1. Chapter 11 - Reducing Interference in RFID Reader Networks

2. Figure 11.1 Basic RFID operation
Tag
RFID data processing subsystem
Reader
Backscatter signal
Antenna
High power CW
Network

3. Figure 11.2 Reader-to-tag collision
Interrogation region
R1’s read range
R2’s read range
Tag R1 R3
R3’s read range

4. Figure 11.3 (a) Reader-to-reader collision
R1 read range
R2 read range
Reader
Tag
R2’s interference range R2 T1 T2 T3 T4
R1‘s interference range

5. Figure 11.3 (b) Reader-to-reader collision
R1 read range
R2 read range
Reader
Tag
R2’s interference range R2
Figure 11.3 (b). Reader-to-reader collision. T1 T2 T3 T4

6. Table 11.1 The ISO 18000 standards for RFID
Frequencies
Spectrum
ISO/IEC :2004
Below 135 kHz
Low frequency
ISO/IEC :2008
At MHz
High frequency
ISO/IEC :2008
At 2.45 GHz
Microwave
ISO/IEC :2004
At 860 MHz to 960 MHz
UHF
ISO/IEC :2008
433 MHz

7. Figure 11.4 RFID reader anti-collision algorithms
Scheduling based approaches
Control mechanism based approaches
Coverage based approaches
Central cooperator based approaches
Other approaches
TDMA based anti- collision algorithms
DCS
Colorwave
AC-MRFID
HiQ learning
Pulse
DiCa
McMAC
Clustering based
Transmission Power control based

8. Figure 11.5 Frame structure of TDMA based anti-collision algorithm…. Tn F1 F2
Reader to reader communication period Reader to Tag communication period.
Tn-1

9. Figure 11.6 DCS Pseudocode DCS Subroutine If experienced collision
current color == random(maxcolors)
broadcast kick with new color
If kick packet received with current color
select different color ramdomly within maxcolors

10. Figure 11.7 An illustration of AC-MRFID protocol
R1’s interference range (ri1)
R1’s read range (rr1) R1 R2 T1 T2 T3

11. Figure 11.8 Hierarchical structure of Q-learning
Root Q-server
Q-server
R-server R1 R2 R4 R5 R3 R6 R7 R8
Frequency and Timeslot allocation
Collision Information R9
R10
R11
R12
R13
Rn1
Rn2
Rn4
Rn5
Rn3
Rn6
Rn7
Rn8 ……

12. Figure 11.9 MCMAC working principle
Reset Tmin
-Lost this cycle
Listening in CCN
-CM
NOT received
(for Tmin)
-CN is free
-Enter in contention phase
-CM received
-Check
for free CN
-Occupy the DCN
-Broadcast CM
-Finished reading
-Continue cycle
-Send control packet (every slot interval)
CN: Channel
CCN: Control Channel
DCN: Data Channel
Tmin: Minimum Listening Time
CM: Control Message No
Yes

13. Figure 11.10 CC-RFID system architecture
CC Receiver Module 1
CC Relay Module
CC Sender Module 1
CC Sender Module 2
CC Storage Module
CC Receiver Module 2 T R2 R4
R10
Central Cooperator device modules

14. Figure 11.11 Two working schemes of CC-RFID
CC Schedule & Multiplexing
Feedback from Tag
To Tag
From Reader
Inverse Multiplexing
Send to Each Reader
CC-RFID scheme one.
CC Timer
CC Feedback
Query to Tag
CC-RFID scheme two (Updating process).
CC Module
Tags
Readers
CC Search
CC-RFID scheme two (Reading communication).

15. Table 11.2 Comparison of reader anti-collision algorithms
Function used
Carrier sensing
Major Overhead
Distributed Control
Fixed Channel Assignment (FCA)
Dynamic Channel
Assignment (DCA)
Tag side consideration for collision avoidance
Colorwave
Color number 
Time synchronization 
AC-MRFID
HiQ Learning
Cost function
Management overhead
Pulse
Beacon frame
Energy consumption and additional channel resource
DiCa
Energy aware
Additional channel resource and time
MCMAC
LBT
Additional channel resource and computational overhead
CC-RFID
MP2P
Special hardware
ACHA
Probability based channel hopping
Multiple channel resources

16. Table 11.3 Comparison in terms of channel assignment
Criterion 
Algorithm 
Multi Chann el
Multi- data Channel
Dedicated Control Channel Requiremen ts
Indispensabl e Initiative
Optimization Technique
MCMAC
Yes
LBT in multi channel
Multiple data channel assignment
ACHA
LBT & channel hopping
Multiple data channel hopping
Pulse No
Beaconing in control channel
Control signaling
DiCa
Handshakin g
Improved control channel range

17. Figure 11.12 Throughput comparison