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| resources:eval:user-guides:circuits-from-the-lab:cn0190 [15 Sep 2017 05:21] – Glaizel Arinuelo | resources:eval:user-guides:circuits-from-the-lab:cn0190 [30 Jul 2021 07:17] (current) – Victor Calinao, Jr | ||
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| ====== EVAL-CN0190-EB1Z Overview ====== | ====== EVAL-CN0190-EB1Z Overview ====== | ||
| + | |||
| [[ADI> | [[ADI> | ||
| The circuit supplies most of the typical power rails required for digital and analog circuits and also demonstrates an easy way to realize overvoltage, | The circuit supplies most of the typical power rails required for digital and analog circuits and also demonstrates an easy way to realize overvoltage, | ||
| - | The circuit is flexible and can accept a wide input voltage range from 6 V to 14 V. This is possible because the highly efficient switching controllers and regulators used in the first stage of each power rail have correspondingly wide input ranges. The [[http:// | + | The circuit is flexible and can accept a wide input voltage range from 6 V to 14 V. This is possible because the highly efficient switching controllers and regulators used in the first stage of each power rail have correspondingly wide input ranges. The [[adi>ADM1178|ADM1178]] block provides overvoltage and overcurrent detection and protection for the input supply, as well as hotswap control for the whole system. The [[adi>ADM1066|ADM1066]] offers a single-chip solution for power supply monitoring and sequencing control for all of the 12 power rails and also margining control for the 3.3V(2A) rail. |
| - | \\ | + | \\ |
| {{: | {{: | ||
| \\ | \\ | ||
| - | ===== Equipment Needed (Equivalents Can be Substituted) ===== | + | ====== Equipment Needed (Equivalents Can be Substituted) |
| \\ | \\ | ||
| - | * Tektronix TDS3034B 4-channel 300 MHz color digital phosphor oscilloscope | + | |
| - | * Tektronix P6139A, 500 MHz, 8 pF, 10 MΩ, 10× passive prob \\ | + | * Tektronix P6139A, 500 MHz, 8 pF, 10 MΩ, 10× passive prob |
| - | * Agilent N3302A, 150 W, 0 A to 30 A, 0 V to 60 V electronic load module combined with N3300A | + | * Agilent N3302A, 150 W, 0 A to 30 A, 0 V to 60 V electronic load module combined with N3300A |
| - | * Agilent E3631A, 0 V to 6 V, 5 A; 0 V to ±25 V, 1 A, triple output dc power supply | + | * Agilent E3631A, 0 V to 6 V, 5 A; 0 V to ±25 V, 1 A, triple output dc power supply |
| - | * Agilent 3458A, 8.5 digit digital multimeter | + | * Agilent 3458A, 8.5 digit digital multimeter |
| - | * Fluke 15B digital multimeter | + | * Fluke 15B digital multimeter |
| - | * USB-SDP-CABLEZ | + | * USB-SDP-CABLEZ |
| - | * PC (Windows 2000 or Windows XP) with USB interface | + | * PC (Windows 2000 or Windows XP) with USB interface |
| - | + | ||
| - | + | ||
| - | \\ | + | |
| ===== Test Setup Functional Block Diagram ===== | ===== Test Setup Functional Block Diagram ===== | ||
| \\ | \\ | ||
| Line 47: | Line 46: | ||
| with preset amplitude and frequency \\ </ | with preset amplitude and frequency \\ </ | ||
| - | \\ | + | \\ |
| + | \\ | ||
| + | ===== Connectors and Jumper Configurations ===== | ||
| + | \\ | ||
| + | {{: | ||
| + | \\ | ||
| + | ==== Input Power ==== | ||
| + | Connector 1, and should be between +6V and +14V\\ | ||
| - | \\ | + | ==== Output Power Options ==== |
| - | ====== Connectors and Jumper Configurations ====== | + | ^ Image Indicator ^ Voltage Output ^ Current Output ^ Power Topology ^ |
| - | \\ | + | | Connector |
| - | {{: | + | | Connector |
| - | Description \\ | + | | Connector |
| - | 1 - +6V to +14V input power supply\\ | + | | Connector |
| - | 2 - +3.3V (2A) power rail based on synchronous buck topology \\ | + | | Connector |
| - | 3 - +1.8V (1A) power rail based on synchronous buck topology\\ | + | | Connector |
| - | 4 - +1.5V (1A) power rail based synchronous buck topology \\ | + | | Connector |
| - | 5 - +1.0V (2A) power rail supplied by LDO\\ | + | | Connector |
| - | 6 - +1.2V (0.5A) power rail based on synchronous buck topology \\ | + | | Connector |
| - | 7 - +3.0V (0.1A) power rail supplied by LDO \\ | + | | Connector |
| - | 8 - -5V (0.2A) power rail generated from 5V (1A) using inverting buck boost topology\\ | + | | Connector |
| - | 9 - +5V (1A) power rail based on synchronous buck topology\\ | + | | Connector |
| - | 10 - +2.5V (1A) power rail based on synchronous buck topology\\ | + | |
| - | 11 - +3.3V (0.1A) power rail supplied by LDO \\ | + | ==== Switch |
| - | 12 - Can be set to four different positive analog power rail (+2.5V, +5V, +12V, +15V) (0.1 A) based on sepic-cuk topology \\ | + | |
| - | 13 - Can be set to four different negative analog power rail (-2.5V, -5V, -12V, -15V) (0.1 A) based on sepic-cuk topology \\ | + | * To select the VDD/VEE outputs on Connector 12 and Connector 13, you must setup the switch matrix. |
| - | 14 - | + | {{ : |
| - | {{: | + | |
| - | 15 - I2C serial interface (1- SCLK, 2 - SDA, 3 - GND)\\ | + | ==== I2C Programming Interface ==== |
| - | < | + | |
| - | ADM1066 through this I2C bus connector JP1 to make the power | + | I2C serial interface |
| - | monitoring and sequencing control for your own application | + | |
| - | using the [[http:// | + | |
| \\ | \\ | ||
| - | ====== Software and Driver Installation ====== | ||
| - | 1. Install [[http:// | ||
| - | 1.1 Open the file setup.exe located at the path \ADMxxxx Run-Time Installer\Installer\Volume\setup.exe \\ {{: | ||
| - | < | ||
| - | 1.2 Follow the on-screen prompts to install the software \\ | ||
| - | {{: | ||
| - | 1.3 After installing the driver, Windows can automatically find new hardware when you plug the USB- | ||
| - | {{: | ||
| - | 2. Install the [[http:// | ||
| - | 2.1 Open the file setup.exe located at the path \SuperSequencer Apps SW Installer\Volume\setup.exe \\ | ||
| - | {{: | ||
| - | < | ||
| - | 2.2 Follow the on-screen prompts to install the software \\ | ||
| - | {{: | ||
| - | {{: | ||
| - | {{: | ||
| - | {{: | ||
| - | 2.3 Install Graphviz \\ | ||
| - | {{: | ||
| - | 2.4 Upon completion, follow the on-screen promps to install the prog106x Setup Application Software \\ | ||
| - | {{: | ||
| - | {{: | ||
| - | {{: | ||
| - | {{: | ||
| - | ====== Downloading Firmware for ADM1066 ====== | + | ===== Software and Driver Installation |
| - | 1. Copy the eeprom file i.e. ADM1066_SuperSequencing_REVB.hex in the root directory on Disk C: \\ | + | |
| - | i.e. (C: | + | You can design your own control strategy and download it into the ADM1066 through this I2C bus connector(JP1) to make the power monitoring and sequencing control for your own custom application using the [[adi> |
| - | 2. Plug USB to I2C converter dongle into the USB port on your PC. Plug the other side of the cable into the JP1 on the right side of the EVAL-CN0190-EB1Z. | + | |
| - | < | + | To create a customer sequencing solution, and programming |
| - | Signal Connection: \\ | + | - Download the USB-SDP-CABLEZ driver |
| - | SCL<->SCL \\ | + | - Install the //Super Sequencer Software// |
| - | SDA<->SDA \\ | + | - Install // |
| - | GND< | + | - Install the //prog106x Setup Application Software// |
| + | - Connect the USB-SDP-CABLEZ | ||
| + | - Download | ||
| + | |||
| + | Step by step details are provided below. | ||
| + | |||
| + | <note> | ||
| + | The ADM1066 comes **pre-programmed out of the box** where ALL the power outputs are active at the same time. So you do NOT need to program the board if you do not want to. The only time you need to program this board is if you want to create your own customer power sequencing/ | ||
| </ | </ | ||
| - | 3. Turn on the power to the supply of EVAL-CN0190-EB1Z \\ | ||
| - | 4. Open the Command Prompt (C: | ||
| - | {{: | ||
| - | 5. In the cmd.exe, key the command prog106x download 6A c: | ||
| - | < | ||
| - | 6. The on-chip EEPROM of ADM1066 is successfully programmed if the picture below is shown on the screen after several seconds. \\ | ||
| - | {{: | ||
| + | ==== Driver Installation ==== | ||
| + | <WRAP center round download 80%> | ||
| + | Download the [[adi> | ||
| + | </ | ||
| + | - Install the USB-SDP-CABLEZ driver | ||
| + | - Open the file setup.exe located at the path \ADMxxxx Run-Time Installer\Installer\Volume\setup.exe {{: | ||
| + | It is recommended that you install the software to the default directory.</ | ||
| + | - Follow the on-screen prompts to install the software{{: | ||
| + | - Plug in the USB-SDP-CABLEZ into your PC or labtop using the USB cable. | ||
| + | - Windows will automatically find the new hardware(USB-SDP-CABLEZ) plugged the into the PC.{{ : | ||
| - | ====== | + | ==== Sequencer Software Installation |
| - | <WRAP round 80% download> | + | |
| - | [[http://www.analog.com/ | + | <WRAP center round download 80%> |
| + | Download and Install the [[adi> | ||
| + | </ | ||
| + | |||
| + | - Open the file setup.exe located at the path \SuperSequencer Apps SW Installer\Volume\setup.exe{{:resources: | ||
| + | - Follow the on-screen prompts to install the software. \\ {{ : | ||
| + | - Install Graphviz. \\ {{ : | ||
| + | - Upon completion, follow the on-screen promps to install the prog106x Setup Application Software \\ {{ : | ||
| + | < | ||
| + | |||
| + | ===== Using Super Sequencer Software ===== | ||
| + | Super Sequencer Evaluation Software enables the user to create new control strategy and generates new intel hex file for ADM1066. For detailed information about Super Sequencer features, visit [[adi> | ||
| + | |||
| + | Generating new hex file using Super Sequencer Software | ||
| + | - Open SuperSequencerSoftwareEval.exe installed in PC {{: | ||
| + | - Assuming all the new configurations and controls were already done on the software, on the main window go to File and click Save Settings to File \\ {{: | ||
| + | - Select Create Intel Hex File and click Save \\ {{: | ||
| + | - Once completed saving, you now have a new hex file to download to ADM1066 | ||
| + | |||
| + | |||
| + | ===== Downloading Firmware for ADM1066 ===== | ||
| + | |||
| + | - Copy the eeprom file i.e. ADM1066_SuperSequencing_REVB.hex in the root directory on Disk C: (i.e. C: | ||
| + | - Plug USB to I2C converter dongle into the USB port on your PC. Plug the other side of the cable into the JP1 on the right side of the EVAL-CN0190-EB1Z.{{ : | ||
| + | < | ||
| + | - Turn on the power to the supply of EVAL-CN0190-EB1Z | ||
| + | - Open the Command Prompt (C: | ||
| + | - In the cmd.exe, key the command < | ||
| + | - The on-chip EEPROM of ADM1066 is successfully programmed if the picture below is shown on the screen after several seconds.{{ : | ||
| + | - Remove power or turn off the power supply on (), then re-apply the power supply in order to make ADM1066 update the program from embedded EEPROM. | ||
| + | |||
| + | ===== Schematic, PCB Layout, Bill of Materials ===== | ||
| + | |||
| + | <WRAP round 80% download> | ||
| + | [[adi>media/ | ||
| * Schematics | * Schematics | ||
| * PCB Layout | * PCB Layout | ||
| Line 133: | Line 156: | ||
| </ | </ | ||
| + | =====Registration===== | ||
| + | <WRAP round tip 80% > | ||
| + | Receive software update notifications, | ||
| + | // End of document // | ||
resources/eval/user-guides/circuits-from-the-lab/cn0190.1505445663.txt.gz · Last modified: 15 Sep 2017 05:21 by Glaizel Arinuelo