HCC/HCF4047B LOW-POWER MONOSTABLE/ASTABLE MULTIVIBRATOR . . . .. . . .. .. LOW POWER CONSUMPTION : SPECIAL COS/MOS OSCILLATOR CONFIGURATION MONOSTABLE (one-shot) OR ASTABLE (freerunning) OPERATION TRUE AND COMPLEMENTED BUFFERED OUTPUTS ONLY ONE EXTERNAL R AND C REQUIRED BUFFERED INPUTS QUIESCENT CURRENT SPECIFIED TO 20V FOR HCC DEVICE STANDARDIZED, SYMMETRICAL OUTPUT CHARACTERISTICS 5V, 10V, AND 15V PARAMETRIC RATINGS INPUT CURRENT OF 100nA AT 18V AND 25°C FOR HCC DEVICE 100% TESTED FOR QUIESCENT CURRENT MEETS ALL REQUIREMENTS OF JEDEC TENTATIVE STANDARD N° 13A, ”STANDARD SPECIFICATIONS FOR DESCRIPTION OF ”B” SERIES CMOS DEVICES” EY (Plastic Package) M1 (Micro Package) F (Ceramic Frit Seal Package) C1 (Plastic Chip Carrier) ORDER CODES : HCC4047BF HCF4047BM1 HCF4047BEY HCF4047BC1 PIN CONNECTIONS DESCRIPTION The HCC4047B (extended temperature range) and HCF4047B (intermediate temperature range) are monolithic integrated circuits, available in 14-lead dual in-line plastic or ceramic package and plastic micropackage. The HCC/HCF4047B consists of a gatable astable multivibrator with logic techniques incorporated to permit positive or negative edgetriggered monostable multivibrator action with retriggering and external counting options. Inputs include +TRIGGER -TRIGGER, ASTABLE, ASTABLE, RETRIGGER, and EXTERNAL RESET. Buffered outputs are Q, Q, and OSCILLATOR. In all modes of operation, an external capacitor must be connected between C-Timing and RC-Common terminals, and an external resistor must be connected between the R-Timing and RC-Common terminals. For operating modes see functional terminal connections and application notes. June 1989 1/15 HCC/HCF4047B BLOCK DIAGRAM FUNCTIONAL TERMINAL CONNECTIONS Terminal Connections Function* Astable Multivibrator : Free Running True Gating Complement Gating Monostable Multivibrator : Positive–Edge Trigger Negative–Edge Trigger Retriggerable External Countdown** to V DD to V SS Input Pulse to 4, 5, 6, 14 4, 6, 14 6, 14 7, 8, 9, 12 7, 8, 9, 12 5, 7, 8, 9 ,12 – 5 4 4, 14 4, 8, 14 4, 14 14 5, 6, 7, 9, 12 5, 7, 9, 12 5, 6, 7, 9 5, 6, 7, 8, 9, 12 8 6 8, 12 – * In all cases external capacitor and resistor between pins, 1, 2 and 3 (see logic diagrams). ** Input pulse to Reset of External Counting Chip. External Counting Chip Output to pin 4. 2/15 Output Pulse From Output Period or Pulse Width 10, 11, 13 10, 11, 13 10, 11, 13 t A (10, 11) = 4.40RC 10, 10, 10, 10, 11 11 11 11 t A (13) = 2.20RC tM (10, 11) = 2.48RC HCC/HCF4047B ABSOLUTE MAXIMUM RATINGS Symbol V DD * Parameter Supply Voltage : HCC Types HCF Types Value Unit – 0.5 to + 20 – 0.5 to + 18 V V Vi Input Voltage – 0.5 to V DD + 0.5 V II DC Input Current (any one input) ± 10 mA Total Power Dissipation (per package) Dissipation per Output Transistor for Top = Full Package-temperature Range 200 mW 100 mW P tot T op Operating Temperature : HCC Types HCF Types – 55 to + 125 – 40 to + 85 °C °C T s tg Storage Temperature – 65 to + 150 °C Stresses above those listed under ”Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for external periods may affect device reliability. * All voltage values are referred to VSS pin voltage. RECOMMENDED OPERATING CONDITIONS Symbol V DD VI Top Parameter Supply Voltage : HC C Types H C F Types Input Voltage Operating Temperature : H CC Types H C F Types Value Unit 3 to 18 3 to 15 V V 0 to V DD V – 55 to + 125 – 40 to + 85 °C °C LOGIC DIAGRAM 3/15 HCC/HCF4047B Detail for Flip-flops FF1 and FF3 (a) and for Flip-flops FF2 and FF4 (b). STATIC ELECTRICAL CHARACTERISTICS (over recommended operating conditions) Test Conditions Symbol IL V OH V OL V IH Parameter Quiescent Current Output High Voltage Output Low Voltage Input High Voltage VI (V) VO (V) Value |IO| V DD (µA) (V) T Low * Min. 25°C Max. Min. T Hi gh * Typ. Max. Min. Max. 0/ 5 5 1 0.02 1 HCC 0/10 Types 0/15 10 2 0.02 2 60 15 4 0.02 4 120 0/20 20 20 0.04 20 600 0/ 5 5 4 0.02 4 30 HCF 0/10 Types 0/15 10 8 0.02 8 60 0.02 16 15 16 4.95 4.95 Unit 30 µA 120 0/ 5 < 1 5 4.95 0/10 < 1 10 9.95 9.95 9.95 0/15 < 1 15 14.95 14.95 14.95 V 5/0 < 1 5 0.05 0.05 0.05 10/0 < 1 10 0.05 0.05 0.05 15/0 < 1 15 0.05 0.05 0.05 0.5/4.5 < 1 5 3.5 3.5 3.5 1/9 < 1 10 7 7 7 1.5/13.5 < 1 15 11 11 11 V V * TLo w = – 55°C for HCC device : – 40°C for HCF device. * THigh = + 125°C for HCC device : + 85°C for HCF device. The Noise Margin for both ”1” and ”0” level is : 1V min. with VDD = 5V, 2V min. with VDD = 10V, 2.5V min. with VDD = 15V. 4/15 HCC/HCF4047B STATIC ELECTRICAL CHARACTERISTICS (continued) Test Conditions Symbol V IL I OH I OL I IH , IIL CI Parameter VI (V) Input Low Voltage Output Drive Current Output Sink Current Input leakage Curent VO (V) Value |IO| V DD (µA) (V) T Low * Min. 25°C Max. Min. T Hi gh * Typ. Max. Min. Max. 4.5/0.5 < 1 5 1.5 1.5 1.5 9/1 < 1 10 3 3 3 13.5/1.5 < 1 15 4 4 4 0/ 5 2.5 5 –2 – 1.6 – 3.2 – 1.15 0/ 5 HCC Types 0/10 4.6 5 – 0.64 – 0.51 – 0.36 9.5 10 – 1.6 – 1.3 – 2.6 – 0.9 0/15 13.5 15 – 4.2 – 3.4 – 6.8 – 2.4 0/ 5 2.5 5 – 1.53 – 1.36 – 3.2 – 1.1 0/ 5 HCF Types 0/10 4.6 5 – 0.52 – 0.44 – 0.36 9.5 10 – 1.3 – 1.1 – 2.6 – 0.9 0/15 13.5 15 – 3.6 – 3.0 – 6.8 – 2.4 0/ 5 0.4 5 0.64 0.51 1 0.36 HCC 0/10 Types 0/15 0.5 10 1.6 1.3 2.6 0.9 1.5 15 4.2 3.4 6.8 2.4 0/ 5 0.4 5 0.52 0.44 1 0.36 HCF 0/10 Types 0/15 0.5 10 1.3 1.1 2.6 0.9 1.5 15 3.6 3.0 6.8 2.4 HCC 0/18 Types –1 V mA mA 18 ± 0.1 ±10–5 ± 0.1 ±1 15 ± 0.3 ±10–5 ± 0.3 ±1 µA Any Input HCF 0/15 Types Input Capacitance –1 Unit Any Input 5 7.5 pF * TLow = – 55°C for HCC device : – 40°C for HCF device. * THigh = + 125°C for HCC device : + 85°C for HCF device. The Noise Margin for both ”1” and ”0” level is : 1V min. with VDD = 5V, 2V min. with VDD = 10V, 2.5V min. with VDD = 15V. DYNAMIC ELECTRICAL CHARACTERISTICS (Tamb = 25°C, CL = 50pF, RL = 200kΩ, typical temperature coefficient for all VDD values is 0.3%/°C, all input rise and fall times = 20ns) Test Conditions Symbol tPLH, tPHL Parameter Propagation Delay Time Astable, Astable to osc. out Astable, Astable to Q, Q + or – Trigger to Q, Q Value V DD (V) Min. Typ. Max. 5 200 400 10 100 200 15 80 160 5 350 700 10 175 350 15 125 250 5 500 1000 10 225 450 15 150 300 Unit ns 5/15 HCC/HCF4047B DYNAMIC ELECTRICAL CHARACTERISTICS (continued) Test Conditions Symbol tPLH, tPHL Parameter Propagation Delay Time Retrigger to Q, Q External Reset to Q, Q tTHL, tT LH tw Transition Time Osc. Out Q, Q Input Pulse Width : + Trigger, – Trigger Reset Retrigger t r, tf Input Rise and Fall Time All Inputs Value V DD (V) Min. Typ. Max. 5 300 600 10 150 300 15 100 200 5 250 500 10 100 200 15 70 140 5 100 200 10 50 100 15 40 80 5 200 400 10 80 160 15 50 100 5 100 200 10 50 100 15 30 60 5 300 600 10 115 230 15 75 150 Unit ns 5 10 µs Unlimited 15 Q or Q Deviation from 50% Duty Factor Typical Output Low (sink) Current Characteristics. 6/15 5 ± 0.5 ±1 10 ± 0.5 ±1 15 ± 0.1 ± 0.5 Minimum Output Low (sink) Current Characteristics. % HCC/HCF4047B Typical Output High (source) Current Characteristics. Minimum Output High (source) Current Characteristics. APPLICATION INFORMATION 1 - CIRCUIT DESCRIPTION Astable operation is enabled by a high level on the ASTABLE input. The period of the square wave at the Q and Q Outputs in this mode of operation is a function of the external components employed. ”True” input pulses on the ASTABLE input or ”Complement” pulses on the ASTABLE input allow the circuit to be used as a gatable multivibrator. The OSCILLATOR output period will be half of the Q terminal output in the astable mode. However, a 50% duty cycle is not guaranteed at this output. In the monostable mode, positive-edge triggering is accomplished by application of a leading-edge pulse to the +TRIGGER input and a low level to the –TRIGGER input. For negative-edge triggering, a trailing-edge pulse is applied to the –TRIGGER and a high level is applied to the +TRIGGER. Input pulses may be of any duration relative to the output pulse. The multivibrator can be retriggered (on the leading edge only) by applying a common pulse to both the RETRIGGER and +TRIGGER inputs. In this mode the output pulse remains high as long as the input pulse period is shorter than the period determined by the RC components. An external countdown option can be implemented by coupling ”Q” to an external ”N” counter and resetting the counter with the trigger pulse. The counter output pulse is fed back to the ASTABLE input and has a duration equal to N times the period of the multivibrator. A high level on the EXTERNAL RESET input assures no output pulse during an ”ON” power condition. This input can also be activated to terminate the output pulse at any time. In the monostable mode, a high-level or power-on reset pulse, must be applied to the EXTERNAL RESET whenever VDD is applied. 2 - ASTABLE MODE The following analysis presents worst-case variations from unit-to-unit as a function of transfer-voltage (VTR) shift (33% – 67% VDD) for free-running (astable) operation. 7/15 HCC/HCF4047B ASTABLE MODE WAVEFORMS. t1 = – RC In t2 = – RC In VTR VDD + VTR VDD – VTR 2 VDD – VTR tA = 2 (t1 + t2) = –2 RC In Typ : VTR = 0.5 VDD tA = 4.40 RC Min : VTR = 0.33 VDD tA = 4.62 RC Max : VTR = 0.67 VDD tA = 4.62 RC thus if tA = 4.40 RC is used, the maximum variation will be (+ 5.0%, – 0.0%) In addition to variations from unit-to-unit, the astable (VTR) (VDD – VTR) (VDD + VTR) (2 VDD – VTR) period may vary as a function of frequency with respect to VDD and temperature. 3 - MONOSTABLE MODE The following analysis presents worst-case variations from unit-to-unit as a function of transfer-voltage (VTR) shift (33% – 67% VDD) for one-shot (monostable) operation. MONOSTABLE WAVEFORMS. t1 = – RC In t2 = – RC In VTR 2 VDD VDD – VTR 2 VDD – VTR tM = (t1 + t2) = – RC In Where tM = monostable mode pulse width. Values for tM are as follows : Typ : VTR = 0.5 VDD tM = 2.48 RC Min : VTR = 0.33 VDD tM = 2.71 RC Max : VTR = 0.67 VDD tM = 2.48 RC Thus if tM = 2.48 RC is used, the maximum variation will be (+ 9.3%, – 0.0%). Note : In the astable mode, the first positive half cycle has a duration of TM ; succeeding durations are tA/2. In addition to variations from unit to unit, the monostable pulse width may vary as a function of frequency with respect to VDD and temperature. 4 - RETRIGGER MODE The HCC/HCF4047B can be used in the retrigger 8/15 (VTR) (VDD – VTR) (2 VDD – VTR) (2 VDD) mode to extend the output-pulse duration, or to compare the frequency of an input signal with that of the internal oscillator. In the retrigger mode the input pulse is applied to terminals 8 and 12, and the output is taken from terminal 10 or 11. As shown in fig. A normal monostable action is obtained when one retrigger pulse is applied. Extended pulse duration is obtained when more than one pulse is applied. For two input pulses, tRE = t1’ + t1 + 2t2. For more than two pulses, tRE (Q OUTPUT) terminates at some variable time tD after the termination of the last retrigger pulse. tD is variable because t RE (Q OUTPUT) terminates after the second positive edge of the oscillator output appears at flip-flop 4 (see logic diagram). HCC/HCF4047B Figure A : Retrigger-mode Waveforms. 5 - EXTERNAL COUNTER OPTION Time tM can be extended by any amount with the use of external counting circuitry. Advantages include digitally controlled pulse duration, small timing capacitors for long time periods, and extremely fast recovery time. A typical implementation is shown in fig. B. The pulse duration at the output is t ext = (N – 1) (t A ) + (t M + t A /2) Where text = pulse duration of the circuitry, and N is the number of counts used. Figure B : Implementation of External Counter Option. 6 - POWER CONSUMPTION In the standby mode (Monostable or Astable), power dissipation will be a function of leakage current in the circuit, as shown in the static electrical characteristics. For dynamic operation, the power needed to charge the external timing capacitor C is given by the following formula : Astable Mode : P = 2CV2f. (Output at Pin 13) P = 4CV2f. (Output at Pin 10 and 11) Monostable Mode : P = (2.9CV2) (Duty Cycle) T (Output at Pin 10 and 11) The circuit is designed so that most of the total power is consumed in the external components. In practice, the lower the values of frequency and volt- age used, the closer the actual power dissipation will be to the calculated value. Because the power dissipation does not depend on R, a design for minimum power dissipation would be a small value of C. The value of R would depend on the desired period (within the limitations discussed above). 7 - TIMING-COMPONENT LIMITATIONS The capacitor used in the circuit should be non-polarized and have low leakage (i.e. the parallel resistance of the capacitor should be an order of magnitude greater than the external resistor used). Three is no upper or lower limit for either R or C value to maintain oscillation. However, in consideration of accuracy, C must be much larger than the inherent stray capacitance in 9/15 HCC/HCF4047B the system (unless this capacitance can be measured and taken into account). R must be much larger than the COS/MOS ”ON” resistance in series with it, which typically is hundreds of ohms. In addition, with very large values of R, some short-term instability with respect to time may be noted. C ≥ 100pF, up to any practical value, for astable modes ; C ≥ 1000pF, up to any practical value, for monostable modes. 10KΩ ≤ R ≤ 1MΩ. The recommended values for these components to maintain agreement with previously calculated formulas without trimming should be : TEST CIRCUITS Quiescent Device Current. Input Current. 10/15 Input Voltage. HCC/HCF4047B Plastic DIP14 MECHANICAL DATA mm DIM. MIN. a1 0.51 B 1.39 TYP. inch MAX. MIN. TYP. MAX. 0.020 1.65 0.055 0.065 b 0.5 0.020 b1 0.25 0.010 D 20 0.787 E 8.5 0.335 e 2.54 0.100 e3 15.24 0.600 F 7.1 0.280 I 5.1 0.201 L Z 3.3 1.27 0.130 2.54 0.050 0.100 P001A 11/15 HCC/HCF4047B Ceramic DIP14/1 MECHANICAL DATA mm DIM. MIN. TYP. inch MAX. MIN. TYP. MAX. A 20 0.787 B 7.0 0.276 D E 3.3 0.130 0.38 e3 0.015 15.24 0.600 F 2.29 2.79 0.090 0.110 G 0.4 0.55 0.016 0.022 H 1.17 1.52 0.046 0.060 L 0.22 0.31 0.009 0.012 M 1.52 2.54 0.060 0.100 N P Q 10.3 7.8 8.05 5.08 0.406 0.307 0.317 0.200 P053C 12/15 HCC/HCF4047B SO14 MECHANICAL DATA mm DIM. MIN. TYP. A a1 inch MAX. MIN. TYP. 1.75 0.1 0.068 0.2 a2 MAX. 0.003 0.007 1.65 0.064 b 0.35 0.46 0.013 0.018 b1 0.19 0.25 0.007 0.010 C 0.5 0.019 c1 45° (typ.) D 8.55 E 5.8 8.75 0.336 6.2 0.228 0.344 0.244 e 1.27 0.050 e3 7.62 0.300 F 3.8 4.0 0.149 0.157 G 4.6 5.3 0.181 0.208 L 0.5 1.27 0.019 0.050 M S 0.68 0.026 8° (max.) P013G 13/15 HCC/HCF4047B PLCC20 MECHANICAL DATA mm DIM. MIN. TYP. inch MAX. MIN. TYP. MAX. A 9.78 10.03 0.385 0.395 B 8.89 9.04 0.350 0.356 D 4.2 4.57 0.165 0.180 d1 2.54 0.100 d2 0.56 0.022 E 7.37 8.38 0.290 0.330 e 1.27 0.050 e3 5.08 0.200 F 0.38 0.015 G 0.101 0.004 M 1.27 0.050 M1 1.14 0.045 P027A 14/15 HCC/HCF4047B Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsability for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may results from its use. No license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGS-THOMSON Microelectronics products are not authorized for use ascritical components in life support devices or systems without express written approval of SGS-THOMSON Microelectonics. 1994 SGS-THOMSON Microelectronics - All Rights Reserved SGS-THOMSON Microelectronics GROUP OF COMPANIES Australia - Brazil - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A 15/15