Abstract: For safety reasons we keep our circuits referenced to our surroundings. In most cases this is earth ground. This application note explains how a proper understanding of local circuit ground as a reference point frees our thinking to consider other simple circuits. 注册参加Maxim在TechOnline举办的在线研讨会 (English only) Where is ground in space? Usually engineering is strictly constrained by the laws of physics. Ground is an exception, as engineers can get an ego boost because we can finally control and define something. It is so, just because we say so. It reminds us of the ego power employed by Humpty Dumpty in Lewis Carroll's Through the Looking-Glass. "'When I use a word,' Humpty Dumpty said in a rather scornful tone, 'it means just what I choose it to mean—neither more nor less.' 'The question is,' said Alice, 'whether you CAN make words mean so many different things.' 'The question is,' said Humpty Dumpty, 'which is to be master—that's all.'"¹ Defining ground in earth orbit emphasizes a possible confusion between "common" and engineering language use. This dichotomy applies equally to airplanes and automobiles driving on rubber tires. When we engineers say "ground," we really mean "reference point." This concept should be the beginning of our thought process. When we realize that we can make the term relative, we gain a certain freedom. For safety reasons we keep our circuits referenced to our surroundings. In most cases this is earth ground. Common electrical building codes mandate that the AC power line be bonded to the earth as it enters the premises. In power tools, insurance safety regulations allow a choice between grounding the metal case with a third wire safety ground or using double insulation. Similarly, we can maintain safety and define the local ground or reference point inside the equipment as we choose. By separating the reference point from safety ground we can look at an IC data sheet in a new perspective. A typical data sheet shows a device's Absolute Maximum Ratings. Figure 1 says that a pin named VCC needs to be within a certain voltage range compared to a pin named GND. Figure 1. Typical listings for absolute values taken from a data sheet. These values raise a question: could VCC and GND meet their relative voltage requirements and still be offset together by thousands of volts compared to something else? Yes, of course! Practical Examples Figure 2. A diagram shows making ground a relative +25V. Assume for the moment that an application needs a circuit to operate near a 30V supply, perhaps a sensor or a LCD contrast control. From Figure 2, the sensor can be buffered with U1 and AC-coupled to other circuits. DP1 can adjust bias gain or contrast. But how do you adjust DP1? Figure 3. A digital pot floating near +30V with self-debouncing switches. The MAX5174 up/down switches are momentary in the up-arrow direction. They are debounced because the switches mechanically chatter between one end at a time. The switches do not bounce between the two voltages. In simple terms, as the switch starts opening on the +25V side, the contact will bounce between open circuit and being connected to +25V. As the moving contact approaches the +30V side, the bounce similarly will be between open and +30V. The mechanics of the switch preclude a bounce between +25V and +30V. Figure 4. A digital pot floating between +25V and +30V with internally debounced switches. The DS1669, DS1809, and DS1869 digital potentiometers have internal 100kΩ pullup resistors. They have internal circuitry to debounce the switches and autoincrement the wiper position. The data sheet explains the repetitive pulse and continuous pulse ("push-and-hold") functions as well as an unique single-switch control configuration. Figure 5. A switch-driven up/down/increment interface. The up/down/increment interface of the MAX5450–MAX5455, MAX5471–MAX5475, and DS4301 devices debounces the switches. If the switch is held down it will autoincrement. See application note 1118, "Manually Operated Digital Potentiometer Doesn't Need a Microprocessor," for details. Maxim's complete list of digital pots is available on the website. ¹Carroll, Lewis, Through the Looking-Glass, Chapter 6 (1872). 相关型号   APP 4292: Sep 25, 2008 DS1669 Dallastat数字电位器 完整的数据资料 (PDF, 180kB) DS1804 非易失调节电位器 完整的数据资料 (PDF, 192kB) 免费样品 DS1809 Dallastat 完整的数据资料 (PDF, 128kB) 免费样品 DS1869 3V、Dallastat数字电位器 完整的数据资料 (PDF, 144kB) 免费样品 DS4301 非易失、32抽头数字电位器 完整的数据资料 (PDF, 160kB) 免费样品 MAX5128 128抽头、非易失、线性变化数字电位器，采用2mm x 2mm µDFN封装 完整的数据资料 (PDF, 764kB) MAX5160 低功耗数字电位器 完整的数据资料 (PDF, 264kB) 免费样品 MAX5450 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5451 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5452 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5453 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5454 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5455 双路、256抽头、增/减控制接口数字电位器 完整的数据资料 (PDF, 492kB) 免费样品 MAX5471 32抽头、非易失、线性变化数字电位器，SOT23封装 完整的数据资料 (PDF, 296kB) 免费样品 MAX5472 32抽头、非易失、线性变化数字电位器，SOT23封装 完整的数据资料 (PDF, 296kB) 免费样品 MAX5474 32抽头、非易失、线性变化数字电位器，SOT23封装 完整的数据资料 (PDF, 296kB) 免费样品 MAX5475 32抽头、非易失、线性变化数字电位器，SOT23封装 完整的数据资料 (PDF, 296kB) 免费样品 MAX6302 +5V、低功耗、微处理器监控电路，带有可调节的复位/看门狗定时器 完整的数据资料 (PDF, 208kB) 免费样品 MAX6817 ±15kV ESD保护、单/双/八通道、CMOS开关去抖器 完整的数据资料 (PDF, 712kB) 免费样品 自动更新 需要自动接收最新发布的应用笔记吗？请订阅EE-Mail™ (English only)。 我们期待您的反馈！ 喜欢？不喜欢？有待改善？或为我们提供建议？请与我们联系 — 我们将根据您的意见或建议改善我们的工作。 网页评价或提供建议   下载，PDF格式 (94kB)  AN4292, AN 4292, APP4292, Appnote4292, Appnote 4292