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书名:数字逻辑设计
定价:59.0
ISBN:9787121441240
作者:无
版次:*1版
出版时间:2022-08
内容提要:
本书是首批*家级*流本科课程“数字逻辑设计”的主讲教材,主要介绍数字逻辑设计的相关知识与思维方法。全书共11 章,内容包括初识数字逻辑、逻辑代数基础、卡诺图化简、组合逻辑电路、触发器、时序逻辑电路分析、时序逻辑电路设计、可编程逻辑器件。 本书可作为高等院校工科类专业数字逻辑设计课程的教材,也可供对数字逻辑设计感兴趣的人员参考。
作者简介:
张彦航,副教授,哈尔滨工业大学计算学部软件学院智能软件工程研究中心副主任,2012年硕士毕业于哈尔滨工业大学计算机科学与技术专业,长期从事智能软件工程的教学与科研工作。
目录:
*1 章开篇——初识数字逻辑············1
1.1 本书知识脉络······················.1
1.2 初识数字逻辑······················.2
1.2.1 数字系统设计的三个层次····3
1.2.2 几个基本概念·················4
1.2.3 数字系统中的开关器件·······5
1.3 编码··································.5
1.3.1 BCD 码························5
1.3.2 余3 码·························6
1.3.3 格雷码·························6
1.3.4 奇偶校验码····················9
1.4 研讨探究··························.10
1.5 深入思考··························.11
1.6 小故事大情怀····················.11
习题1 ····································.11
*2 章万丈高楼平地起——逻辑
代数基础 ··························.12
2.1 几个基本概念····················.12
2.2 基本逻辑运算····················.13
2.2.1 与运算(逻辑乘) ·········.13
2.2.2 或运算(逻辑加) ·········.14
2.2.3 非运算(逻辑反) ·········.14
2.3 复合逻辑运算····················.15
2.3.1 与非运算···················.15
2.3.2 或非运算···················.15
2.3.3 与或非运算·················.16
2.3.4 异或运算···················.16
2.3.5 同或运算···················.17
2.4 逻辑函数的表示方法···········.18
2.4.1 由真值表写出标准逻辑
表达式······················.18
2.4.2 由逻辑表达式画出真值表·.19
2.4.3 由逻辑图得出逻辑表达式·.20
2.4.4 由逻辑表达式画出逻辑图·.20
2.5 逻辑代数定理及规则···········.20
2.5.1 公理························.20
2.5.2 基本定理···················.21
2.5.3 特殊定理···················.21
2.6 代数化简法·······················.23
2.6.1 何为*简···················.23
2.6.2 代数化简法实例············.24
2.7 *小项与*大项·················.25
2.7.1 *小项与*大项的定义····.25
2.7.2 *小项与*大项的性质····.25
2.7.3 *小项与*大项表达式····.26
2.8 非完全给定函数·················.28
2.8.1 无关项······················.28
2.8.2 非完全给定函数的定义····.29
2.9 小材大用——应用异或门
设计旅客身高检测器···········.29
2.10 研究探讨························.30
2.11 深入思考························.30
2.12 小故事大情怀··················.31
习题2 ····································.31
第3 章方圆之间的神奇——卡诺图
化简 ································.33
3.1 卡诺图的含义····················.33
3.2 填写卡诺图·······················.34
3.2.1 由真值表填写卡诺图······.34
3.2.2 由标准与或式、标准或与式
填写卡诺图·················.34
3.2.3 由一般表达式填写卡诺图·.35
3.3 基于卡诺图的逻辑运算·······.35
3.4 卡诺图化简法····················.36
3.4.1 利用卡诺图读取*简
与或式······················.37
3.4.2 利用卡诺图读取*简
或与式······················.38
3.4.3 利用卡诺图读取*简
与或非式 ···················.38
3.5 带无关项的卡诺图化简········.39
3.6 卡诺图化简的进一步讨论·····.41
3.6.1 展开定理···················.41
3.6.2 卡诺图拆分后相邻单元格
的判断······················.41
3.7 研究探讨··························.43
3.8 深入思考··························.43
3.9 小故事大情怀····················.44
习题3 ····································.44
第4 章玩转逻辑门——组合逻辑
电路(一) ·······················.45
4.1 门电路的级数····················.45
4.1.1 二级门电路·················.45
4.1.2 二级门电路的8 种基本
形式 ························.47
4.2 利用单一逻辑门设计二级
组合逻辑电路···················.48
4.2.1 利用与非门设计二级组合
逻辑电路 ···················.48
4.2.2 利用或非门设计二级组合
逻辑电路 ···················.49
4.2.3 利用与或非门设计二级
组合逻辑电路 ··············.50
4.3 利用单一逻辑门设计多级
组合逻辑电路···················.51
4.3.1 利用与非门设计多级组合
逻辑电路 ···················.51
4.3.2 利用或非门设计多级组合
逻辑电路 ···················.51
4.4 多输出电路的设计··············.52
4.5 组合逻辑电路的分析···········.53
4.6 应用案例——多功能函数
发生器·····························.55
4.7 利用逻辑门设计组合逻辑
电路 ·······························.55
4.8 使用有限扇入门设计组合
逻辑电路 ·························.58
4.9 典型组合逻辑部件··············.59
4.9.1 半加器······················.59
4.9.2 全加器······················.60
4.9.3 并行加法器·················.61
4.9.4 集电极开路门··············.63
4.9.5 三态缓冲器·················.64
4.10 研讨探究························.66
4.11 深入思考························.67
4.12 小故事大情怀··················.67
习题4 ····································.67
第5 章险象环生——组合逻辑
电路(二) ·······················.69
5.1 组合逻辑电路中的险象········.69
5.1.1 门延迟······················.69
5.1.2 组合逻辑电路的冒险······.69
5.1.3 冒险的类型·················.70
5.2 险象的判别·······················.73
5.2.1 代数判别法·················.73
5.2.2 卡诺图判别法··············.74
5.3 险象的消除·······················.74
5.4 组合逻辑电路的测试···········.76
5.5 研讨探究··························.76
5.6 深入思考··························.77
5.7 小故事大情怀····················.77
习题5 ····································.77
第6 章数字逻辑的基石——组合
逻辑电路(三) ·················.79
6.1 集成电路的分类·················.79
6.2 数据选择器·······················.80
6.3 译码器·····························.83
6.3.1 二进制译码器··············.83
6.3.2 代码转换译码器············.85
6.3.3 显示译码器·················.87
6.4 编码器·····························.88
6.4.1 普通编码器·················.88
6.4.2 优先权编码器··············.90
6.5 数值比较器·······················.91
6.5.1 一位数值比较器············.91
6.5.2 多位数值比较器············.92
6.5.3 数值比较器的级联·········.93
6.6 奇偶校验器·······················.94
6.7 利用中规模芯片设计组合
逻辑电路 ·························.96
6.7.1 利用中规模芯片数据选择器
设计组合逻辑电路·········.96
6.7.2 利用中规模芯片译码器
设计组合逻辑电路·········100
6.8 研讨探究··························103
6.9 深入思考··························103
6.10 小故事大情怀··················103
习题6 ····································104
第7 章走在时间的边沿——
触发器 ·····························106
7.1 时序逻辑电路的特点···········106
7.1.1 两个重要概念··············107
7.1.2 双稳态触发器/锁存器的
特点 ························107
7.1.3 锁存器和触发器的区别····108
7.2 锁存器·····························108
7.2.1 基本RS 锁存器············108
7.2.2 门控D 锁存器·············.113
7.2.3 锁存器或触发器的空翻
现象 ·······················.114
7.3 触发器····························.115
7.3.1 RS 触发器·················.116
7.3.2 D 触发器··················.116
7.3.3 JK 触发器·················.117
7.3.4 T 触发器···················.119
7.3.5 T ‘触发器···················120
7.4 带附加输入端的触发器········120
7.4.1 带异步清零端和异步
置 1 端······················120
7.4.2 带时钟使能端··············121
7.5 触发器类型转换·················122
7.5.1 代数法······················122
7.5.2 卡诺图法···················123
7.6 研讨探究·························.124
7.7 深入思考·························.124
7.8 小故事大情怀···················.124
习题7 ···································.125
第8 章与时间打交道——时序逻辑
电路分析 ·························.127
8.1 时序逻辑电路分类·············.127
8.2 寄存器····························.128
8.2.1 基本寄存器················.128
8.2.2 单向移位寄存器···········.129
8.2.3 双向移位寄存器···········.133
8.3 计数器····························.136
8.3.1 计数器的概念及特点·····.136
8.3.2 计数器的种类·············.136
8.3.3 时序逻辑电路的分析
方法 ·······················.136
8.3.4 同步计数器举例···········.137
8.3.5 异步计数器举例···········.139
8.4 节拍发生器······················.141
8.4.1 计数型节拍发生器举例···.141
8.4.2 移位型节拍发生器举例···.143
8.5 时序逻辑电路的分析··········.145
8.5.1 同步时序逻辑电路的
分析 ·······················.146
8.5.2 异步时序逻辑电路的
分析 ·······················.149
8.6 应用案例——简易I/O 电路··.151
8.7 研讨探究·························.153
8.8 深入思考·························.153
8.9 小故事大情怀···················.153
习题8 ···································.154
第9 章触发器用起来——时序逻辑
电路设计(一) ················.158
9.1 时序逻辑电路设计方法
概述 ······························.158
9.1.1 开篇示例··················.158
9.1.2 建立原始状态图和原始
状态表·····················.161
9.1.3 状态表化简················.167
9.1.4 状态分配··················.173
9.2 利用触发器设计同步时序
逻辑电路典型案例·············175
9.2.1 模8 可逆计数器············175
9.2.2 自动售卖机·················177
9.2.3 时序锁······················184
9.2.4 二进制串行加法器·········187
9.2.5 串行输入的8421BCD 码
检测器······················189
9.2.6 奇偶校验器·················193
9.3 复杂时序逻辑电路的设计·····194
9.3.1 码制转换器·················194
9.3.2 多序列检测器··············198
9.4 利用触发器设计异步时序
逻辑电路 ·························199
9.4.1 利用触发器设计异步时序
逻辑电路的方法···········199
9.4.2 利用触发器设计异步
计数器······················203
9.5 应用案例——时序逻辑电路
故障诊断 ·························208
9.6 研讨探究··························210
9.7 深入思考··························210
9.8 小故事大情怀···················.211
习题9 ···································.211
*10 章中规模芯片显身手——
时序逻辑电路设计(二) ···215
10.1 计数器芯片·····················215
10.1.1 采用清零法设计计
数器 ·····················217
10.1.2 采用置数法设计计
数器 ·····················219
10.1.3 计数器级联··············219
10.1.4 计数器的应用···········223
10.1.5 可变模值计数器设计····225
10.2 寄存器芯片·····················226
10.2.1 寄存器芯片74LS194
概述·····················226
10.2.2 寄存器芯片的典型
应用 ····················.227
10.2.3 应用案例——同步
二进制串行加法器·····.230
10.3 应用案例——数字密码锁···.231
10.4 研讨探究·······················.233
10.5 深入思考·······················.233
10.6 小故事大情怀·················.233
习题10··································.234
*11 章我的芯片我做主——可编程
逻辑器件 ·······················.237
11.1 可编程逻辑器件概述········.237
11.2 ROM 的基本原理及应用····.238
11.2.1 ROM 系列概述·········.238
11.2.2 ROM 的基本原理······.239
11.2.3 ROM 的典型应用······.242
11.3 PROM 的基本原理及应用··.247
11.3.1 PROM 的基本原理·····.247
11.3.2 PROM 的典型应用·····.247
11.3.3 PROM 的扩展··········.251
11.4 其他低密度PLD··············.255
11.4.1 PLA 的基本原理及
应用 ····················.255
11.4.2 PAL 的基本原理及
应用 ····················.265
11.4.3 GAL 的基本原理及
应用 ····················.266
11.5 高密度PLD····················.271
11.5.1 CPLD 的基本原理······.271
11.5.2 FPGA 的基本原理······.272
11.6 新一代智能芯片··············.274
11.7 应用案例——简易十字路口
交通控制器 ····················.277
11.8 研讨探究·······················.280
11.9 深入思考·······················.280
11.10 小故事大情怀················.280
习题11··································.281
附录A 参考答案··························.283
定价:59.0
ISBN:9787121441240
作者:无
版次:*1版
出版时间:2022-08
内容提要:
本书是首批*家级*流本科课程“数字逻辑设计”的主讲教材,主要介绍数字逻辑设计的相关知识与思维方法。全书共11 章,内容包括初识数字逻辑、逻辑代数基础、卡诺图化简、组合逻辑电路、触发器、时序逻辑电路分析、时序逻辑电路设计、可编程逻辑器件。 本书可作为高等院校工科类专业数字逻辑设计课程的教材,也可供对数字逻辑设计感兴趣的人员参考。
作者简介:
张彦航,副教授,哈尔滨工业大学计算学部软件学院智能软件工程研究中心副主任,2012年硕士毕业于哈尔滨工业大学计算机科学与技术专业,长期从事智能软件工程的教学与科研工作。
目录:
*1 章开篇——初识数字逻辑············1
1.1 本书知识脉络······················.1
1.2 初识数字逻辑······················.2
1.2.1 数字系统设计的三个层次····3
1.2.2 几个基本概念·················4
1.2.3 数字系统中的开关器件·······5
1.3 编码··································.5
1.3.1 BCD 码························5
1.3.2 余3 码·························6
1.3.3 格雷码·························6
1.3.4 奇偶校验码····················9
1.4 研讨探究··························.10
1.5 深入思考··························.11
1.6 小故事大情怀····················.11
习题1 ····································.11
*2 章万丈高楼平地起——逻辑
代数基础 ··························.12
2.1 几个基本概念····················.12
2.2 基本逻辑运算····················.13
2.2.1 与运算(逻辑乘) ·········.13
2.2.2 或运算(逻辑加) ·········.14
2.2.3 非运算(逻辑反) ·········.14
2.3 复合逻辑运算····················.15
2.3.1 与非运算···················.15
2.3.2 或非运算···················.15
2.3.3 与或非运算·················.16
2.3.4 异或运算···················.16
2.3.5 同或运算···················.17
2.4 逻辑函数的表示方法···········.18
2.4.1 由真值表写出标准逻辑
表达式······················.18
2.4.2 由逻辑表达式画出真值表·.19
2.4.3 由逻辑图得出逻辑表达式·.20
2.4.4 由逻辑表达式画出逻辑图·.20
2.5 逻辑代数定理及规则···········.20
2.5.1 公理························.20
2.5.2 基本定理···················.21
2.5.3 特殊定理···················.21
2.6 代数化简法·······················.23
2.6.1 何为*简···················.23
2.6.2 代数化简法实例············.24
2.7 *小项与*大项·················.25
2.7.1 *小项与*大项的定义····.25
2.7.2 *小项与*大项的性质····.25
2.7.3 *小项与*大项表达式····.26
2.8 非完全给定函数·················.28
2.8.1 无关项······················.28
2.8.2 非完全给定函数的定义····.29
2.9 小材大用——应用异或门
设计旅客身高检测器···········.29
2.10 研究探讨························.30
2.11 深入思考························.30
2.12 小故事大情怀··················.31
习题2 ····································.31
第3 章方圆之间的神奇——卡诺图
化简 ································.33
3.1 卡诺图的含义····················.33
3.2 填写卡诺图·······················.34
3.2.1 由真值表填写卡诺图······.34
3.2.2 由标准与或式、标准或与式
填写卡诺图·················.34
3.2.3 由一般表达式填写卡诺图·.35
3.3 基于卡诺图的逻辑运算·······.35
3.4 卡诺图化简法····················.36
3.4.1 利用卡诺图读取*简
与或式······················.37
3.4.2 利用卡诺图读取*简
或与式······················.38
3.4.3 利用卡诺图读取*简
与或非式 ···················.38
3.5 带无关项的卡诺图化简········.39
3.6 卡诺图化简的进一步讨论·····.41
3.6.1 展开定理···················.41
3.6.2 卡诺图拆分后相邻单元格
的判断······················.41
3.7 研究探讨··························.43
3.8 深入思考··························.43
3.9 小故事大情怀····················.44
习题3 ····································.44
第4 章玩转逻辑门——组合逻辑
电路(一) ·······················.45
4.1 门电路的级数····················.45
4.1.1 二级门电路·················.45
4.1.2 二级门电路的8 种基本
形式 ························.47
4.2 利用单一逻辑门设计二级
组合逻辑电路···················.48
4.2.1 利用与非门设计二级组合
逻辑电路 ···················.48
4.2.2 利用或非门设计二级组合
逻辑电路 ···················.49
4.2.3 利用与或非门设计二级
组合逻辑电路 ··············.50
4.3 利用单一逻辑门设计多级
组合逻辑电路···················.51
4.3.1 利用与非门设计多级组合
逻辑电路 ···················.51
4.3.2 利用或非门设计多级组合
逻辑电路 ···················.51
4.4 多输出电路的设计··············.52
4.5 组合逻辑电路的分析···········.53
4.6 应用案例——多功能函数
发生器·····························.55
4.7 利用逻辑门设计组合逻辑
电路 ·······························.55
4.8 使用有限扇入门设计组合
逻辑电路 ·························.58
4.9 典型组合逻辑部件··············.59
4.9.1 半加器······················.59
4.9.2 全加器······················.60
4.9.3 并行加法器·················.61
4.9.4 集电极开路门··············.63
4.9.5 三态缓冲器·················.64
4.10 研讨探究························.66
4.11 深入思考························.67
4.12 小故事大情怀··················.67
习题4 ····································.67
第5 章险象环生——组合逻辑
电路(二) ·······················.69
5.1 组合逻辑电路中的险象········.69
5.1.1 门延迟······················.69
5.1.2 组合逻辑电路的冒险······.69
5.1.3 冒险的类型·················.70
5.2 险象的判别·······················.73
5.2.1 代数判别法·················.73
5.2.2 卡诺图判别法··············.74
5.3 险象的消除·······················.74
5.4 组合逻辑电路的测试···········.76
5.5 研讨探究··························.76
5.6 深入思考··························.77
5.7 小故事大情怀····················.77
习题5 ····································.77
第6 章数字逻辑的基石——组合
逻辑电路(三) ·················.79
6.1 集成电路的分类·················.79
6.2 数据选择器·······················.80
6.3 译码器·····························.83
6.3.1 二进制译码器··············.83
6.3.2 代码转换译码器············.85
6.3.3 显示译码器·················.87
6.4 编码器·····························.88
6.4.1 普通编码器·················.88
6.4.2 优先权编码器··············.90
6.5 数值比较器·······················.91
6.5.1 一位数值比较器············.91
6.5.2 多位数值比较器············.92
6.5.3 数值比较器的级联·········.93
6.6 奇偶校验器·······················.94
6.7 利用中规模芯片设计组合
逻辑电路 ·························.96
6.7.1 利用中规模芯片数据选择器
设计组合逻辑电路·········.96
6.7.2 利用中规模芯片译码器
设计组合逻辑电路·········100
6.8 研讨探究··························103
6.9 深入思考··························103
6.10 小故事大情怀··················103
习题6 ····································104
第7 章走在时间的边沿——
触发器 ·····························106
7.1 时序逻辑电路的特点···········106
7.1.1 两个重要概念··············107
7.1.2 双稳态触发器/锁存器的
特点 ························107
7.1.3 锁存器和触发器的区别····108
7.2 锁存器·····························108
7.2.1 基本RS 锁存器············108
7.2.2 门控D 锁存器·············.113
7.2.3 锁存器或触发器的空翻
现象 ·······················.114
7.3 触发器····························.115
7.3.1 RS 触发器·················.116
7.3.2 D 触发器··················.116
7.3.3 JK 触发器·················.117
7.3.4 T 触发器···················.119
7.3.5 T ‘触发器···················120
7.4 带附加输入端的触发器········120
7.4.1 带异步清零端和异步
置 1 端······················120
7.4.2 带时钟使能端··············121
7.5 触发器类型转换·················122
7.5.1 代数法······················122
7.5.2 卡诺图法···················123
7.6 研讨探究·························.124
7.7 深入思考·························.124
7.8 小故事大情怀···················.124
习题7 ···································.125
第8 章与时间打交道——时序逻辑
电路分析 ·························.127
8.1 时序逻辑电路分类·············.127
8.2 寄存器····························.128
8.2.1 基本寄存器················.128
8.2.2 单向移位寄存器···········.129
8.2.3 双向移位寄存器···········.133
8.3 计数器····························.136
8.3.1 计数器的概念及特点·····.136
8.3.2 计数器的种类·············.136
8.3.3 时序逻辑电路的分析
方法 ·······················.136
8.3.4 同步计数器举例···········.137
8.3.5 异步计数器举例···········.139
8.4 节拍发生器······················.141
8.4.1 计数型节拍发生器举例···.141
8.4.2 移位型节拍发生器举例···.143
8.5 时序逻辑电路的分析··········.145
8.5.1 同步时序逻辑电路的
分析 ·······················.146
8.5.2 异步时序逻辑电路的
分析 ·······················.149
8.6 应用案例——简易I/O 电路··.151
8.7 研讨探究·························.153
8.8 深入思考·························.153
8.9 小故事大情怀···················.153
习题8 ···································.154
第9 章触发器用起来——时序逻辑
电路设计(一) ················.158
9.1 时序逻辑电路设计方法
概述 ······························.158
9.1.1 开篇示例··················.158
9.1.2 建立原始状态图和原始
状态表·····················.161
9.1.3 状态表化简················.167
9.1.4 状态分配··················.173
9.2 利用触发器设计同步时序
逻辑电路典型案例·············175
9.2.1 模8 可逆计数器············175
9.2.2 自动售卖机·················177
9.2.3 时序锁······················184
9.2.4 二进制串行加法器·········187
9.2.5 串行输入的8421BCD 码
检测器······················189
9.2.6 奇偶校验器·················193
9.3 复杂时序逻辑电路的设计·····194
9.3.1 码制转换器·················194
9.3.2 多序列检测器··············198
9.4 利用触发器设计异步时序
逻辑电路 ·························199
9.4.1 利用触发器设计异步时序
逻辑电路的方法···········199
9.4.2 利用触发器设计异步
计数器······················203
9.5 应用案例——时序逻辑电路
故障诊断 ·························208
9.6 研讨探究··························210
9.7 深入思考··························210
9.8 小故事大情怀···················.211
习题9 ···································.211
*10 章中规模芯片显身手——
时序逻辑电路设计(二) ···215
10.1 计数器芯片·····················215
10.1.1 采用清零法设计计
数器 ·····················217
10.1.2 采用置数法设计计
数器 ·····················219
10.1.3 计数器级联··············219
10.1.4 计数器的应用···········223
10.1.5 可变模值计数器设计····225
10.2 寄存器芯片·····················226
10.2.1 寄存器芯片74LS194
概述·····················226
10.2.2 寄存器芯片的典型
应用 ····················.227
10.2.3 应用案例——同步
二进制串行加法器·····.230
10.3 应用案例——数字密码锁···.231
10.4 研讨探究·······················.233
10.5 深入思考·······················.233
10.6 小故事大情怀·················.233
习题10··································.234
*11 章我的芯片我做主——可编程
逻辑器件 ·······················.237
11.1 可编程逻辑器件概述········.237
11.2 ROM 的基本原理及应用····.238
11.2.1 ROM 系列概述·········.238
11.2.2 ROM 的基本原理······.239
11.2.3 ROM 的典型应用······.242
11.3 PROM 的基本原理及应用··.247
11.3.1 PROM 的基本原理·····.247
11.3.2 PROM 的典型应用·····.247
11.3.3 PROM 的扩展··········.251
11.4 其他低密度PLD··············.255
11.4.1 PLA 的基本原理及
应用 ····················.255
11.4.2 PAL 的基本原理及
应用 ····················.265
11.4.3 GAL 的基本原理及
应用 ····················.266
11.5 高密度PLD····················.271
11.5.1 CPLD 的基本原理······.271
11.5.2 FPGA 的基本原理······.272
11.6 新一代智能芯片··············.274
11.7 应用案例——简易十字路口
交通控制器 ····················.277
11.8 研讨探究·······················.280
11.9 深入思考·······················.280
11.10 小故事大情怀················.280
习题11··································.281
附录A 参考答案··························.283
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