TI TRF1500

TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
D
D
D
D
D
Low-Noise Amplifier for Each Band
RF Mixer for Each Band With Image
Rejection Configuration for High Band
IF Amplifier for Both Low and High Bands
Operates From a Supply Voltage Range of
3.6 V to 4 V
Suitable for Portable Dual-Band/Dual-Mode
Cellular Telephones (IS136)
48-Pin Plastic Thin Quad Flatpack Package
(TQFP)
D
description
The TRF1500 is a dual-band/dual-mode personal communications system (PCS) receiver for cellular
telephones operating dual mode (analog and digital) in the 800-MHz band and single mode (digital) in the
1900-MHz band. The TRF1500 consists of a low-noise amplifier (LNA) and mixer for each band. The high band
uses an image rejection mixer for down conversion while the low band relies on an off-chip image rejection filter
between the LNA and mixer.
The local oscillator (LO) inputs additionally have buffered outputs that can be used in either single-ended or
differential mode for a phase-locked-loop (PLL) configuration. A state is also available that allows the low-band
LO to serve as the high-band LO through a mode-selectable frequency doubler.
A wideband mixer is also available for transmit loop architectures commonly used in advanced mobile phone
systems, global systems for mobile communications, and digital cellular systems.
Power consumption is low and can be further reduced by operating the TRF1500 in sleep mode. Typical power
consumption for each receiver function is shown in Table 1.
The TRF1500 is available in a 48-pin plastic thin-quad flatpack package (TQFP) and is characterized for
operation from –30 _C to 85 _C operating free-air temperature.
Table 1. Typical Power Consumption at VCC = 3.75 V
FUNCTION
TYPICAL POWER
UNIT
38
µW
Low band
85
mW
High band
190
mW
Transmit mixer
50
mW
Frequency doubler
12
mW
Sleep mode
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
Copyright  1997, Texas Instruments Incorporated
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of Texas Instruments
standard warranty. Production processing does not necessarily include
testing of all parameters.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
HIGH_BAND_LNA_IN
GND
VCC
GND
STRONG_SIGNAL
IR_ADJUST_B
IR_ADJUST_C
GND
GND
LOW_BAND_LNA_OUT
GND
LOW_BAND_LNA_IN
PFB PACKAGE
(TOP VIEW)
48 47 46 45 44 43 42 41 40 39 38 37
BIAS_ADJUST
TX_IF +
TX_IF –
GND
MIX_IN_LOW_BAND
GND
VCC
GND
TX +
TX –
GND
IR_ADJUST_D
1
36
2
35
3
34
4
33
5
32
6
31
7
30
8
29
9
28
10
27
11
26
12
25
HI/LO
SYN_ON
HIGH_BAND_IF+
HIGH_BAND_IF–
LOW_BAND_IF+
LOW_BAND_IF–
GND
HIGH_BAND_LO+
HIGH_BAND_LO–
LOW_BAND_LO+
LOW_BAND_LO–
RX_ON
13 14 15 16 17 18 19 20 21 22 23 24
2
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• DALLAS, TEXAS 75265
IR_ADJUST_A
X2_ON
GND
GND
LOW_BAND_LO_IN
VCC
DOUBLER_TANK
GND
HIGH_BAND_LO_IN +
HIGH_BAND_LO_IN –/RF_GND
TX_ON
VCC
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
functional block diagram
Low-Band LNA
LOW BAND LNA IN
LOW BAND IF +
LOW BAND IF –
45
43
17
5
18
LOW BAND LO –
32
Low-Band LO
Buffer Amplifier
22
HIGH BAND LO IN –
/RF GND
HIGH BAND LO IN +
LOW BAND LO IN
23
High-Band IF
High-Band
Image Reject Mixer Buffer Amplifier
HIGH BAND LNA IN
MIX IN LOW BAND
Low-Band LO
Buffer Amplifier
Low-Band IF
Buffer Amplifier
LOW BAND LO +
LOW BAND LNA OUT
Low-Band
Mixer
42
LNA
15
16
High-Band LO
Buffer Amplifier
27
28
20
21
Buffer
Amplifier
Transmit
Mixer
HIGH BAND IF +
HIGH BAND IF –
HIGH BAND LO +
HIGH BAND LO –
Buffer
Amplifier
2
3
9
TX IF +
TX IF –
Buffer
Amplifier
TX +
TX –
DOUBLER
TANK
10
Doubler
30
Buffer
Amplifier
×2
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3
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
Terminal Functions
TERMINAL
NAME
NO.
I/O
DESCRIPTION
DOUBLER_TANK
30{
O
Doubler output
HIGH_BAND_IF +
15{
O
High-band IF noninverting output
HIGH_BAND_IF –
16{
O
High-band IF inverting output
HIGH_BAND_LNA_IN
42{
I
High-band LNA input
HIGH_BAND_LO +
20{
O
Buffered high-band LO noninverting output
HIGH_BAND_LO –
21{
O
Buffered high-band LO inverting output
HIGH_BAND_LO_IN –
/RF_GND
27{
I
High-band LO inverting input/RF GND
HIGH_BAND_LO_IN +
28{
I
High-band LO noninverting input
HI/LO
13
I
High-band/low-band select; 1 = high band, 0 = low band
IR_ADJUST_A
36
I
Image rejection adjustment
IR_ADJUST_B
37
I
Image rejection adjustment
IR_ADJUST_C
48
I
Image rejection adjustment
12
I
Image rejection adjustment
IR_ADJUST_D
GND
4, 6, 8, 11, 19, 29, 33, 34,
39, 41, 44, 46, 47
Ground
LOW_BAND_IF +
17{
O
Low-band IF noninverting output
LOW_BAND_IF –
18{
O
Low-band IF inverting output
LOW_BAND_LNA_IN
43{
I
Low-band LNA input
LOW_BAND_LNA_OUT
45{
O
Low-band LNA output
LOW_BAND_LO –
23{
O
Buffered low-band LO inverting output
LOW_BAND_LO_IN
32{
I
Low-band LO input
MIX_IN_LOW_BAND
5{
I
Low-band mixer input
BIAS_ADJUST
1
I
Bias adjustment
RX_ON
24
I
Receiver LNA/mixer power control
STRONG_SIGNAL
38
I
Strong signal indication
SYN_ON
14
I
VCO power control
TX +
9{
I
Transmit, noninverting input
TX –
10{
I
Transmit, inverting input
TX_IF +
2{
O
Transmit IF, noninverting output
TX_IF –
3{
O
Transmit IF, inverting output
TX_ON
26
I
Transmit mixer/driver power control
VCC
X2_ON
7, 25, 31, 40
I
35
I
VCC
Doubler power control
† Pins without internal ESD protection
4
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
absolute maximum ratings over operating free-air temperature range (unless otherwise noted)†
Supply voltage range, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 6 V
Power dissipation, TA = 25°C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 350 mW
Maximum operating junction temperature, TJmax . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150°C
Operating free-air temperature range, TA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 85°C
Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 65°C to 150°C
† Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not
implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
recommended operating conditions
Supply voltage, VCC
High-level input voltage, VIH
MIN
NOM
MAX
3.6
3.75
4
V
V
3
UNIT
Low-level input voltage, VIL
– 0.3
VCC
0.5
Operating free-air temperature, TA
– 30
85
_C
Operating junction temperature, TJ
– 30
105
_C
V
control state
CONTROL STATE (HI/L0, SYN ON, RX ON, TX ON, STRONG SIGNAL, X2)
ACTIVE CIRCUITS
000000
Sleep mode
010000
Low-band LO input buffer on
LB LO buffer
011000
Low-band receive normal
LB LO buffer, LB LNA, LB mixer
011010
Low-band receive strong signal
LB LO buffer,LB mixer
010100
Low-band transmit mixer
LB LO buffer, LB TX mixer
011100
Low-band receive and transmit mixer
LB LO buffer, LB LNA (on high), LB mixer, LB TX mixer
011110
Low-band transmit
LB LO buffer, LB LNA (on high), LB mixer
010001
Double on
LB LO buffer, doubler, HB LO buffer
011001
LB Receive normal, doubler on
LB LO buffer, LB LNA, LB mixer, doubler
011011
LB receive strong signal, doubler on
LB LO buffer, LB mixer, doubler
011111
LB transmit, doubler on
LB LO buffer, LB LNA (on high), LB mixer, LB TX mixer
111011
High–band receive strong signal
HB LO buffer, HB mixer, doubler
110000
High-band LO input buffer on
HB LO buffer
111000
High-band receive normal
HB LO buffer, HB LNA, HB mixer
111010
High-band receive strong signal
HB LO buffer, HB mixer
111001
High-band receive frequency doubler on
LB LO buffer, HB LNA, HB mixer, frequency doubler, HB
LO buffer
110100
High-band transmit normal
HB LO buffer, HB TX mixer
110101
High-band transmit frequency doubler on
LB LO buffer, HB TX mixer, frequency doubler, HB LO
buffer
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
5
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
current consumption, VCC = 3.75 V, TA = 25°C
CONTROL STATE (HI/L0, SYN ON, RX ON, TX ON, STRONG SIGNAL, X2)
MIN
TYP
MAX
UNIT
000000
Sleep mode
20
100
µA
010000
Low-band LO input buffer on
3.3
4
mA
011000
Low-band receive normal
24
28
mA
110000
High-band LO input buffer on
4
5
mA
111000
High-band receive normal
56
62
mA
111001
High–band receive with doubler on
61
68
mA
010100
Low-band transmit mixer
13
16
mA
110100
High-band transmit mixer
17
21
mA
110101
High-band transmit mixer, doubler on
22
27
mA
TYP
MAX
UNIT
869
894
MHz
979.52
1004.52
MHz
electrical characteristics at 881.5 MHz (unless otherwise noted)
low-band LNA, mixer, saw filter, and IF buffer amplifier, VCC = 3.75 V†, TA = 25°C
PARAMETER
TEST CONDITIONS
RF input frequency range
LO frequency range
MIN
IF frequency
LO input power
Turn on/off time
24
Strong signal condition: LNA off
Noise figure
RF input return loss
MHz
–5
dBm
µs
65
Power conversion gain
Power conversion gain reduction
110.52
26
19
2.5
Z= 50 Ω
5.6
LO input return loss
LO buffer output power
Power leakage LO in to RF in
28
dB
dB
3.0
dB
dB
16.5
dB
–10.3
dBm
–53
dBm
IIP3 (third-order intermodulation product)
Referenced RF input port
–9.7
dBm
1-dB RF input compression point
Referenced RF input port
– 21
dBm
1-dB blocking point
Blocking signal 45 MHz below f0
–18
dBm
† Low-band LNA, mixer, and IF amplifier with an external surface-acoustic wave (SAW) filter having 3-dB insertion loss (IL). All specifications apply
for an IF output terminated into a 1-kΩ load. Parametric limits apply only when tested using the evaluation board or the recommended application
circuit.
6
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• DALLAS, TEXAS 75265
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
electrical characteristics at 1960 MHz (unless otherwise noted)
high-band LNA, mixer, and IF buffer amplifier, doubler, VCC = 3.75 V†, TA = 25°C
PARAMETER
MIN
TEST CONDITIONS
RF input frequency range
TYP
MAX
UNIT
1990
MHz
1050.26
MHz
1930
LO frequency range (at doubler input)
1020.26
IF frequency
110.52
LO input power
MHz
–5
Power conversion gain
24
Power conversion gain reduction
Strong signal condition: LNA off
Image Rejection
dBm
26.3
29
43.5
20
Noise figure
dB
22.5
dB
4.66
Noise figure
Control state 111000,
LOFR=2070.52
4.35
RF input return loss
50 Ω
dB
5.1
dB
dB
14.2
dB
LO buffer output power
–14
dBm
Power leakage LO in to RF in
–50
dBm
IIP3 (third-order intermodulation product)
Referenced RF input port
1-dB RF input compression point
Referenced RF input port
2 x 2 spur performance
3 x 3 spur performance
–19
–17.7
dBm
– 23.7
dBm
–50 dBm referenced RF input
port,
LO=1020.13 MHz and RF=1985
69
dBc
–50 dBm referenced RF input
port,
LO=1019.92 MHz and RF=2003
81
dBc
† High-band LNA, mixer, and IF amplifier specifications apply for an IF output terminated into a 1-kΩ load. Parametric limits apply only when tested
using the evaluation board or recommended application circuit using the internal frequency doubler.
electrical characteristics at 836.5 MHz (unless otherwise noted)
low-band transmit mixer, VCC = 3.75 V}, TA = 25°C
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TX mixer input frequency
824
849
MHz
LO frequency
941
966
MHz
TX mixer output frequency
LO input power
Conversion power gain
17
117
MHz
–5
dBm
19
dB
dB
Noise figure
Double sideband
7.8
TX input return loss
Balanced 200 Ω
9.8
dB
–49
dBm
Power leakage LO in to TX in
Power leakage TX in to LO in
TX In = –30 dBm
–70.6
dBm
1-db input compression point
Referred to TX input
–20
dBm
Second-order input intercept point (IIP2)
Referred to TX input
29.5
dBm
Third-order input intercept point (IIP3)
Referred to TX input
‡ Transmit mixer specifications apply for an IF output terminated into a 1-kΩ resistor load.
–11.5
dBm
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
7
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
electrical characteristics at 1910 MHz (unless otherwise noted)
high-band transmit mixer, doubler, VCC = 3.75 V† , TA = 25°C
MAX
UNIT
TX mixer input frequency
PARAMETER
TEST CONDITIONS
1850
MIN
1910
MHz
LO frequency
983.8
1013.5
MHz
TX mixer output frequency
LO input power
Conversion power gain
6
TYP
117
MHz
–5
dBm
9.9
dB
Noise figure
Double sideband
12.7
dB
TX input return loss
Balanced 200 Ω
16.6
dB
Power leakage LO in to TX in
–55.5
dBm
Power leakage TX in to LO in
TX In = –30 dBm
–69.5
dBm
1-db input compression point
Referred to TX input
–15.7
dBm
Second-order input intercept point (IIP2)
Referred to TX input
27
dBm
Third-order input intercept point (IIP3)
Referred to TX input
–6.7
dBm
† High-band transmit mixer specifications apply for an IF output terminated into a 1-kΩ resistor load using the internal frequency doubler.
8
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
J15
VCC
C54
Optional
C12
J50
SYN_ON
HI_LO
VCC
STR_SIG
TX_ON
VCC
C31
C30
VCC
X2_ON
VCC
C33
RX_ON
L11
C36
VCC
S51
VCC
C35
T30
F10
T31
VCC
S50
J30
L50
C50
L31
C13
HI_LO
12
11
10
9
8
7
6
5
4
3
2
1
J21
C23
SYN_ON
C32
VCC
C2
L30
T20
R6
R7
VCC
C20
L20
TRF1500
T10
C55
L51
C51
C15
L12
L13
C1
GND
GND
X2_ON
J11
C14
J23
C16
VCC
VCC
TX_ON
HIGH_BAND_LO_IN–
/RF_GND
HIGH_BAND_LO_IN+
GND
DOUBLER_TANK
VCC
T22
Zo = 35
E = 90 @
2.07 GHz
C28
C3
C41
J13
Zo = 35
E = 90 @
2.07 GHz
C27
VCC
TX_ON
C40
L14
J12
C4
X2_ON
STR_SIG
C17
RX_ON
25
26
27
28
29
30
31
32
33
34
35
36
VCC
IR_AD–
JUST_A
LOW_BAND_LO_IN
37
LOW_BAND_IF+
44
Figure 1. Recommended Application Circuits
L52
C52
C21
L22
L21
C22
IR_ADJUST_D
GND
TX–
TX+
GND
VCC
GND
MIX_IN_LOW_BAND
GND
TX_IF–
TX_IF+
BIAS_
ADJUST
48
13
J31
IR_ADJUST_C
HI_LO
C34
GND
SYN_ON
VCC
16
Optional
C53
GND
17
45
LOW_BAND_LNA_OUT
HIGH_BAND_IF–
C10
HIGH_BAND_LO+
C29
HIGH_BAND_LO–
L10
22
C11
46
15
LOW_BAND_LNA_IN
LOW_BAND_IF–
GND
HIGH_BAND_IF+
43
18
GND
LOW_BAND_LO+
HIGH_BAND_LNA_IN
GND
38
23
42
19
STRONG_SIGNAL
LOW_BAND_LO–
J20
20
IR_ADJUST_B
RX_ON
47
14
41
GND
40
V
CC
39
21
POST OFFICE BOX 655303 • DALLAS, TEXAS 75265
24
J10
T11
Zo = 35
E = 90 @
992 MHz
C19
C26
C24
L40
Zo = 35
E = 90 @
992 MHz
C18
J22
VCC
TRF1500
DUAL-BAND/DUAL MODE PCS RECEIVER
SLWS041A – JANUARY 1998
APPLICATION INFORMATION
9
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
APPLICATION INFORMATION
Table 2. TRF1500 External Component List
DESIGNATOR
DESCRIPTION (SIZE)
VALUE
MANUFACTURER
PART #
C1
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C2
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C3
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C4
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C10
Capacitor (0402)
15000 pF
Murata
GRM36Y5V153Z 16
C11
Capacitor (0402)
1 pF
Murata
GRM36COG010C 50s
C12{
Capacitor (0402)
10 pF
Murata
GRM36COG100D 50S
C13
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50S
C16
Capacitor (0402)
1000 pF
Murata
GRM36COG102K 50
C17
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50S
C18
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50S
C19
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50S
C20
Capacitor (0402)
1.5 pF
Murata
GRM36COG1R5C 50
C23
Capacitor (0402)
1000 pF
Murata
GRM36COG102K 50
C26
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C27
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C28
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C29
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C30
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C31
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C34
Capacitor (0402)
47 pF
Murata
GRM36COG470J 50
C40}
Capacitor (0402)
0.5 pF
Murata
GRM36COG0R5C 50S
C41}
Capacitor (0402)
0.5 pF
Murata
GRM36COG0R5C 50S
C55
Capacitor (0402)
1.5 pF
Murata
GRM36COG1R5C 50S
L10
Inductor (0603)
12 nH
Coilcraft
0603HS-12NTJBC
L11
Inductor (0805)
10 nH
Coilcraft
0603HS-10NTJBC
L12
Inductor (0805)
150 nH
Coilcraft
0805HS-150TKBC
L13
Inductor (0805)
150 nH
Coilcraft
0805HS-150TKBC
L14
Inductor (0402)
3.9 nH
Coilcraft
0603HS–3N9TKBC
L20
Inductor (0603)
1.8 nH
Coilcraft
0603HS-1N8TKBC
L21
Inductor (0805)
150 nH
Coilcraft
0805HS-151TKBC
L22
Inductor (0805)
150 nH
Coilcraft
0805HS-151TKBC
L30
Inductor (0805)
120 nH
Coilcraft
0805HS-121TKBC
L31
Inductor (0805)
120 nH
Coilcraft
0805HS-121TKBC
L40}
Inductor (0603)
1.2 nH
TOKO
LL100S-F12NK
R6
Resistor (0402)
1.5 M
R7
Resistor (0402)
560K
F10
Saw filter
MA/COM
SAFC881.5MA70N–TC
† Remove C12 to test the low-band LNA or mixer.
‡ Remove C40, L40, and change C41 to 1 pF to test the high-band receive normal mode (doubler turned off).
10
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• DALLAS, TEXAS 75265
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
APPLICATION INFORMATION
Table 3. TRF1500 External Component List For Evaluation Board Test Purposes Only
DESIGNATOR
DESCRIPTION (SIZE)
VALUE
MANUFACTURER
PART #
C14
Capacitor (0402)
10 pF
Murata
GRM36COG100D 50S
C15
Capacitor (0402)
9 pF
Murata
GRM36COG090D 50S
C21
Capacitor (0402)
9 pF
Murata
GRM36COG090D 50S
C22
C24†
Capacitor (0402)
8 pF
Murata
GRM36COG080D 50S
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C32
Capacitor (0402)
12 pF
Murata
GRM36COG120D 50S
C33
Capacitor (0402)
12 pF
Murata
GRM36COG120D 50S
C35
Capacitor (0402)
0.5 pF
Murata
GRM36COG0R5C 50S
C36
Capacitor (0402)
0.5 pF
Murata
GRM36COG0R5C 50S
C50
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C51
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C52
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
C53}
C54§
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
Capacitor (0402)
100 pF
Murata
GRM36COG101J 50
L50
Inductor (0603)
68 nH
Coilcraft
0603HS-68NTJBC
L51
Inductor (0603)
47 nH
Coilcraft
0603HS-47NTJBC
L52
Inductor (0603)
68 nH
Coilcraft
0603HS-68NTJBC
S50
Triple SPDT switch
Grayhill
76SC03
S51
Triple SPDT switch
Grayhill
76SC03
J10
SMA board connector
EF Johnson
142-0701-801
J11
SMA board connector
EF Johnson
142-0701-801
J12
SMA board connector
EF Johnson
142-0701-801
J13
SMA board connector
EF Johnson
142-0701-801
J20
SMA board connector
EF Johnson
142-0701-801
J21
SMA board connector
EF Johnson
142-0701-801
J22
SMA board connector
EF Johnson
142-0701-801
J23
SMA board connector
EF Johnson
142-0701-801
J30
SMA board connector
EF Johnson
142-0701-801
J31
SMA board connector
EF Johnson
142-0701-801
J50
SMB board connector
Amphenol
903-373J-51A
T10
RF 16:1 transformer
MA/COM
ET16-1
T11
RF 1:1 transformer
MA/COM
ETC1-1-13
T20
RF 16:1 transformer
MA/COM
ET16-1
T22
RF 1:1 transformer
MA/COM
ETC1-1-13
T30
RF 4:1 transformer
MA/COM
ETC1.6-4-2-3
T31
RF 16:1 transformer
MA/COM
ET16–1
† Populate C24 to test the high-band receive normal mode.
‡ Populate C53 to test the low-band LNA.
§ Populate C54 to test the low-band mixer.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
11
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
TYPICAL CHARACTERISTICS
LOW BAND RECEIVER
LOW BAND RECEIVER
CASCADED POWER CONVERSION GAIN
vs
FREQUENCY
CASCADED NOISE FIGURE
vs
FREQUENCY
4
VCC = 3.75 V
RFin = –30 dBm @ 881.5 MHz
IF = 110.52 MHz
State = 011000
28
–30°C
27
25°C
26
85°C
25
24
869
881.5
VCC = 3.75 V
RFin = –30 dBm @ 881.5 MHz
IF = 110.52 MHz
State = 011000
3.5
85°C
3
25°C
2.5
–30°C
2
1.5
869
894
f – Frequency (MHz)
881.5
f – Frequency (MHz)
Figure 2
Figure 3
894
LOW BAND RECEIVER
HIGH BAND RECEIVER
CASCADED THIRD ORDER INPUT INTERCEPT POINT
vs
FREQUENCY
CASCADED POWER CONVERSION GAIN
vs
FREQUENCY
–7
29
VCC = 3.75 V
RFin = –30 dBm @ 881.5 MHz
IF = 110.52 MHz
State = 011000
–8
85°C
G – Cascaded Power Conversion Gain – dB
IIP3 – Cascaded Third Order Input Intercept Point – dBm
12
NF – Cascaded Noise Figure – dB
G – Cascaded Power Conversion Gain – dB
29
–9
–10
25°C
–11
–30 dC
–12
–13
–14
869
881.5
894
28
27
VCC = 3.75 V
RFin = –30 dBm @ 1960 MHz
IF = 110.52 MHz
State = 111001
–30°C
25°C
26
85°C
25
24
1930
1960
f – Frequency (MHz)
f – Frequency (MHz)
Figure 4
Figure 5
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1990
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
TYPICAL CHARACTERISTICS
HIGH BAND RECEIVER
CASCADED THIRD ORDER INPUT INTERCEPT POINT
vs
FREQUENCY
NF – Cascaded Noise Figure – dB
7
6
VCC = 3.75 V
RFin = –30 dBm @ 1960 MHz
IF = 110.52 MHz
State = 111001
85°C
25°C
5
–30°C
4
3
2
1930
1960
1990
IIP3 – Cascaded Third Order Input Intercept Point – dBm
HIGH BAND RECEIVER
CASCADED NOISE FIGURE
vs
FREQUENCY
–15
VCC = 3.75 V
RFin = –30 dBm @ 1960 MHz
IF = 110.52 MHz
State = 111001
–16
85°C
–17
25°C
–18
–30°C
–19
–20
1930
1960
Figure 7
Figure 6
HIGH BAND RECEIVER
LOW BAND TRANSMITTER
IMAGE REJECTION
vs
FREQUENCY
CASCADED POWER CONVERSION GAIN
vs
FREQUENCY
26
22
VCC = 3.75 V
RFin = –30 dBm @ 1960 MHz
IF = 110.52 MHz
State = 111001
G – Cascaded Power Conversion Gain – dB
IR – Image Rejection – dB
25
24
85°C
23
25°C
–30°C
22
21
1930
1990
f – Frequency (MHz)
f – Frequency (MHz)
1960
1990
21
–30°C
20
VCC = 3.75 V
RFin = –30 dBm @ 836.5 MHz
IF = 117 MHz
State = 010100
25°C
19
85°C
18
17
16
824
f – Frequency (MHz)
836.5
849
f – Frequency (MHz)
Figure 8
Figure 9
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
13
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
TYPICAL CHARACTERISTICS
LOW BAND TRANSMITTER
CASCADED THIRD ORDER INPUT INTERCEPT POINT
vs
FREQUENCY
NF – Cascaded Noise Figure – dB
11
10
VCC = 3.75 V
RFin = –30 dBm @ 836.5 MHz
IF = 117 MHz
State = 010100
9
85°C
8
25°C
–30°C
7
6
824
836.5
849
IIP3 – Cascaded Third Order Input Intercept Point – dBm
LOW BAND TRANSMITTER
CASCADED NOISE FIGURE
vs
FREQUENCY
–8
VCC = 3.75 V
RFin = –30 dBm @ 836.5 MHz
IF = 117 MHz
State = 010100
–9
85°C
–10
25°C
–11
–30°C
–12
–13
–14
824
f – Frequency (MHz)
Figure 11
HIGH BAND TRANSMITTER
HIGH BAND TRANSMITTER
CASCADED POWER CONVERSION GAIN
vs
TEMPERATURE
16
VCC = 3.75 V
RFin = –30 dBm @ 1910 MHz
IF = 117 MHz
State = 110101
11
10
9
8
7
6
5
–30
14
CASCADED NOISE FIGURE
vs
TEMPERATURE
NF – Cascaded Noise Figure – dB
G – Cascaded Power Conversion Gain – dB
12
849
f – Frequency (MHz)
Figure 10
13
836.5
25
85
15
VCC = 3.75 V
RFin = –30 dBm @ 1910 MHz
IF = 117 MHz
State = 110101
14
13
12
11
10
–30
25
TA – Temperature – °C
TA – Temperature – °C
Figure 12
Figure 13
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
85
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
TYPICAL CHARACTERISTICS
IIP3 – Cascaded Third Order Input Intercept Point – dBm
HIGH BAND TRANSMITTER
CASCADED THIRD ORDER INPUT INTERCEPT POINT
vs
TEMPERATURE
–4
–5
VCC = 3.75 V
RFin = –30 dBm @ 1910 MHz
IF = 117 MHz
State = 110101
–6
–7
–8
–9
–10
–40
25
85
TA – Temperature – °C
Figure 14
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
15
TRF1500
DUAL-BAND/DUAL-MODE PCS RECEIVER
SLWS041A – JANUARY 1998
MECHANICAL DATA
PFB (S-PQFP-G48)
PLASTIC QUAD FLATPACK
0,27
0,17
0,50
36
0,08 M
25
37
24
48
13
0,13 NOM
1
12
5,50 TYP
7,20
SQ
6,80
9,20
SQ
8,80
Gage Plane
0,25
0,05 MIN
0°– 7°
1,05
0,95
Seating Plane
0,75
0,45
0,08
1,20 MAX
4073176 / B 10/96
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
C. Falls within JEDEC MS–026
16
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
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