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HF Antenna Configuration

Learn how to optimize HF antenna configurations for better tag reading performance and range in RFID systems. Understand the impact of antenna size, field strength, and field lines to maximize reading efficiency. Explore methods for reading closely packed tags and tags in various orientations.

philipjmiller
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HF Antenna Configuration

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  1. HF Antenna Configuration

  2. HF Antenna Configuration • Background • HF tags were developed with particular applications in mind • Express parcels and packages • Airline baggage. • These applications had certain performance criteria • A reading zone 1m × 1m × 1m (approx 39” cubed) • Conveyor belts moving up to 3m/s (600 ft/sec) • Multiple tags in the field (around 5) • These criteria should be kept in mind when exploring more ambitious applications (greater reading distances/ more tags in the field)

  3. HF Antenna Configuration • What if I want more than 1m range? • As a general rule, the larger the antenna loop, the longer the reading range. • A 1m × 1m Antenna can achieve up to 1m range • If the antenna gets much larger, the range drops again • These large antennas may exceed legal power limits. • Large antennas have a low field density and perform poorly when there are large numbers of tags in the field. • It is better to use opposing pairs of antennas • They can be driven from a single reader using a splitter • They can be optimised for tags parallel or at right angles to the antenna • They can be ‘rotated’ to read tags in more than one orientation

  4. HF Antenna Configuration • What if I want to read lots of tags in the field? • As a general rule, the smaller the antenna loop, the better the ability to read closely packed tags • When tags are close together they • De-tune each other • Absorb more of the available RF energy • Smaller antennas can ‘illuminate’ tags that are closer together • If pairs of opposing antennas are to be used • Antennas on splitters develop a stronger field (Both driven) • Antennas that are ‘rotated’ have a weaker field (only one antenna is driven. • ‘Rotating field’ antennas should be closer together than those on a splitter • Another method is the alternately drive each antenna with a MUX

  5. 2.00 1.90 1.80 1.70 1.60 1.50 H(x)r = 0.5 m 1.40 H(x)r = 0.4 m 1.30 H(x)r = 0.3 m 1.20 H(x)r = 0.2 m 1.10 H(x) [A/m] 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 0.00 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Metres HF Antenna Configuration • Magnetic Field Strength • Larger size antennas have lower field strengths close to the antenna, but read at longer distances. • Small antennas have high field strengths close to the antenna but the field quickly decays with distance.

  6. 0.40 H(x)r = 0.5 m 0.30 H(x)r = 0.4 m H(x)r = 0.3 m H(x)r = 0.2 m 0.20 H(x) [A/m] 152 dBµV/m 93 mA/m 0.10 (100 mA/m) 0.00 0.6 1.0 0.5 0.7 0.8 0.9 Metres HF Antenna Configuration • Magnetic Field Strength • The activation field strength for Tag-it HF-I inlays is 93 mA/m

  7. HF Antenna Configuration • Reading close packed tags (1) • The Antenna below was designed to create a strong field to read boxes of optical lenses. • It uses parallel loops to ensure each tag is near to an antenna • This is an straight-forward application – the tags are all in the same orientation Box of Lenses

  8. HF Antenna Configuration • The 72 tags are only a few mm apart and can be in any vertical orientation • The two crossed antennas are multiplexed • Reading close packed tags (2) • The Tube reader below uses small antennas to maximize the field strength

  9. HF Antenna Configuration • Antenna Field Lines • With a pair of antennas on a splitter, the field patterns depend on the phase. In-Phase Antennas Out-of-Phase Antennas

  10. SPLITTER HF Antenna Configuration • Using Splitters (1) • If antennas need to be used facing each other, I.e. across a conveyor system, they can be used with a 0º two way splitter to more than double the range. • Although a splitter adds losses, when antennas are used opposing each other, with careful tuning good performance results. • It is important though, to ensure that the antennas are in phase in we need to optimize for Tags passing parallel to the antennas.

  11. SPLITTER HF Antenna Configuration • Using Splitters (2) • If antennas need to be used facing each other, I.e. across a conveyor system, but the tag orientation is not optimal, use a 90º two-way splitter to ensure that the antennas are exactly 90º Out-of-Phase. • The same effect can be achieved using a ¼ wavelength of extra feeder cable to one antenna

  12. Rx only Tx and Rx HF Antenna Configuration • What if the tags can be in any orientation? • If the tags can pass through a system in any orientation, then multiple antennas have to be used. • We can create a ‘Rotating field’ effect by having a ‘Basic’ antenna that serves both transmit and receive functions (Tx/Rx) and opposing it, a ‘Complementary’ antenna that is receive only (Rx) • By careful adjustment of the Complementary antenna we can get the RF field to rapidly oscillate between In-Phase and Out-of-Phase thus reading Tags in both orientations

  13. HF Antenna Configuration • Complementary Antennas • A pair of rotating antennas will detects all tags in vertical orientations and some tags in high and low horizontal positions as they pass through. • Unfortunately, there is ALWAYS a reading hole at the centre for horizontal tags.

  14. Complementary (RX) Basic (TX/RX) HF Antenna Configuration • Removing the Reading Hole • The reading hole can be removed with a second set of antennas • The second set are connected to the same reader using two splitters • The overlap removes the hole • The reader power output will need to be increased to compensate for losses in the splitters

  15. Complementary (RX) Basic (TX/RX) HF Antenna Configuration • Removing the reading Hole (2) • The reading hole can also be removed with an extra horizontal antenna either above or below. • The antenna MUST be outside the zone of the Basic/ Complementary pair • This antenna is on a splitter with the Basic (RX/TX) antenna

  16. HF Antenna Configuration • What if I need the portal to be more compact? • One approach is to use three antennas and read each one in turn using a multiplexer. This was the basis of the British Airways tunnel reader and other portals in commercial use

  17. HF Antenna Configuration • Three antennas cover the three tag orientations

  18. HF Antenna Configuration • Three antennas in position

  19. HF Antenna Configuration • London Heathrow System

  20. HF Antenna Configuration • London Heathrow System Antennas

  21. HF Antenna Configuration • If we were to build another!

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