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EET 252 Digital Systems II Professor Nick Reeder Reminders Please turn off cell phones. No food or soft drinks in the classroom. Stow water bottles at floor level. EET 252 Unit 1 Review; Arithmetic Logic Units Review Floyd, Chapter 2 and Chapters 6 to 9. Study Unit 1 e-Lesson. Do Lab #1. Homework #1 and Lab #1 due next week. Quiz next week. Overview of This Week’s Lecture Unused Inputs Pull-up Resistors Review of Logical Operations Review of Arithmetic Operations Arithmetic Logic Units Unused Gate Inputs (Floyd, p. 143) Tying Other Inputs HIGH or LOW The same rules apply to other input pins (such as enable inputs). To force them HIGH, tie them to VCC through a 1-kΩ resistor for TTL. To force them LOW, tie them to ground. But what about the Trainer’s Data Switches? When you connect a TTL input pin to one of the trainer’s data switches and set the switch to HIGH, do you need a 1−kΩ resistor between the switch and the input pin? From the Trainer’s Schematic Diagram Don’t Tie Outputs HIGH or LOW Remember that, in general, unused output pins should be left unconnected. Do not tie them HIGH or LOW. Overview of This Week’s Lecture Unused Inputs Pull-up Resistors Review of Logical Operations Review of Arithmetic Operations Arithmetic Logic Units Pull-Up Resistor A pull-up resistor is a resistor with one end connected to a HIGH voltage level and the other end connected to a point in a digital circuit. The resistor’s purpose is to pull up the voltage at that point to a HIGH level when it would otherwise be in a float condition (not HIGH or LOW). Pull-Up Resistor (Continued) Three common uses of pull-up resistors: 1. On a switch connected to an input pin. 2. When interfacing two logic families that use different voltage levels. 3. On open-collector outputs (TTL) or open-drain outputs (CMOS). First Use for Pull-Up Resistor: Switch on an Input Pin Good explanation at http://www.seattlerobotics.org/encoder /mar97/basics.html See also example on next slide from your textbook. Figure 6.42 A simplified keyboard encoder. (Floyd, p. 316) Digital Fundamentals, Tenth Edition Thomas L. Floyd Copyright ©2009 by Pearson Higher Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. Second Use for Pull-Up Resistor: Interfacing Logic Families Suppose we want to connect the output of a TTL gate to the input of a CMOS gate. A TTL HIGH output may be as low as 2.4 V. But CMOS expects at least 3.3 V for a HIGH. Problem: The CMOS gate may interpret the TTL gate’s HIGH output as a LOW. Solution? See next slide. Figure 9–27 Using a pull-up resistor to interface TTL to CMOS. Digital Electronics: A Practical Approach, Eighth Edition William Kleitz Copyright ©2008 by Pearson Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. Third Use for Pull-Up Resistor: Open Collector Outputs As we’ll see next week, some TTL gates are intentionally designed with a missing transistor on the output. To work properly, such an output needs an external pull-up resistor. One of the output pins on the chip in tonight’s lab is an open-collector output, and therefore needs a pull-up resistor. Figure 14.31 TTL inverter with open-collector output. Digital Fundamentals, Tenth Edition Thomas L. Floyd Copyright ©2009 by Pearson Higher Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. Overview of This Week’s Lecture Unused Inputs Pull-up Resistors Review of Logical Operations Review of Arithmetic Operations Arithmetic Logic Units How Many Logical Operations? You already know how to perform some logical operations on two input bits, A and B. Examples: X = AB X = A+B Question: How many possible logical operations are there on two input bits? How Many Logical Ops? (Continued) A B 0 0 0 1 1 0 1 1 Let’s list them all: Overview of This Week’s Lecture Unused Inputs Pull-up Resistors Review of Logical Operations Review of Arithmetic Operations Arithmetic Logic Units Overview of This Week’s Lecture Unused Inputs Pull-up Resistors Review of Logical Operations Review of Arithmetic Operations Arithmetic Logic Units Arithmetic Logic Unit (ALU) Central to any computer system is its ALU, which performs mathematical and logical operations on data. In modern systems, the ALU is contained on the computer’s microprocessor chip. (See next slide, or Figure 13-3 on p. 724 of Floyd.) In older systems, the ALU was a separate chip, such as the 74181. Figure 13.3 Digital Fundamentals, Tenth Edition Thomas L. Floyd Copyright ©2009 by Pearson Higher Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. 74181 ALU chip Can perform 16 logical operations (bitby-bit) and 16 arithmetic operations on two four-bit input numbers. Data Sheet shows two truth tables: Table 1 if you’re considering data inputs & outputs to be active-low, and Table 2 if you’re considering data inputs & outputs to be active-high. Data Sheet: 74LS181 Positive Logic versus Negative Logic Any gate or logic circuit can be looked at from either an active-HIGH perspective (“positive logic”) or an active-LOW perspective (“negative logic”). Example: The gates on a 7408 chip can be considered either positive-AND gates or negative-OR gates. Data Sheet: 7408 74181 ALU (Continued) Caution: In the “Arithmetic Operations” columns of the 74181 truth tables, the + symbol always means logical OR, not addition. The word “PLUS” is used for addition. 74181 ALU (Continued) Fourteen Input Pins: M is the mode pin (arithmetic or logic). S0 to S3 select the operation performed. Cn is the carry-in bit, used only during arithmetic ops (ignored during logic ops). A0 to A3 form one of the 4-bit inputs. B0 to B3 form the other 4-bit input. 74181 ALU (Continued) Eight Output Pins: F0 to F3 form the 4-bit output. Cn=4 is carry-out bit, meaningful only for arithmetic ops. (Ignore it for logic ops.) A=B is comparison bit, meaningful only when performing “A MINUS B” operation. (Ignore it for all other ops.) P and G are carry-look-ahead bits for high-speed arithmetic, when 74181 is used in conjunction with 74182 chip. (We’ll ignore these.)