SL1024A150RF Datasheet| | PowerStore Power Up RECALL/ | Symbol | | | | | | No | Hardware Controlled STORE | Alt. | IEC | Conditions | Min | Max | Unit | | 24 | Power Up RECALL Duration' e | tRESTORE | | | | 650 | US | | 25 | STORE Cycle Duration | tHLQX | td(H)S | Vcc2.7 V | | 1 0 | ms | | 26 | HSB Low to Inhibit One | tHLQZ | tdis(H)S | | 500 | | ns | | 27 | HSB High to Inhibit Offe | tHHQX | ten(H)S | | | 700 | ns | | 28 | External STORE Pulse Widthe | tHLHX | tw(H)S | | 20 | | ns | | | HSB Output Low Currente, | IHSBOL | | HSB=VOL | 1.8 | | mA | | | HSB Output High Currente, | IHSBOH | | HSB=Vii | 5 | 60 | pA | | | Low Voltage Trigger Level | VSWITCH | | | 2.4 | 217 | V | | | | | | | | |
SL1024A150RF Price .. Reception and transmission of standard and extended frame format messages .. Receive FIFO (64-byte) .. Single/dual acceptance filter with mask and code register for standard and extended frame .. Error counters with read/write access .. Programmable error warning limit .. Last error code register .. Error interrupt for each CAN-bus error .. Arbitration lost interrupt with detailed bit position .. Single-shot transmission (no re-transmission on error or arbitration lost) .. Listen only mode (monitoring of the CAN-bus, no acknowledge, no error flags) .. Hot plugging supported (disturbance-free software driven bit rate detection) .. Disable CLKOUT by hardware. SL1024A150RF on stock| Characteristics | Symbol | Test Condition | Min | Typ. | Max | Unit | | Recovered Audio Output Voltage | AF | Vrf-30dBm | 120 | 200 | 320 | mVms | | Recovered Audio Drop Voltage Loss | AFioss | Vr,- - 30dBm Vff - 4.0 2.OV | - 8.0 | -15 | | _B | | Meter Drive | MV | Vrf= - 100dBm | | 0 3 | 0 5 | V | | OutDut Voltage | MV-, | Vf- - 70dBm | 1 1 | 1 5 | 1 9 | | ( No Modulacion) | MV | Vf- -40dBm | 2 0 | 2 5 | 3 1 | | Fllter Amp Gain | A, (Amp) | R,=600Q. fs=lOKHz. Vfa = 1.OrTiVrrris | 47 | 50 | | cB | | Mixer Conversion Gain | A,(Mix) | Vrr= -40dBm. R, =1.8KQ | 14 | 20 | | cB | | Signal to Noise Ratio | S/N | Vrf- - 30dBm | 36 | 67 | | eB | | Total harmonic Distortion | THD | Vrf- - 30dBm BW-400Hz30KHz | | 0 6 | 3 4 | % | | Detector Output Impedance | z | | | 450 | | Q | | Detector Output Voltage | DV | Vrf= -30dBm No Modulation | | 1 45 | | V | | Meter Driver | M | Vrf- - 100 -40dBm | | 08 | | pA/dB | | Meter Driver | RFi\, | | | 60 | | | | Dynamic Range | IFIN | | | 80 | | dB | | Mixer Third Order Input Intercept Point | IT O,ix | f, -58.125MHz fz=58.1375MHz | | - 22 | | dBm | | Mixer Input Resistance | R | | | 3 3 | | kQ | | Mixer Input Capaatance | C | | | 2 2 | | OF | | | | | | | |
How to calculating the max output current The internal power dissipation(PD)follows the equation: PD = lo x Vo x (1 -Tl) lo = PD /Vo x (1-Tl) Where PD = Internal power dissipation lo = Output current Vo = Output voltage 11 = Efficiency Example: R-745.OP , at Vin = 28Vdc J Vo = 5Vdc ,rl=91 % (see table l) (a) When Ta = 600C , Po = 1.4 Watt (see fig-l) lo = 1.4(W) / 5(V) x (1 -0.91) = 3.11 (A) (b) When Ta = 85aC , PD = 1 Watt (see fig-l) lo = 1 (W) / 5(V) x (1 -0.91) = 2.222(A) (c) At Vin = 12Vdc efficiency = 94% (see table l) When Ta = 850C , PD = 1 Watt (see fig-l) lo = 1 (W) / 5(V) x (1 -0.94) =3.33(A)
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