INTEGRATED CIRCUITS DATA SHEET For a complete data sheet, please also download: The IC6 74HC/HCT/HCU/HCMOS ogic Family Specifications The IC6 74HC/HCT/HCU/HCMOS ogic Package Information The IC6 74HC/HCT/HCU/HCMOS ogic Package Outlines Presettable synchronous BCD decade File under Integrated Circuits, IC6 December 199
FEATURES Synchronous reversible counting Asynchronous parallel load Asynchronous reset Expandable without external logic Output capability: standard I CC category: MSI GENERA DESCRIPTION The are high-speed Si-gate CMOS devices and are pin compatible with low power Schottky TT (STT). They are specified in compliance with JEDEC standard no. 7A. The are synchronous BCD up/down counters. Separate up/down clocks, CP U and CP D respectively, simplify operation. The outputs change state synchronously with the OW-to-HIGH transition of either clock input. If the CP U clock is pulsed while CP D is held HIGH, the device will count up. If the CP D clock is pulsed while CP U is held HIGH, the device will count down. Only one clock input can be held HIGH at any time, or erroneous operation will result. The device can be cleared at any time by the asynchronous master reset input (MR); it may also be loaded in parallel by activating the asynchronous parallel load input (P). The 192 contains four master-slave JK flip-flops with the necessary steering logic to provide the asynchronous reset, load, and synchronous count up and count down functions. Each flip-flop contains JK feedback from slave to master, such that a OW-to-HIGH transition on the CP D input will decrease the count by one, while a similar transition on the CP U input will advance the count by one. One clock should be held HIGH while counting with the other, otherwise the circuit will either count by two s or not at all, depending on the state of the first flip-flop, which cannot toggle as long as either clock input is OW. Applications requiring reversible operation must make the reversing decision while the activating clock is HIGH to avoid erroneous counts. The terminal count up (TC U ) and terminal count down (TC D ) outputs are normally HIGH. When the circuit has reached the maximum count state of 9, the next HIGH-to-OW transition of CP U will cause TC U to go OW. TC U will stay OW until CP U goes HIGH again, duplicating the count up clock. ikewise, the TC D output will go OW when the circuit is in the zero state and the CP D goes OW. The terminal count outputs can be used as the clock input signals to the next higher order circuit in a multistage counter, since they duplicate the clock waveforms. Multistage counters will not be fully synchronous, since there is a slight delay time difference added for each stage that is added. The counter may be preset by the asynchronous parallel load capability of the circuit. Information present on the parallel data inputs (D to D 3 ) is loaded into the counter and appears on the outputs (Q to Q 3 ) regardless of the conditions of the clock inputs when the parallel load (P) input is OW. A HIGH level on the master reset (MR) input will disable the parallel load gates, override both clock inputs and set all outputs (Q to Q 3 ) OW. If one of the clock inputs is OW during and after a reset or load operation, the next OW-to-HIGH transition of that clock will be interpreted as a legitimate signal and will be counted. December 199 2
QUICK REFERENCE DATA GND = V; T amb =25 C; t r =t f = 6 ns TYPICA SYMBO PARAMETER CONDITIONS HC HCT UNIT t PH / t PH CP D, CP U to Q n 2 2 ns C = 15 pf; V CC =5V f max maximum clock frequency 4 45 MHz C I input capacitance 3.5 3.5 pf C PD power dissipation capacitance per package notes 1 and 2 28 pf Notes 1. C PD is used to determine the dynamic power dissipation (P D in µw): P D =C PD V 2 CC f i + (C V 2 CC f o ) where: f i = input frequency in MHz f o = output frequency in MHz (C V 2 CC f o ) = sum of outputs C = output load capacitance in pf V CC = supply voltage in V 2. For HC the condition is V I = GND to V CC For HCT the condition is V I = GND to V CC 1.5 V ORDERING INFORMATION See 74HC/HCT/HCU/HCMOS ogic Package Information. December 199 3
PIN DESCRIPTION PIN NO. SYMBO NAME AND FUNCTION 3, 2, 6, 7 Q to Q 3 flip-flop outputs 4 CP D count down clock input (1) 5 CP U count up clock input (1) 8 GND ground ( V) 11 P asynchronous parallel load input (active OW) 12 TC U terminal count up (carry) output (active OW) 13 TC D terminal count down (borrow) output (active OW) 14 MR asynchronous master reset input (active HIGH) 15, 1, 1, 9 D to D 3 data inputs 16 V CC positive supply voltage Note 1. OW-to-HIGH, edge triggered Fig.1 Pin configuration. Fig.2 ogic symbol. Fig.3 IEC logic symbol. December 199 4
FUNCTION TABE OPERATING MODE reset (clear) Notes 1. H = HIGH voltage level = OW voltage level = don t care = OW-to-HIGH clock transition 2. TC U =CP U at terminal count up (HH) 3. TC D =CP D at terminal count down () INPUTS OUTPUTS MR P CP U CP D D D 1 D 2 D 3 Q Q 1 Q 2 Q 3 TC U TC D H H H H parallel load H H H H H Q n =D n H H H H Q n =D n H H count up H H count up H (2) H count down H H count down H H (3) H H H Fig.4 Functional diagram. December 199 5
(1) Clear overrides load, data and count inputs. (2) When counting up the count down clock input (CP D ) must be HIGH, when counting down the count up clock input (CP U ) must be HIGH. Sequence Clear (reset outputs to zero); load (preset) to BCD seven; count up to eight, nine, terminal count up, zero, one and two; count down to one, zero, terminal count down, nine, eight, and seven. Fig.5 Typical clear, load and count sequence. Fig.6 ogic diagram. December 199 6
DC CHARACTERISTICS FOR 74HC For the DC characteristics see 74HC/HCT/HCU/HCMOS ogic Family Specifications. Output capability: standard I CC category: MSI AC CHARACTERISTICS FOR 74HC GND = V; t r =t f = 6 ns; C =5pF T amb ( C) TEST CONDITIONS SYMBO PARAMETER 74HC +25 4 to +85 4 to +125 min. typ. max. min. max. min. max. UNIT V CC (V) WAVEFORMS t PH / t PH 66 CP U, CP D to Q n 19 215 43 37 27 54 46 325 65 55 Fig.7 t PH / t PH 33 CP U to TC U 12 1 125 25 21 155 31 26 19 38 32 Fig.8 t PH / t PH 39 CP D to TC D 14 11 125 25 21 155 31 26 19 38 32 Fig.8 t PH / t PH 69 P to Q n 25 2 215 43 37 27 54 46 325 65 55 Fig.9 t PH 63 MR to Q n 23 18 2 4 34 25 5 43 3 6 51 Fig.1 t PH 91 D n to Q n 33 26 275 55 47 345 69 59 415 83 71 Fig.9 t PH 8 D n to Q n 29 23 48 41 3 6 51 36 72 61 Fig.9 t PH / t PH P to TC U, P to TC D 12 37 3 315 63 54 395 79 67 475 95 81 Fig.12 t PH / t PH MR to TC U, MR to TC D 96 35 28 285 57 48 355 71 6 43 86 73 Fig.12 t PH / t PH D n to TC U, D n to TC D 83 3 29 58 49 365 73 62 435 87 74 Fig.12 t TH / t TH output transition time 19 7 6 75 15 13 95 19 16 11 22 19 Fig.1 December 199 7
T amb ( C) TEST CONDITIONS SYMBO PARAMETER 74HC +25 4 to +85 4 to +125 min. typ. max. min. max. min. max. UNIT V CC (V) WAVEFORMS up clock pulse width HIGH or OW 12 2 39 14 11 15 3 26 18 36 31 Fig.7 down clock pulse width HIGH or OW 14 28 5 18 14 175 35 3 21 42 36 Fig.7 master reset pulse width HIGH 8 16 14 22 8 6 1 2 17 12 2 Fig.1 parallel load pulse width OW 8 16 14 22 8 6 1 2 17 12 2 Fig.9 t rem removal time 5 P to CP U, CP D 1 9 3 1 1 65 13 11 75 15 13 Fig.9 t rem removal time 5 MR to CP U, CP D 1 9 65 13 11 75 15 13 Fig.1 t su set-up time D n to P 8 16 14 22 8 6 1 2 17 12 2 Fig.11 note: CP U =CP D = HIGH t h hold time D n to P 14 5 4 Fig.11 t h hold time CP U to CP D, CP D to CP U 8 16 14 19 7 6 1 2 17 12 2 Fig.13 f max maximum up, down clock pulse frequency 4. 2 12 36 43 3.2 16 19 2.6 13 15 MHz 2. Fig.7 December 199 8
DC CHARACTERISTICS FOR 74HCT For the DC characteristics see 74HC/HCT/HCU/HCMOS ogic Family Specifications. Output capability: standard I CC category: MSI Note to HCT types The value of additional quiescent supply current ( I CC ) for a unit load of 1 is given in the family specifications. To determine I CC per input, multiply this value by the unit load coefficient shown in the table below. INPUT D n CP U, CP D P MR UNIT OAD COEFFICIENT.35 1.4.65 1.5 December 199 9
AC CHARACTERISTICS FOR 74HCT GND = V; t r =t f = 6 ns; C =5pF T amb ( C) TEST CONDITIONS 23 43 54 65 ns Fig.7 16 3 38 45 ns Fig.8 17 3 38 45 ns Fig.8 28 46 58 69 ns Fig.9 4 5 6 ns Fig.1 36 62 78 93 ns Fig.9 36 64 8 96 ns Fig.12 36 64 8 96 ns Fig.12 33 58 73 87 ns Fig.12 74HCT SYMBO PARAMETER UNIT V WAVEFORMS +25 4 to +85 4 to +125 CC (V) min. typ. max. min. max. min. max. t PH / t PH CP U, CP D to Q n t PH / t PH CP U to TC U t PH / t PH CP D to TC D t PH / t PH P to Q n t PH MR to Q n t PH / t PH D n to Q n t PH / t PH P to TC U, P to TC D t PH / t PH MR to TC U, MR to TC D t PH / t PH D n to TC U,D n to TC D t TH / t TH output transition time 7 15 19 22 ns Fig.1 t rem t rem t su t h t h f max up, down clock pulse width HIGH or OW 25 14 31 38 ns Fig.7 master reset pulse width 16 6 2 ns Fig.1 HIGH parallel load pulse width 2 1 25 3 ns Fig.9 OW removal time 1 1 13 15 ns Fig.9 P to CP U, CP D removal time 1 2 13 15 ns Fig.1 MR to CP U, CP D set-up time D n to P 16 8 2 ns Fig.11 note: CP U =CP D = HIGH hold time D n to P 6 ns Fig.11 hold time 2 9 25 3 ns Fig.13 CP U to CP D, CP D to CP U maximum up, down clock 2 41 16 13 MHz Fig.7 pulse frequency December 199 1
AC WAVEFORMS (1) HC : V M = 5%; V I = GND to V CC. Fig.7 Waveforms showing the clock (CP U, CP D ) to output (Q n ) s, the clock pulse width and the maximum clock pulse frequency. (1) HC : V M = 5%; V I = GND to V CC. Fig.8 Waveforms showing the clock (CP U, CP D ) to terminal count output (TC U, TC D ) s. (1) HC : V M = 5%; V I = GND to V CC. Fig.9 Waveforms showing the parallel load input (P) and data (D n ) to Q n output s and P removal time to clock input (CP U, CP D ). December 199 11
(1) HC : V M = 5%; V I = GND to V CC. Fig.1 Waveforms showing the master reset input (MR) pulse width, MR to Q n s, MR to CP U, CP D removal time and output transition times. The shaded areas indicate when the input is permitted to change for predictable output performance. (1) HC : V M = 5%; V I = GND to V CC. Fig.11 Waveforms showing the data input (D n ) to parallel load input (P) set-up and hold times. (1) HC : V M = 5%; V I = GND to V CC. Fig.12 Waveforms showing the data input (D n ), parallel load input (P) and the master reset input (MR) to the terminal count outputs (TC U, TC D ) s. December 199 12
(1) HC : V M = 5%; V I = GND to V CC. Fig.13 Waveforms showing the CP U to CP D or CP D to CP U hold times. APPICATION INFORMATION Fig.14 Cascaded with parallel load. PACKAGE OUTINES See 74HC/HCT/HCU/HCMOS ogic Package Outlines. December 199 13