CMLMICRO FX651D4

CML Semiconductor Products
SPM and Security Subsystem
FX651
D/651/4 September 1997
1.0
Features
•
Provisional Information
Two Integrated Telecoms
Functions:
•
Low Power (3.3V) Requirement
•
•
12kHz SPM Detector
Half Duplex 18kHz Modem
•
Component Adjustable Input
Sensitivity
•
Compact 16-pin Small Outline
(SOIC) Package
•
Meets European 12kHz SPM
Frequency Specifications
•
Card Operated Telephone
Installations
•
Worldwide Pay-Phone
Applications
VBIAS
1.1
Brief Description
The FX651 integrated circuit combines 12kHz Subscriber Private Metering (SPM) detection with 18kHz
tone processing for anti-fraud purposes within a telephone system. This compact, low power device is
suitable for battery or line powered systems. Under simple logic or µProcessor control it will:
Decode 12kHz SPM pulses in the presence of high level voice and 18kHz signalling, and
provide a logic output.
Transmit an NRZ modulated 18kHz security tone to line.
Decode an incoming modulated 18kHz security tone in the presence of high level voice
and 12 kHz SPM tones, and provide a logic output.
Employing high accuracy switched capacitor filters, the FX651 is protected from crosstalk and false
decoding.
 1997 Consumer Microcircuits Limited
SPM and Security Subsystem
FX651
CONTENTS
Section
Page
1.0 Features .......................................................................................................... 1
1.1 Brief Description ............................................................................................ 1
1.2 Block Diagram ................................................................................................ 3
1.3 Signal List ....................................................................................................... 4
1.4 External Components .................................................................................... 6
1.5 General Description ....................................................................................... 7
1.5.1 Overall Function............................................................................. 7
1.5.2 Description of Blocks .................................................................... 7
1.6 Application Notes........................................................................................... 9
1.6.1 Device Sensitivity........................................................................... 9
1.6.2 Alias Responses ............................................................................ 9
1.7 Performance Specification.......................................................................... 10
1.7.1 Electrical Performance ................................................................ 10
1.7.2 Packaging ..................................................................................... 14
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1.2
FX651
Block Diagram
VBIAS
Figure 1 Block Diagram
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1.3
FX651
Signal List
Package
D4
Pin No.
Signal
Name
Description
Type
1
XTAL
I/P
The input to the on-chip oscillator inverter.
2
XTALN
O/P
The inverted output of the on-chip oscillator.
To use, a crystal of frequency 3.579545MHz
should be connected between these two pins.
No other external components are necessary.
4
CLKIN
I/P
A logic input which may be used when an
external clock signal is available in place of a
crystal. The external 3.579545MHz signal is
applied to this pin and XTAL is tied to VDD.
When not used, this pin should be tied to VDD.
5
RX/TXN
I/P
A logic input which controls the operating mode
of the device. In Rx, the device detects the
presence of 12kHz and 18kHz tones. In Tx, the
18kHz detect function is disabled and 18kHz is
transmitted from the TXOP pin modulated ON OFF by the NRZ Data pin.
6
NRZ DATA
I/P
A logic input used in Tx mode to ASK modulate
the TXOP pin. A logic high corresponds to no
tone and logic low corresponds to 18kHz.
7
TXOP
O/P
The Tx mode output. It is ASK modulated by the
NRZ data input pin. It transmits 18kHz or no
tone depending upon the state of the NRZ data
input pin. This pin goes to a high impedance
state when in Rx mode.
8
VSS
9
VBIAS
 1997 Consumer Microcircuits Limited
POWER
O/P
Negative supply rail.
A bias line for the internal circuitry, held at
½ VDD. It also forms the analogue ground for
the input differential amplifier. This pin must be
decoupled by a capacitor mounted close to the
device pins (see Figure 1).
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D/651/4
SPM and Security Subsystem
FX651
Package
D4
Pin No.
Signal
Name
Description
Type
10
AMPOP
O/P
The input amplifier's output. External
components are used in conjunction with the
amplifier to couple the line signal into the device.
Both inputs are available to allow a differential
configuration because a two wire input is
assumed.
11
NEGIP
I/P
The input amplifier's inverting input.
12
POSIP
I/P
The input amplifier's non inverting input.
13
DETECT
18kHz
O/P
The logic output of the 18kHz channel which is
active in Rx mode. Logic "0" signals the
presence on the line of 18kHz tone within
specified frequency and amplitude limits.
14
DETECT
12kHz
O/P
The logic output of the 12kHz channel. It goes
to logic "0" when a 12kHz tone within specified
frequency and amplitude limits has been
detected for a minimum length of time.
16
VDD
3, 15
N/C
Notes:
I/P =
O/P =
POWER
The positive supply rail. Levels and voltages are
dependent upon this supply. This pin should be
decoupled to VSS by a capacitor
(see Figure 1).
No internal connection: leave open circuit.
Input
Output
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1.4
FX651
External Components
Component
C1, C2
R1, R3
R2, R4
C3, C4
R5
C5
3.3V
33pF ±10%
1.1MΩ ±1%
270kΩ ±1%
5.0V
68pF ±10%
1.0MΩ ±1%
330kΩ ±1%
0.1µF ±20%
51kΩ ±1%
100pF ±10%
Notes
1. The device's sensitivity is approximately proportional to its power supply (VDD) voltage. The input
gain must compensate for this and also prevent the input circuitry saturating. It is recommended
that the amplifier components (R1 to R4, C1 and C2) are used to set the gain between -10dB (if
VDD is 5.0V) and -13dB (if VDD is 3.3V).
Figure 2 Recommended External Components (D4)
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FX651
1.5
General Description
1.5.1
Overall Function
The FX651 is a dual channel tone detector for use in the French Payphone system where 12kHz SPM
and 18kHz security tones are used.
SPM (12kHz) Detector
The SPM detector channel responds to a low level (50mV) 12kHz tone in the presence of a large
security tone (16kHz - 20kHz) and speech.
The device responds after a period of continuous valid tone and so recognises a valid SPM toneburst
(minimum transmission duration, 75ms).
This function is permanently enabled.
Security Tone (18kHz) Detector (Rx Mode Only)
This demodulates the 18kHz ASK signal in the presence of the SPM signalling.
Security Tone Transmission (Tx Mode Only)
An 18kHz tone modulated ON - OFF by the NRZ data pin. A logic low gates the signal ON so that
18kHz is transmitted. A logic high gates the signal OFF so that no tone appears at the TXOP pin.
1.5.2
Description of Blocks
(See Figure 1)
Input Amplifier
This amplifier is connected as a differential amplifier and is used to couple the signal into the device. It
also attenuates the combined speech, SPM tone and security tone to prevent its output saturating. Its
signal gain should be -10dB at 5.0V supply and -13dB at 3.3V.
(See Figure 2 for recommended component values)
Sample and Hold (12kHz Channel)
This samples the input signal at 17.898kHz and creates images of the incoming frequencies. The
12kHz SPM is translated to 5.898kHz and the security tone is translated to between 978Hz and
1182Hz. This simplifies the subsequent signal processing.
Filtering and Frequency Detection (12kHz Channel)
The output of the sample and hold circuit is passed to filter HPF1. This is a switched capacitor high
pass filter which amplifies the frequency shifted SPM tone (about 5.9kHz) but rejects the frequency
shifted security tone (about 1kHz). The filter also rejects any speech signals present. The filter output
is passed to the level detect and frequency measurement circuitry which determines the presence or
absence of a valid SPM signal on the line. A valid signal sends the "DETECT 12kHz" pin to logic low.
Sample and Hold (18kHz Channel)
This samples the input signal at 71.592kHz. It is synchronised with the following high pass filter, which
is a switched capacitor circuit with the same sampling rate. The sample and hold circuit stores the
value of the input waveform value between sampling instants so that it is a suitable input for the filter.
Without the sample and hold circuit, speech or SPM tone components which are large compared with
the security tone would interfere with the level discrimination at the filter output.
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FX651
Filtering and Frequency Detection (18kHz Channel)
The output of the sample and hold circuit is passed to filter HPF2. This is a switched capacitor high
pass filter which amplifies the security tone (about 16.92kHz - 19.08kHz) but rejects the SPM tone.
The filter output signal is passed to the level detect and frequency measurement circuitry which
determines the presence or absence of a valid security tone on the line. A valid signal sends the
"DETECT 18kHz" pin to logic low.
Clock Oscillator and Dividers
These circuits generate the internal clocks by division of the oscillator reference frequency. The crystal
is connected as shown in Figure 2 without any need for other external components. When a crystal is
used, the CLKIN pin should be left open circuit.
Alternatively, when a frequency of 3.579545MHz is externally available, the use of a crystal is
unnecessary. The external frequency is applied to the CLKIN pin. In this case, the XTAL pin should be
tied to VDD.
In Tx, the dividers also generate a pulse train, frequency 18kHz, which is passed to the Tx circuitry
(Gate ON - OFF and Band Pass Filter) for digital modulation and filtering.
Gate ON-OFF (Tx Only)
This circuit is a digital block. It performs ON - OFF modulation of the 18kHz pulse train generated from
the crystal frequency by the digital dividers. It is controlled by the NRZ DATA pin and is used to encode
NRZ data packets as pulsed 18kHz (ASK data). The modulated digital signal is passed to the Tx filter
for wave shaping.
Band Pass Filter (Tx Only)
This is a 4th order band pass filter with centre frequency 18kHz. It shapes the modulated digital pulse
train from the previous block into a low distortion pulsed sinusoidal waveform. The resulting signal is
the system acknowledgement security tone. It is transmitted by the subscriber equipment, via the
telephone link, to the local exchange.
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FX651
1.6
Application Notes
1.6.1
Device Sensitivity versus VDD - Input Amplifier Gain
The device sensitivity is proportional to VDD because internal voltage references are derived from the
power supply. This means that the input amplifier signal gain should be adjusted to compensate.
Figure 2 shows components recommended for 5.0V and 3.3V operation.
1.6.2
Alias Responses - False Decodes
The FX651 is designed to work in telephone systems where certain ranges of input frequencies are
expected and other ranges are not. The 12kHz SPM channel works in the presence of speech and a
tone in the range 16kHz - 20kHz. The security tone detector functions in the presence of an interfering
tone in the range 11kHz - 13kHz. A significant tone at other frequencies may interfere with correct
decoding of valid transmissions and should be avoided.
A small range of input frequencies could cause false decoding when no valid tone has been received.
This is because of the frequency shifting property of the SPM channel and the SWC filters (i.e sampled
data filters) in both channels.
The alias frequencies which should be avoided are:
12kHz Channel
Input frequencies in the ranges:
5.708kHz - 6.078kHz
41.504kHz - 41.874kHz
23.606kHz - 23.976kHz
47.986kHz - 47.616kHz
29.718kHz - 30.088kHz
59.402kHz - 59.772kHz
In general, decodes may be caused by tones in the ranges:
(( n × 17.898) ± (5.708 − 6.078))kHz
where n = 0, 1, 2, 3......
Taking n = 1 and the minus sign represents valid SPM inputs in the range 11.82kHz 12.18KHz. The other inputs represent false decodes. The response time and level sensitivity
for a false decode is the same as that for a valid decode, e.g. 42ms - 45ms of 5708Hz at 50mV
could cause a false decode at the "DETECT 12kHz" pin.
18kHz Channel
Input frequencies in the ranges:
52.511kHz - 54.671kHz
88.511kHz - 90.671kHz
In general, decodes could be caused by any tone in the ranges:
(( n × 71.591) ± (16.92 − 19.08))kHz
where n = 0, 1, 2, 3......
The case where n = 0 and the addition sign is used represents valid security tone inputs. The
other cases represent false decodes. The response time and level sensitivity for a false
decode is the same as that for a valid decode, e.g. 5.8ms of 52.511kHz at 40mV could cause a
false response at the "DETECT 18kHz" pin.
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1.7
Performance Specification
1.7.1
Electrical Performance
FX651
Absolute Maximum Ratings
Exceeding these maximum ratings can result in damage to the device.
Min.
-0.3
-0.3
-30
-20
-55
-40
Supply (VDD - VSS)
Voltage on any pin (wrt VSS)
Current into or out of VDD and VSS pins
Current into or out of any other pin
Storage Temperature
Operating Temperature
Total Allowable Power Dissipation at Tamb = 25°C
Derating ...
Max.
7.0
VDD + 0.3
+30
+20
+125
+85
800
13
Units
V
V
mA
mA
°C
°C
mW
mW/°C
Max.
5.5
+85
3.580082
Units
V
°C
MHz
Operating Limits
Correct operation of the device outside these limits is not implied.
Min.
3.0
-40
3.579008
Supply (VDD - VSS)
Operating Temperature
Xtal Frequency
Operating Characteristics
For the following conditions unless otherwise specified:
Xtal Frequency = 3.579545MHz, Noise and Distortion Measured in 50kHz Bandwidth
VDD = 3.3V to 5.5V, Tamb = -40°C to 85°C.
Notes
DC Parameters
VDD
IDD
IDD
Typ.
Max.
Units
2.5
1.0
5.5
4.0
2.0
V
mA
mA
3.3
1
2
Logic "1" Input Level
Logic "0" Input Level
Logic "1" Output Level at IOH = -120µA
Logic "1" Output Level at IOL = 360µA
Notes:
Min.
1, 3
1, 3
1
1
3.5
1.5
4.6
0.4
1.
At VDD = 5.0V only, IDD specification does not include any current drawn from the
device pins by external circuitry.
2.
At VDD = 3.3V only, IDD specification does not include any current drawn from the
device pins by external circuitry.
3.
CLKIN input signal may be sinusoidal.
 1997 Consumer Microcircuits Limited
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V
V
V
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SPM and Security Subsystem
FX651
Operating Characteristics (continued)
Notes
AC Parameters
Tx Output
Tx O/P Impedance (Tx mode)
Tx O/P Impedance (Rx mode)
Output Frequency
Output Distortion
Signal Level
Signal Level
Response/De-response Times
Rise/Fall Times
4
4
5
5, 6
5, 7
8
9
300
17.82
3.0
2.0
Typ.
Max.
Units
1.0
500
2.5
kΩ
kΩ
kHz
%
Vp-p
Vp-p
µs
ms
3.4
2.2
18.18
2
3.7
2.4
100
5
10
Rx Input
Rx I/P Impedance
Rx I/P Amp Voltage Gain
10.0
MΩ
V/V
500
11
12kHz (SPM) Channel Performance
12
12
12
12
With Interfering Speech & Security Tone
12kHz Input Signal Level
12kHz Decode Min Signal Level
12kHz No Decode Max Signal Level
Response Delay
De-response Delay
Detect Bandwidth
Not Detect Frequencies (below 12kHz)
Not Detect Frequencies (above 12kHz)
12, 13
12, 13
12
12
12
800
50
mV
mV
mV
50
50
12.18
11.52
ms
ms
kHz
kHz
kHz
1.2
40
V
mV
mV
8
19.08
16.25
ms
kHz
kHz
kHz
25
40
40
11.82
12.48
14
18kHz (Security Tone) Channel Performance
With Interfering Speech & SPM Tone
18kHz Input Signal Level
18kHz Decode Min Signal Level
18kHz No Decode Max Signal Level
15
15
15
15
Response/De-response Times
Detect Bandwidth
Not Detect Frequencies (below 18kHz)
Not Detect Frequencies (above 18kHz)
15, 16
15
15
15
 1997 Consumer Microcircuits Limited
Min.
11
10
16.92
19.75
D/651/4
SPM and Security Subsystem
Notes:
FX651
4.
Small signal impedance.
5.
At output of smoothing network.
6.
VDD = 5.0V.
7.
VDD = 3.3V.
8.
The time between a logic "1 - 0" transition at NRZ data input and the tone at TXOP
reaching 10% of its full value or between a "0 - 1" transition at NRZ data input and the
tone falling to 90% of its full value.
9.
The time for the 18kHz tone at TXOP to rise from 10% to 90% or to fall from 90% to
10% of its full value.
10.
Input amplifier signal gain set to -10dB for VDD = 5.0V, -13dB for VDD = 3.3V.
11.
Maximum 10% distortion for incoming SPM tone, not including interfering speech or
security tone (16kHz - 20kHz).
Minimum SNR 22dB for incoming SPM tone.
12.
Signal levels at the line side of the input capacitor. 12kHz channel performance
specified in the presence of the following interfering signals:
(a)
A 1.2V tone in the frequency range 16kHz - 20kHz.
(b)
An ordinary speech signal containing frequencies in the range
300Hz - 3400Hz of maximum instantaneous amplitude 8.0Vpk-pk.
13.
The device responds after 40-50ms of continuous valid tone and de-responds after: a
40-50ms period of no-tone, tones less than 25mV or an out of band tone.
14.
Maximum 10% distortion for incoming security tone, not including interfering SPM tone
(11kHz - 13kHz).
Minimum 20dB SNR for incoming security tone.
15.
Signal level specified at the line side, i.e. before the input capacitor. Performance
specified in the presence of an interfering 800mV tone in the frequency range 11kHz 13kHz.
16.
The device responds after 8ms of continuous valid tone and de-responds after: a 8ms
period of no-tone, tone of 10mV or less, or an out of band tone.
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FX651
System Timings (See also Table 1 on next page)
(a) SPM (12kHz) channel. Toneburst and tonegaps less than the response and de-response
are ignored.
delays
(b) Security tone (18kHz) channel. The response and de-response times are short to enable the
device to recognise the short ON-OFF bursts (20ms each).
(c) Transmit Mode. TXOP is modulated by the NRZ DATA pin. An 18kHz toneburst represents logic
"0" and "no tone" represents logic "1". Data packets with symbol periods greater than or equal to
6ms can be transmitted.
Figure 3 System Timing Diagrams
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Rx
FX651
Min
Max
Unit
40
40
50
50
ms
ms
12KHz
Response Delay
De-response Delay
18KHz
Response Time
De-response Time
8
8
ms
ms
Transmit "0" Time
Transmit "1" Time
5.1
5.1
ms
ms
Tx *
Table 1 System Timings
* Note: Tx Transmit Times include both Response/De-response Times and Rise/Fall
Times.
1.7.2
Packaging
The FX651 is available in the 16-pin SOIC package detailed below:
D IM .
A
B
C
E
F
H
J
K
K1
L
P
T
W
X
Y
M IN .
T Y P.
M AX.
0 .3 95 (1 0 .0 3)
0 .41 3 (1 0 .49 )
0 .2 99 (7 .5 9)
0 .29 1 (7 .3 9)
0 .0 93 (2 .3 6 )
0.1 0 5 (2 .67 )
0.39 4 (1 0.0 1 )
0.41 9 (1 0.64 )
0 .3 66 (9 .2 9 )
0 .00 4 (0 .1 0)
0 .0 1 2 (0.3 0 )
0 .0 19 (0 .4 8 )
0 .01 3 (0 .3 3)
0.04 1 (1 .04 )
0 .0 41 (1 .0 4 )
0.05 0 (1 .2 7)
0.0 1 6 (0 .41 )
0.0 5 0 (1 .27 )
0.01 2 (0 .3 0)
0 .0 0 9 (0.2 3 )
45°
0°
8°
7°
N O T E : A ll d im e nsio n s in in ch e s (m m .)
A n g les in d e gre es
Figure 4 SOIC Mechanical Outline: Order as part no. FX651D4
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FX651
Handling precautions: This product includes input protection, however, precautions should be taken to
prevent device damage from electro-static discharge. CML does not assume any responsibility for the
use of any circuitry described. No IPR or circuit patent licences are implied. CML reserves the right at
any time without notice to change the said circuitry and this product specification. CML has a policy of
testing every product shipped using calibrated test equipment to ensure compliance with this product
specification. Specific testing of all circuit parameters is not necessarily performed.
CONSUMER MICROCIRCUITS LIMITED
1 WHEATON ROAD
WITHAM - ESSEX
CM8 3TD - ENGLAND
Telephone:
Telefax:
e-mail:
+44 1376 513833
+44 1376 518247
[email protected]
http://www.cmlmicro.co.uk
CML Microcircuits
COMMUNICATION SEMICONDUCTORS
CML Product Data
In the process of creating a more global image, the three standard product semiconductor
companies of CML Microsystems Plc (Consumer Microcircuits Limited (UK), MX-COM, Inc
(USA) and CML Microcircuits (Singapore) Pte Ltd) have undergone name changes and, whilst
maintaining their separate new names (CML Microcircuits (UK) Ltd, CML Microcircuits (USA)
Inc and CML Microcircuits (Singapore) Pte Ltd), now operate under the single title CML Microcircuits.
These companies are all 100% owned operating companies of the CML Microsystems Plc
Group and these changes are purely changes of name and do not change any underlying legal
entities and hence will have no effect on any agreements or contacts currently in force.
CML Microcircuits Product Prefix Codes
Until the latter part of 1996, the differentiator between products manufactured and sold from
MXCOM, Inc. and Consumer Microcircuits Limited were denoted by the prefixes MX and FX
respectively. These products use the same silicon etc. and today still carry the same prefixes.
In the latter part of 1996, both companies adopted the common prefix: CMX.
This notification is relevant product information to which it is attached.
Company contact information is as below:
CML Microcircuits
(UK)Ltd
CML Microcircuits
(USA) Inc.
CML Microcircuits
(Singapore)PteLtd
COMMUNICATION SEMICONDUCTORS
COMMUNICATION SEMICONDUCTORS
COMMUNICATION SEMICONDUCTORS
Oval Park, Langford, Maldon,
Essex, CM9 6WG, England
Tel: +44 (0)1621 875500
Fax: +44 (0)1621 875600
[email protected]
www.cmlmicro.com
4800 Bethania Station Road,
Winston-Salem, NC 27105, USA
Tel: +1 336 744 5050,
0800 638 5577
Fax: +1 336 744 5054
[email protected]
www.cmlmicro.com
No 2 Kallang Pudding Road, 09-05/
06 Mactech Industrial Building,
Singapore 349307
Tel: +65 7450426
Fax: +65 7452917
[email protected]
www.cmlmicro.com
D/CML (D)/1 February 2002