{"id":2193,"date":"2014-08-28T14:23:18","date_gmt":"2014-08-28T18:23:18","guid":{"rendered":"https:\/\/itp.nyu.edu\/physicalcomputing\/wp-content\/uploads\/LabToneInstrument_schem1.png"},"modified":"2018-08-14T15:48:33","modified_gmt":"2018-08-14T19:48:33","slug":"labtoneinstrument_schem-2","status":"inherit","type":"attachment","link":"https:\/\/itp.nyu.edu\/physcomp\/labs\/labs-arduino-digital-and-analog\/tone-output-using-an-arduino\/labtoneinstrument_schem-2\/","title":{"rendered":"LabToneInstrument_schem"},"author":2,"featured_media":0,"comment_status":"open","ping_status":"open","template":"","meta":[],"class_list":["post-2193","attachment","type-attachment","status-inherit","hentry"],"description":{"rendered":"<p class=\"attachment\"><a href='https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1.png'><img loading=\"lazy\" decoding=\"async\" width=\"300\" height=\"185\" src=\"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1-300x185.png\" class=\"attachment-medium size-medium\" alt=\"Schematic view of an Arduino connected to three force sensing resistors (FSR) and a speaker. Each of the three FSRs have one of their respective legs connected to +5 volts. Each of the other legs connect to one leg of a 10-kilohm resistor and simultaneously connect to one of the Arduino&#039;s analog input pins. In this case the pin connections are A0, A1, and A2. Each of the respective 10-kilohm resistors then connect to ground. The red positive wire of the speaker is connected to digital pin 8 of the Arduino. The black ground wire of the speaker is connected to one leg of a 100 ohm resistor. The other leg of the 100-ohm resistor connects to ground.\" srcset=\"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1-300x185.png 300w, https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1.png 319w\" sizes=\"(max-width: 300px) 85vw, 300px\" \/><\/a><\/p>\n<p>Schematic view of an Arduino connected to three force sensing resistors (FSR) and a speaker. Each of the three FSRs have one of their respective legs connected to +5 volts. Each of the other legs connect to one leg of a 10-kilohm resistor and simultaneously connect to one of the Arduino&#8217;s analog input pins. In this case the pin connections are A0, A1, and A2. Each of the respective 10-kilohm resistors then connect to ground. The red positive wire of the speaker is connected to digital pin 8 of the Arduino. The black ground wire of the speaker is connected to one leg of a 100 ohm resistor. The other leg of the 100-ohm resistor connects to ground.<\/p>\n"},"caption":{"rendered":"<p>Schematic view of an Arduino connected to three force sensing resistors (FSR) and a speaker. Each of the three FSRs have one of their respective legs connected to +5 volts. Each of the other legs connect to one leg of a 10-kilohm resistor and simultaneously connect to one of the Arduino&#8217;s analog input pins. In this case the pin connections are A0, A1, and A2. Each of the respective 10-kilohm resistors then connect to ground. The red positive wire of the speaker is connected to digital pin 8 of the Arduino. The black ground wire of the speaker is connected to one leg of a 100 ohm resistor. The other leg of the 100-ohm resistor connects to ground.<\/p>\n"},"alt_text":"Schematic view of an Arduino connected to three force sensing resistors (FSR) and a speaker. Each of the three FSRs have one of their respective legs connected to +5 volts. Each of the other legs connect to one leg of a 10-kilohm resistor and simultaneously connect to one of the Arduino's analog input pins. In this case the pin connections are A0, A1, and A2. Each of the respective 10-kilohm resistors then connect to ground. The red positive wire of the speaker is connected to digital pin 8 of the Arduino. The black ground wire of the speaker is connected to one leg of a 100 ohm resistor. The other leg of the 100-ohm resistor connects to ground.","media_type":"image","mime_type":"image\/png","media_details":{"width":319,"height":197,"file":"LabToneInstrument_schem1.png","sizes":{"thumbnail":{"file":"LabToneInstrument_schem1-150x150.png","width":150,"height":150,"mime_type":"image\/png","source_url":"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1-150x150.png"},"medium":{"file":"LabToneInstrument_schem1-300x185.png","width":300,"height":185,"mime_type":"image\/png","source_url":"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1-300x185.png"},"full":{"file":"LabToneInstrument_schem1.png","width":319,"height":197,"mime_type":"image\/png","source_url":"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1.png"}},"image_meta":{"aperture":0,"credit":"","camera":"","caption":"","created_timestamp":0,"copyright":"","focal_length":0,"iso":0,"shutter_speed":0,"title":""}},"post":225,"source_url":"https:\/\/itp.nyu.edu\/physcomp\/wp-content\/uploads\/LabToneInstrument_schem1.png","_links":{"self":[{"href":"https:\/\/itp.nyu.edu\/physcomp\/wp-json\/wp\/v2\/media\/2193"}],"collection":[{"href":"https:\/\/itp.nyu.edu\/physcomp\/wp-json\/wp\/v2\/media"}],"about":[{"href":"https:\/\/itp.nyu.edu\/physcomp\/wp-json\/wp\/v2\/types\/attachment"}],"author":[{"embeddable":true,"href":"https:\/\/itp.nyu.edu\/physcomp\/wp-json\/wp\/v2\/users\/2"}]}}