1. November 2007
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [Binary CDMA for BAN]
Date Submitted: [9 Nov., 2007]
Source: [Changsoo Eun, Seung-Moon Ryu] Company [CNU, Casuh, Inc.]
Address [813 Leaders Building, Yatap-dong, Bundang-gu, Seongnam, Gyeonggi-do , Korea ]
Voice:[ ], FAX: [ ],
Re: [Contribution to IEEE SG-BAN Meeting, November 2007]
Abstract: [This document presents Binary CDMA: a constant envelope CDMA air interface for short range BAN applications.]
Purpose: [Proposal]
Notice: This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein.
Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P
Casuh, Inc.

2. November 2007
Binary CDMA for BAN
Casuh, Inc.
Casuh, Inc.

3. What is Binary CDMA? What is binary CDMA? Constant RF envelope
November 2007
What is Binary CDMA?
What is binary CDMA?
Constant RF envelope
RF amplifiers with high linearity are not necessary.
Simple circuitry
Support both CDMA and TDMA
Casuh Code 1
Casuh Code 2
Casuh Code 3
Data1
Data2
Data3
Casuh Code 4
Data4
Casuh Code n
Data n M
Casuh Code 1
Casuh Code 2
Casuh Code 3
Casuh Code 4
Casuh Code n
Data1
Data2
Data3
Data4
Data n
TDMA RF
TDMA RF
Casuh, Inc.

4. What is Binary CDMA? How to generate B-CDMA … … … … November 2007 13 X
c1(t)
d1(t)
e1(t)
c2(t)
d2(t)
e2(t)
cn(t)
dn(t)
en(t)
… … 11
Encoding X
c1(t)
d1(t)
e1(t)
c2(t)
d2(t)
e2(t)
cn(t)
dn(t)
en(t)
… … 9 7 5 3
Tr = 1 1
Binary
CDMA
Binary
CDMA -1 -3 -5 -7 -9
-11
-13
n : odd
Casuh, Inc.

5. What is Binary CDMA? PW(pulse width) and SB (sign bit) November 2007 5-5 -3 -1 1 3 5 Tc
Truncated Signal
PW modulated Signal
Sign Bit Signal
Casuh, Inc.

6. Error Performance Error performance of SB-CDMA 64-bit code
November 2007
Error Performance
Error performance of SB-CDMA
64-bit code
Casuh, Inc.

7. November 2007
Error Performance
Another simulation
Casuh, Inc.

8. Error Performance Error performance of SB-CDMA
November 2007
Error Performance
Error performance of SB-CDMA
64-bit code of duo binary format
Casuh, Inc.

9. Binary CDMA without Loss
November 2007
Binary CDMA without Loss
CS/CDMA d1
Block A
orthogonal
code set
C1 ~ C8 d2 Ci d3
Correlator c1 d1 d4
max absolute value Ci d5 d2
Block A
orthogonal
code set
C9 ~ C16
Correlator
Encoding d6 Cj c2 d3 d7
Correlator d8 c3 d9
Block A
orthogonal
code set
C17 ~ C24
d10 Ck
d11
d12
d12
Correlator p1
c32
Block A
orthogonal
code set
C25 ~ C32 p2 Cp p3 p4
Casuh, Inc.

10. Error Performance Comparison of error performances
November 2007
Error Performance
Comparison of error performances
Without amplifier nonlinearity
Casuh, Inc.

11. Error Performance Comparison of error performances
November 2007
Error Performance
Comparison of error performances
With amplifier nonlinearity
Ideal
Channel
Saturated
Eb /N0
BER
Casuh, Inc.

12. Introduction of Retaw Retaw (reversed ‘w-a-t-e-r’)
November 2007
Introduction of Retaw
Retaw (reversed ‘w-a-t-e-r’)
Retaw is a proprietary PHY/MAC specification.
Chips for short-range applications are already available.
Wireless multi-channel translation system
Wireless conference system
Pico-net digital broadcasting system
Multiple wireless microphone system
Technologies in Retaw
PHY
Binary CDMA for baseband
ZigBee RF Compatible
MAC
Uniformed Super Frame Structure
Proprietary protocol
Casuh, Inc.

13. Introduction of Retaw Features of Retaw Low power consumption
November 2007
Introduction of Retaw
Features of Retaw
Low power consumption
Deep sleep possible
Low interference
Simultaneous communications
Peer-to-peer
Point-to-multipoint
Simple (cheap) hardware
Support for scalable data rate up to 3.2 Mbps
Inherent security
Very simple MAC
Accommodates more than 100 devices
Multiple simultaneous network operation
Casuh, Inc.

14. Multi-hop/Multi-link
November 2007
Evolution of Retaw
Retaw: Now and Future
Retaw-1 (Now)
Retaw-2 (Future)
Carrier Freq.
2.4 G
400M, 900M, 2.4G
Protocol Clock Rate
1 Mbps
62.5 K, 1 M
Data Rate
10 K Mbps
50 bps Mbps
Power Consumption
(active/sleep)
30 mA/50 µA
(100 µA - 20 mA)/10 µA
RF Modulation
GFSK, MSK
MSK, QPSK
Preamble length
128 bits
8 bits, 128 bits
Baseband Modulation
HC/CDMA, TDMA
Long Code, SB/CDMA, TDMA
Topology
Peer-to-peer,
Point-to-multipoint
Retaw1 +
Multi-hop/Multi-link
Applications
Audio, Voice, Data
Retaw1 + Mobile Video,
USN, BAN
Casuh, Inc.

15. Evolution of Retaw Retaw-2 = Enhanced Retaw-1 + ZigBee November 2007
S/P
Codeword
(16)
Data
S/P d1 d2 Ci c1 d3 d1 d4 c2
Data x 3 d5 d2 d6 Cj
Encoding
ZigBee RF
ZigBee RF d3 d7 c3
Data d8 d9
d10 Ck
d11
d12 p1
d12 p2 Cp
c32 p3 p4
High Data
High Data
Low Data
Low Data
Long Code
Long Code
Casuh, Inc.

16. Evolution of Retaw Modes of Retaw-2 Mode 1 Mode 2 Mode 3 Mode 4 Remark
November 2007
Evolution of Retaw
Modes of Retaw-2
Mode 1
Mode 2
Mode 3
Mode 4
Remark
Type
Binary
CDMA
TDMA
ZigBee
Long
Code
Frequency
2.4G,900M,400M
2.4G
Synch
Two PHY
Data Rate
800K
3.6M
250K
50bps
Pure data
# Simul. Ch.
5 x 16 16
128
Code Length 64 -
16 / 32
16000
Multiple Access
Synch -
LBT
CSMA-CA
Asynch -
collision
Application
Multi channel
Multimedia
Sensor
Secure
control
Casuh, Inc.

17. Peak Power Consumption
November 2007
Evolution of Retaw
Retaw for BAN
Requirements
Retaw
Operating Range
In, on, or around Body
Up to 3 m
Data Rate
Scalable
Few Kbps - few Mbps
Frequency
Unlicensed & MIC
M, ISM, UWB
Peak Power Consumption
Few μW - few 10mW
Coexistence
No interference
Up to 5 pico-nets
Up to 100 devices/net
Connection
Virtual path
Peer-to-peer,
Peer-to-multipoint
Topology
Multiple simultaneous link
Multi-hop/Multi-link
Security
High
Authentication, privacy, encryption
Future Proof
Realizable
Proven technology
Location
Desirable
Few cm
Casuh, Inc.

18. Evolution of Retaw Retaw for BAN Secure channel procurement QoS
November 2007
Evolution of Retaw
Retaw for BAN
Secure channel procurement
QoS
Low power consumption
Synchronized dual Phy (Avoid Mutual Interference)
Scalable Data Rate (Adaptive Process Gain)
Reliable Link Connection (Relay)
Casuh, Inc.