S15: RFID Security Box

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Revision as of 20:47, 27 May 2015 by Proj user18 (talk | contribs) (Software Design)

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Grading Criteria

  • How well is Software & Hardware Design described?
  • How well can this report be used to reproduce this projec
  • Code Quality
  • Overall Report Quality:
    • Software Block Diagrams
    • Hardware Block Diagrams
      Schematic Quality
    • Quality of technical challenges and solutions adopted.

Project Title

Abstract

The RFID Security Box is a container with an electronic lock that can be unlocked by using RFID tags, NFC-compatible devices, or a manually entered passcode.

Objectives & Introduction

Show list of your objectives. This section includes the high level details of your project. You can write about the various sensors or peripherals you used to get your project completed.

A security box for storing valuables that is accessible through a numeric keypad, NFC-compatible device, and RFID tags, tokens, and cards.

  • NFC/RFID Controller breakout board
  • Lock-style Solenoid
  • 3x4 Phone-style Matrix Keypad
  • RGB LCD Screen

Team Members & Responsibilities

  • Rajwinder Ruprai
    • NFC/RFID driver
    • Keypad driver
    • Security box layout
  • Charles MacDonald
    • LCD driver and backlight circuit
    • Solenoid driver and control circuit
    • Power supply circuit

Schedule

Show a simple table or figures that show your scheduled as planned before you started working on the project. Then in another table column, write down the actual schedule so that readers can see the planned vs. actual goals. The point of the schedule is for readers to assess how to pace themselves if they are doing a similar project.

Week# Date Task Actual
1 04/14 Order parts needed for required functionality, work on box design
(component placement, mounting requirements, etc.)
Completed
Week# Date Task Actual
2 04/21 Develop keypad and LCD display drivers. In progress
Week# Date Task Actual
3 04/28 Develop solenoid driver and start work on RFID/NFC driver. In progress
Week# Date Task Actual
4 05/5 Finish RFID/NFC driver, finish PSU wiring. Upcoming
Week# Date Task Actual
5 05/12 Component integration and testing. Upcoming
Week# Date Task Actual
6 05/19 Tweaking and polishing implementation. Upcoming
Week# Date Task Actual
7 05/25 Project presentation. Upcoming

Parts List & Cost

Give a simple list of the cost of your project broken down by components. Do not write long stories here.

Quantity Description Cost
1 Lock-style Solenoid - 12VDC $14.95
1 i2c / SPI character LCD backpack $10.00
1 MiFare Classic (13.56 MHz) tag assortment (1KB) $10.00
1 PN532 NFC/RFID controller breakout board (v1.6) $39.95
1 3x4 Phone-style Matrix Keypad $7.50
1 RGB backlight negative LCD 16x2 + extras (RGB on black) $13.95
1 Extra-long break-away 0.1" 16-pin strip male header (5 pieces) $3.00
1 Murata OKI-78SR Fixed Output 1.5A DC/DC Converter (5.0V) $4.30
1 ST Microelectronics 3.3V Linear Regulator $0.64
1 1N4007 Diode $0.13
1 Meanwell RS-15-12 +12V, 1.3A PSU $9.95
1 IEC 320-C14 AC power receptacle $0.79

Design & Implementation

The design section can go over your hardware and software design. Organize this section using sub-sections that go over your design and implementation.

Hardware Design

Initial rough draft of system architecture / schematic diagram (external link):

Hardware Interface

The various buses are allocated as follows

  • UART2 (free)
  • UART3 (free, either one is a candidate for the UART interface of the fingerprint reader)
  • SSP0 Shift register chain
  • SSP1 AT45/SD card/PN532
  • GPIO Various control outputs and inputs

GPIO assignments

  • P2.0 : Keypad matrix row data, bit 0
  • P2.1 : Keypad matrix row data, bit 1
  • P2.2 : Keypad matrix row data, bit 2
  • P2.3 : Keypad matrix row data, bit 3
  • P2.4 : Storage register clock for shift register #1
  • P2.5 : Storage register clock for shift register #2
  • P2.6 : External reset button input
  • P2.7 : LCD interface, data bit 7 (input to read busy status)
  • P0.19 : PN532 chip select for SSP1 bus (also shared with AT45 and SD card)

Shift register assignments

  • S1.0 : LCD panel tri-color backlight LED blue cathode
  • S1.1 : LCD panel tri-color backlight LED green cathode
  • S1.2 : LCD panel tri-color backlight LED red cathode
  • S1.3 : To solenoid coil connector
  • S1.4 : Piezo buzzer (negative terminal)
  • S1.5 : Keypad matrix column select, bit 0
  • S1.6 : Keypad matrix column select, bit 1
  • S1.7 : Keypad matrix column select, bit 2
  • S2.0 : LCD interface, register select (RS)
  • S2.1 : LCD interface, read/write (R/W#)
  • S2.2 : LCD interface, enable strobe (EN)
  • S2.3 : (Not used)
  • S2.4 : LCD interface, data bit 4
  • S2.5 : LCD interface, data bit 5
  • S2.6 : LCD interface, data bit 6
  • S2.7 : LCD interface, data bit 7

Keypad implementation

The keypad is arranged as a 4x3 matrix. Where each row and column intersect is a switch, and a physical connection between the row and column is made when the switch is depressed. Otherwise there is no connection and the relationship between the row and the column at that point appears as an open circuit.

As the keypad has no datasheet the first task was to disassemble the keypad and use the continuity test function of a multimeter to determine the pin assignments:

  • Pin 1 - Not used (goes to a test point on the PCB)
  • Pin 2 - Row (keys *,0,#)
  • Pin 3 - Row (keys 7,8,9)
  • Pin 4 - Row (keys 4,5,6)
  • Pin 5 - Row (keys 1,2,3)
  • Pin 6 - Column (keys 3,6,9,#)
  • Pin 7 - Column (keys 2,5,8,0)
  • Pin 8 - Column (keys 1,4,7,*)

The notation of row vs. column is completely arbitrary, and were chosen only to have a consistent naming scheme.

Solenoid implementation

The solenoid used (Adafruit #1512) is designed to function similarly to the latch of a door. A spring pushes the latch outwards such that the door is locked when the system is turned off. The solenoid contains a coil that generates a magnetic field when energized, which draws the latch inwards allowing the door to be opened. Thus the solenoid locks the door when off, and unlocks it when on.

The solenoid requires +12V to operate and draws 680mA normally. When the solenoid is turned off after a period of activation, the magnetic field collapses, at which point the force of the internal spring overcomes the force of the magnetic field holding the latch in place, and the spring can then move the latch to the outward position.

When the magnetic field collapses current is induced in the coil, causing a large voltage spike that can be damaging to any digital circuitry connected to it. To prevent this, a diode is placed in parallel with the solenoid coil with the cathode to the positive voltage supply (+12V). This provides a safe discharge path so that the voltage spike does not go into the digital circuitry.

To control the the solenoid with a GPIO port, a ULN2803 is used, which is an eight channel Darlington transistor array. A Darlington transistor is a pair of transistors in series that can sink a large amount of current, and can interface to higher voltage signals such as 12V. The ULN2803 has built-in resistors to provide a TTL/CMOS compatible interface. Two important aspects to remember are the the Darlington transistors have an inverted output in relation to the input, such that an active-high input sinks current and an active-low input makes the output high impedance. Secondly, the high impedance output should have a pull-up or pull-down resistor to prevent the output from oscillating.

Keypad scanning

The keypad can be scanned as follows

1. Assign the columns as outputs (3-bit output). 2. Assign the rows as inputs (4-bit input), with internal pull-up resistors enabled. 3. For each column, drive the corresponding column output low (e.g. for column bits 2,1,0, the will be set to

  • 1,1,0 : Select column #0
  • 1,0,1 : Select column #1
  • 0,1,1 : Select column #2

4. When a given column is selected, input the row data. 5. Row bits will be 0 where the row and column intersect AND the key is pressed, or 1 where the key is released.

Note that the keypad;s operation is fully mechanical like any switch, there is no ground or power connections necessary.

Software Design

Show your software design. For example, if you are designing an MP3 Player, show the tasks that you are using, and what they are doing at a high level. Do not show the details of the code. For example, do not show exact code, but you may show psuedocode and fragments of code. Keep in mind that you are showing DESIGN of your software, not the inner workings of it.

Implementation

This section includes implementation, but again, not the details, just the high level. For example, you can list the steps it takes to communicate over a sensor, or the steps needed to write a page of memory onto SPI Flash. You can include sub-sections for each of your component implementation.

Testing & Technical Challenges

Describe the challenges of your project. What advise would you give yourself or someone else if your project can be started from scratch again? Make a smooth transition to testing section and described what it took to test your project.

Include sub-sections that list out a problem and solution, such as:

Issue #1 : Backlight control

The LCD panel has a RGB backlight consisting of a single RGB LED, that has a common anode and three independent cathodes. Each cathode has a 200-ohm resistor in series to limit current to 25mA (when +5V supplied to the anode) per LED. In order to control the red, green, and blue channels of the backlight independently, a circuit is required that can interface GPIOs from the SJOne board to the cathode such that 25mA can be sunk per cathode. This amount of current to sink in order to fully turn on a single LED is beyond the limit of the LPC1758 ability, so a direct connection is not possible.

The solution is to use a Darlington transistor. The ULN2803 contains eight independent Darlington transistors, each of which has the appropriate base and collector resistors to appear as TTL/CMOS compatible inputs, suitable for control by the SJOne GPIOs directly. This chip can sink 500mA per transistor which meets and exceeds the current requirements of the RGB backlight.

Interfacing the backlight controls to three GPIOs will provide 2^3=8 total colors. However we will use the PWM function of the LPC1758 to to increase the range of available colors to several hundred thousand. This will also allow software-defined brightness control, to either set the brightness to a user-defined level or for strobing or flashing effects on the display by modulating the brightness over time.

Issue #2 : Power supply

The solenoid requires 12V, the SJOne board uses 3.3V, and the LCD backlight requires 5V. In order to meet this requirement a power supply circuit was designed with the goal of keeping efficiency high and heat output low.

A switching PSU is used to convert 120V AC to 12V DC for the solenoid. The 12V is fed into a switching 5V regulator to provide 5V for the LCD backlight. Note that the relatively large voltage drop from 12V to 5V does not cause excessive heat due to the switching regulator being used, thus no heatsinking or other cooling methods are required. Finally, the 5V is fed into a 3.3V linear regulator. At this point the voltage drop is relatively small (approx. 2V) and the corresponding heat dissipation is low.

In this way all three power rails (3.3V, 5V, and 12V) can be provided to the system. The least efficient part is the 3.3V linear regulator, but the switching 5V regulator and switching 12V PSU are highly efficient in terms of conversion.

Conclusion

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Project Video

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Project Source Code

References

Acknowledgement

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References Used

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Appendix

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