tone Adjustable Warbling Rate Extension Tone Ringer Modules Alarms or Other Alerting Devices Adjustable for Reduced Supply Initiation Current. Built-in hysteresis prevents false triggering and rotary dial Chirps SOP 8 DIP 8 T A = -45 to 65 C ORDERIN INFORMATION Device Operating Temperature Range Package Packing IL2411N DIP8 Tube IL2411D T A = -45 to 65 C SOP8 Tube IL2411DT SOP8 Tape & Reel LOIC DIARAM PIN ASSINMENT V CC R SL LFI LF0 OUT FI F0 ND PIN 1 = V CC PIN 5 = ND 1. Output amplifier 2. igh frequency oscillator 3. Low frequency oscillator 4. ysteresis regulator (Regulator circuit has built-in hysteresis to prevent false triggering and rotary dial Chirps )
PIN DESCRIPTION Name Pin Description V CC 1 Positive power supply. R SL 2 External resistor LFI 3 Input low frequency oscillator LF0 4 Output low frequency oscillator ND 5 Negative power supply F0 6 igh frequency oscillator output FI 7 igh frequency oscillator input Out 8 Tone output MAXIMUM RATINS * Symbol Parameter Value Unit V CC DC Supply Voltage (Referenced to ND) to +30.0 V P D Power Dissipation in Still Air, Plastic DIP 400 mw Tstg Storage Temperature -65 to +150 C * Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. RECOMMENDED OPERATIN CONDITIONS Symbol Parameter Min Max Unit V CC DC Supply Voltage (Referenced to ND) 13.0 29.0 V T A Operating Temperature -45 +65 C This device contains protection circuitry to guard against damage due to high static voltages or electric fields. owever, precautions must be taken to avoid applications of any voltage higher than maximum rated voltages to this high-impedance circuit. For proper operation, V IN and V OUT should be constrained to the range ND (V IN or V OUT ) V CC. Unused inputs must always be tied to an appropriate logic voltage level (e.g., either ND or V CC ). Unused outputs must be left open.
ELECTRICAL CARACTERISTICS (Voltages Referenced to ND, T A = -20 to +70 C) uaranteed Limits Symbol Parameter Test Conditions Min Typ Max Unit V SI I SI Initiation Supply Voltage (1) Initiation Supply Current (1) See Figure 1 16.8 21.2 V 1.4 4.2 ma V SUS Sustaining Voltage (2) See Figure 1 9.5 12.2 V I SUS Sustaining Current (2) No Load V CC =V SUS See Figure 1 V O V OL I IN igh-level Output Voltage Low-Level Output Voltage Maximun Input Leakage Current (Pin 3) (Pin 7) V CC =21V, I O =-15mA, Pin 6=6V, Pin 7=ND V CC =21V, I OL =15mA, Pin 6=ND, Pin 7=6V Pin 3=6V,Pin 4=ND, V CC =21V Pin 7=6V,Pin 6=ND, V CC =21V 0.7 2.5 ma 16.7 21.0 V - 1.8 V - 1.0 A - 1.0 A f 1 igh Frequency 1 R 3 =191K,C 3 =6800pF 461 563 z f 2 igh Frequency 2 R 3 =191K,C 3 =6800pF 576 704 z f L Low Frequency R 2 =165K,C 2 =0.47 F 9.0 11.0 z Notes: 1. Initiation supply voltage (V SI ) is the supply voltage required to start the tone ringer oscillating. 2. Sustaining voltage (V SUS ) is the supply voltage required to maintain oscillation.
CIRCUIT CURRENT-SUPPLY VOLTAE (NO LOAD) Figure 1 SUPPLY CURRENT (NO LOAD) VC. SUPPLY VOLTAE Figure 2
APPLICATION CIRCUIT igure 3 F APPLICATION NOTE The application circuit illustrates the use of the IL2411 devices in typical telephone or extension tone ringer application. The AC ringer signal voltage appears across the TIP and RIN inputs of the circuit and is attenuated by capacitor C 1 and resistor R 1. C 1 also provides isolation from DC voltages (48V) on the exchange line. After full wave rectification by the bridge diode, the waveform is filtered by capacitor C 4 to provide a DC supply for the tone ringer chip. As this voltage exceeds the initiation voltage (V SI ), oscillation starts. With the components shown, the ouptut frequency chops between 512(f h1 ) and 640z(f h2 ) at a 10z(f L ) rate. The loudspeaker load is coupled through a 1300 to 8 transformer. The output coupling capacitor C 5 is required with transformer coupled loads. When driving a piezo-ceramic transducer type load, the coupling C 5 and transformer (1300 :8 ) are not required. owever, a current limiting resistor is required. The low frequency oscillator oscillates at a rate (f L ) controlled by an external resistor (R 2 ) and capacitor (C 2 ). The frequency can be determined using the relation f L =1/1.289R 2 *C 2. The high frequency oscillates at a f 1, f 2 controlled by an external resistor (R 3 ) and capacitor (C 3 ). The frequency can be determined using the relation f 1 =1/1.504R 3 *C 3, f 2 =1/1.203R 3 *C 3. Pin 2 allows connection of an external resistor R SL, which is used to program the solpe of the supply current vs supply voltage characteristics (see Fig2), and hence the supply current up to the initiation voltage ( V SI ). This initiation voltage remains constant independent of R SL. The supply current drawn prior to triggering varies inversely with R SL, decreasing for increasing value of resistance. Thus, increasing the value of R SL will decrease the amount of AC ringing current required to trigger the device. As such, longer sucribser loops are possible since less voltage is dropped per unit length of loop wire due to the lower current level. R SL can also be used to compensated for smaller AC couplin capacitors (C 5 on Fig 3) (higher impedance) to the line which can be used to alter the ringer equivalence number of a tone ringer circuit. The graph in Fig2 illustrates the variation of supply current with supply voltage. Three curves are drawn to show the variation of initiation current with R SL. Curve B( R SL =6.8K ) shows the I-V characteristic for the IL2411 tone ringer. Curve A is a plot with R SL <6.8K and shows an increase in the current drawn up to the initiation voltagev SI. The I-V characteristic after initiation remains unchanged. Curve C illustrates the effect of increasing R SL above 6.8K initiation current decreases but again current after triggering is unchanged.
N SUFFIX PLASTIC DIP (MS 001BA) A NOTES: 8 1 F 5 4 N D 0.25 (0.010) M T B C 1. Dimensions A, B do not include mold flash or protrusions. Maximum mold flash or protrusions 0.25 mm (0.010) per side. -T- -T- K SEATIN PLANE M L J Dimension, mm Symbol MIN MAX A 8.51 10.16 B 6.1 7.11 C 5.33 D 0.36 0.56 F 1.14 1.78 2.54 7.62 J 0 10 K 2.92 3.81 L 7.62 8.26 M 0.2 0.36 N 0.38 D SUFFIX SOIC (MS - 012AA) 8 1 D A B 0.25 (0.010) M T C M 5 4 K P C SEATIN PLANE J Symbol MIN MAX A 4.8 5 B 3.8 4 C 1.35 1.75 D 0.33 0.51 F 0.4 1.27 Dimension, mm J 0 8 NOTES: K 0.1 0.25 1. Dimensions A and B do not include mold flash or protrusion. M 0.19 0.25 2. Maximum mold flash or protrusion 0.15 mm (0.006) per side P 5.8 6.2 for A; for B 0.25 mm (0.010) per side. R 0.25 0.5 R x 45 F M 1.27 5.72