SN54/74LS390 SN54/74LS393 DUAL DECADE COUNTER; DUAL 4-STAGE BINARY COUNTER The SN54 / 74LS390 and SN54 / 74LS393 each contain a pair of high-speed 4-stage ripple counters. Each half of the LS390 is partitioned into a divide-by-two section and a divide-by five section, with a separate clock input for each section. The two sections can be connected to count in the 8.4.2.1 BCD code or they can count in a biquinary sequence to provide a square wave (50% duty cycle) at the final output. Each half of the LS393 operates as a Modulo-16 binary divider, with the last three stages triggered in a ripple fashion. In both the LS390 and the LS393, the flip-flops are triggered by a HIGH-to-LOW transition of their CP inputs. Each half of each circuit type has a Master Reset input which responds to a HIGH signal by forcing all four outputs to the LOW state. • • • • • Dual Versions of LS290 and LS293 LS390 has Separate Clocks Allowing ÷ 2, ÷ 2.5, ÷ 5 Individual Asynchronous Clear for Each Counter Typical Max Count Frequency of 50 MHz Input Clamp Diodes Minimize High Speed Termination Effects DUAL DECADE COUNTER; DUAL 4-STAGE BINARY COUNTER LOW POWER SCHOTTKY J SUFFIX CERAMIC CASE 620-09 16 1 N SUFFIX PLASTIC CASE 648-08 16 1 CONNECTION DIAGRAM DIP (TOP VIEW) SN54 / 74LS390 VCC CP0 MR Q0 CP1 Q1 Q2 Q3 16 15 14 13 12 11 10 9 16 1 D SUFFIX SOIC CASE 751B-03 J SUFFIX CERAMIC CASE 632-08 14 1 1 2 3 4 5 6 7 8 CP0 MR Q0 CP1 Q1 Q2 Q3 GND SN54 / 74LS393 VCC CP MR Q0 Q1 Q2 Q3 14 13 12 11 10 9 8 NOTE: The Flatpak version has the same pinouts (Connection Diagram) as the Dual In-Line Package. N SUFFIX PLASTIC CASE 646-06 14 1 14 1 D SUFFIX SOIC CASE 751A-02 ORDERING INFORMATION 1 2 3 4 5 6 7 CP MR Q0 Q1 Q2 Q3 GND SN54LSXXXJ SN74LSXXXN SN74LSXXXD FAST AND LS TTL DATA 5-544 Ceramic Plastic SOIC SN54/74LS390 • SN54/74LS393 PIN NAMES LOADING (Note a) LOW HIGH CP CP0 CP1 MR Q0 – Q3 Clock (Active LOW going edge) Input to +16 (LS393) Clock (Active LOW going edge) Input to ÷ 2 (LS390) Clock (Active LOW going edge) Input to ÷ 5 (LS390) Master Reset (Active HIGH) Input Flip-Flop outputs (Note b) 0.5 U.L. 1.0 U.L. 0.5 U.L. 1.0 U.L. 0.5 U.L. 0.5 U.L. 10 U.L. 1.5 U.L. 0.25 U.L. 5 (2.5) U.L. NOTES: a) 1 TTL Unit Load (U.L.) = 40 µA HIGH/1.6 mA LOW. b) The Output LOW drive factor is 2.5 U.L. for Military (54) and 5 U.L. for Commercial (74) b) Temperature Ranges. FUNCTIONAL DESCRIPTION Each half of the SN54 / 74LS393 operates in the Modulo 16 binary sequence, as indicated in the ÷ 16 Truth Table. The first flip-flop is triggered by HIGH-to-LOW transitions of the CP input signal. Each of the other flip-flops is triggered by a HIGH-to-LOW transition of the Q output of the preceding flip-flop. Thus state changes of the Q outputs do not occur simultaneously. This means that logic signals derived from combinations of these outputs will be subject to decoding spikes and, therefore, should not be used as clocks for other counters, registers or flip-flops. A HIGH signal on MR forces all outputs to the LOW state and prevents counting. Each half of the LS390 contains a ÷ 5 section that is independent except for the common MR function. The ÷ 5 section operates in 4.2.1 binary sequence, as shown in the ÷ 5 Truth Table, with the third stage output exhibiting a 20% duty cycle when the input frequency is constant. To obtain a ÷10 function having a 50% duty cycle output, connect the input signal to CP1 and connect the Q3 output to the CP0 input; the Q0 output provides the desired 50% duty cycle output. If the input frequency is connected to CP0 and the Q0 output is connected to CP1, a decade divider operating in the 8.4.2.1 BCD code is obtained, as shown in the BCD Truth Table. Since the flip-flops change state asynchronously, logic signals derived from combinations of LS390 outputs are also subject to decoding spikes. A HIGH signal on MR forces all outputs LOW and prevents counting. SN54 / 74LS390 LOGIC DIAGRAM (one half shown) CP1 CP0 CD K CP J Q CD K CP J Q CD K CP J Q CD K CP J Q MR Q0 Q1 Q2 Q3 SN54 / 74LS393 LOGIC DIAGRAM (one half shown) CP CD K CP J Q CD K CP J Q CD K CP J Q CD K CP J Q MR Q0 Q1 FAST AND LS TTL DATA 5-545 Q2 Q3 SN54/74LS390 • SN54/74LS393 SN54/ 74LS390 ÷ 5 TRUTH TABLE (Input on CP1) SN54 / 74LS390 BCD TRUTH TABLE (Input on CP0; Q0 CP1) OUTPUTS COUNT Q3 Q2 Q1 SN54 / 74LS393 TRUTH TABLE OUTPUTS COUNT Q0 0 1 2 L L L L L L L L H L H L 3 4 5 L L L L H H H L L H L H 6 7 8 9 L L H H H H L L H H L L L H L H OUTPUTS Q3 Q2 Q1 L L L L H L L H H L 0 1 2 3 4 COUNT L H L H L SN54 / 74LS390 ÷ 10 (50% @ Q0) TRUTH TABLE (Input on CP1, Q3 to CP0) OUTPUTS COUNT Q3 Q2 Q1 Q0 0 1 2 L L L L L H L H L L L L 3 4 5 L H L H L L H L L L L H 6 7 8 9 L L L H L H H L H L H L H H H H Q3 Q2 Q1 Q0 0 1 2 3 L L L L L L L L L L H H L H L H 4 5 6 7 L L L L H H H H L L H H L H L H 8 9 10 11 H H H H L L L L L L H H L H L H 12 13 14 15 H H H H H H H H L L H H L H L H H = HIGH Voltage Level L = LOW Voltage Level GUARANTEED OPERATING RANGES Symbol Parameter Min Typ Max Unit VCC Supply Voltage 54 74 4.5 4.75 5.0 5.0 5.5 5.25 V TA Operating Ambient Temperature Range 54 74 – 55 0 25 25 125 70 °C IOH Output Current — High 54, 74 – 0.4 mA IOL Output Current — Low 54 74 4.0 8.0 mA FAST AND LS TTL DATA 5-546 SN54/74LS390 • SN54/74LS393 DC CHARACTERISTICS OVER OPERATING TEMPERATURE RANGE (unless otherwise specified) Limits Symbol Min Parameter VIH Input HIGH Voltage VIL Input LOW Voltage VIK Input Clamp Diode Voltage VOH Output HIGH Voltage VOL Output LOW Voltage IIH Input HIGH Current IIL Input LOW Current Typ Max Unit 2.0 54 0.7 74 0.8 – 0.65 – 1.5 Test Conditions V Guaranteed Input HIGH Voltage for All Inputs V Guaranteed Input LOW Voltage for All Inputs V VCC = MIN, IIN = – 18 mA 54 2.5 3.5 V 74 2.7 3.5 V VCC = MIN, IOH = MAX, VIN = VIH or VIL per Truth Table 0.25 0.4 V IOL = 4.0 mA 74 0.35 0.5 V IOL = 8.0 mA 20 µA VCC = MAX, VIN = 2.7 V VCC = MAX, VIN = 7.0 V 0.1 mA MR – 0.4 mA CP, CP0 – 1.6 mA CP1 – 2.4 mA – 100 mA VCC = MAX 26 mA VCC = MAX IOS Short Circuit Current (Note 1) ICC Power Supply Current VCC = VCC MIN, VIN = VIL or VIH per Truth Table 54, 74 – 20 VCC = MAX, VIN = 0.4 V Note 1: Not more than one output should be shorted at a time, nor for more than 1 second. AC CHARACTERISTICS (TA = 25°C, VCC = 5.0 V) Limits Symbol Parameter Min Typ 35 fMAX Maximum Clock Frequency CP0 to Q0 25 fMAX Maximum Clock Frequency CP1 to Q1 20 tPLH tPHL Propagation Delay, CP to Q0 LS393 Max Unit MHz MHz 12 13 20 20 ns tPLH tPHL CP0 to Q0 LS390 12 13 20 20 ns tPLH tPHL CP to Q3 LS393 40 40 60 60 ns 60 60 ns tPLH tPHL CP0 to Q2 LS390 37 39 tPLH tPHL CP1 to Q1 LS390 13 14 21 21 ns tPLH tPHL CP1 to Q2 LS390 24 26 39 39 ns tPLH tPHL CP1 to Q3 LS390 13 14 21 21 ns LS390/393 24 39 ns tPHL MR to Any Output Test Conditions FAST AND LS TTL DATA 5-547 CL = 15 pF SN54/74LS390 • SN54/74LS393 AC SETUP REQUIREMENTS (TA = 25°C, VCC = 5.0 V) Limits Symbol Min Parameter Typ Max Unit tW Clock Pulse Width LS393 20 ns tW CP0 Pulse Width LS390 20 ns tW CP1 Pulse Width LS390 40 ns tW MR Pulse Width LS390/393 20 ns trec Recovery Time LS390/393 25 ns Test Conditions VCC = 5.0 V AC WAVEFORMS Figure 1 Figure 2 *The number of Clock Pulses required between tPHL and tPLH measurements can be determined from the appropriate Truth Table. FAST AND LS TTL DATA 5-548 Case 751B-03 D Suffix 16-Pin Plastic SO-16 -A- "! ! " " ! " # 1 %# ) ! !" $ !" 8 C -T- D M K " ! #! J F ! Case 648-08 N Suffix 16-Pin Plastic R X 45° G " ! ) #! P ! " " 9 -B- ! 16 & ! ! ° ° ° ° ( ( ( ( "! ! " " ! ! ' " " ! ' ! " # & -A- 16 9 1 8 ! ! $ ! B # ) " ! " # ) !" $ !" ) F L C S -T- K H G M J D " Case 620-09 J Suffix 16-Pin Ceramic Dual In-Line -A- ! ! ! ! ° ° ° ° "! ! " 16 " ) " L K M N J G D " $ " $ ! " " ! ! FAST AND LS TTL DATA 5-549 & # ) !" $ !" ) -T $ " " C F & 8 E ! ! ! " " -B1 & 9 * * ! ! ! ! * * ! ° ° ! ° ° Motorola reserves the right to make changes without further notice to any products herein. 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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. ◊ FAST AND LS TTL DATA 5-550