Appendix B: Additional Regression Results | RDP 2024-01: Do Monetary Policy and Economic Conditions Impact Innovation? Evidence from Australian Administrative Data

Table B1: Effect of 100 Basis Point Contractionary Shock on Share of Firms Innovating
By firm size, cash rate change
	Year 0	Year 1	Year 2	Year 3
All firms
Effect	−1.25* (0.65)	0.03 (0.92)	0.38 (0.64)	1.25 (1.20)
R²	0.20	0.14	0.11	0.09
No of observations	45,053	35,635	26,302	17,536
SMEs
Effect	−1.28 (0.83)	−0.29 (1.06)	−0.25 (0.80)	−0.64 (1.27)
R²	0.19	0.13	0.12	0.10
No of observations	29,551	22,185	14,616	7,291
Large firms
Effect	−1.03 (0.91)	0.48 (1.19)	1.05 (0.85)	2.50 (1.73)
R²	0.19	0.11	0.07	0.06
No of observations	15,502	13,450	11,686	10,245
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

Table B2: Effect of 100 Basis Point Contractionary Shock on Share of Firms Innovating
By firm size, Beckers shock
	Year 0	Year 1	Year 2	Year 3
All firms
Effect	−4.38** (1.49)	−3.52** (1.55)	−0.03 (2.06)	5.51** (2.26)
R²	0.05	0.05	0.05	0.04
No of observations	45,151	35,705	26,342	17,545
SMEs
Effect	−5.60*** (1.44)	−6.44*** (1.13)	−3.87* (1.84)	−0.93 (1.67)
R²	0.05	0.05	0.05	0.05
No of observations	29,648	22,255	14,656	7,300
Large firms
Effect	−1.37 (3.01)	1.01 (2.65)	3.84 (2.64)	10.48** (3.99)
R²	0.03	0.02	0.03	0.03
No of observations	15,503	13,450	11,686	10,245
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

Table B3: Effect of 100 Basis Point Contractionary Shock on Share of Firms Innovating
By firm size, BT shock
	Year 0	Year 1	Year 2	Year 3
All firms
Effect	−1.75 (1.09)	−0.83 (1.40)	0.19 (0.97)	2.28 (1.69)
R²	0.05	0.05	0.05	0.04
No of observations	45,151	35,705	26,342	17,545
SMEs
Effect	−2.51 (1.50)	−2.16 (1.45)	−1.51 (1.22)	−2.10 (1.43)
R²	0.05	0.05	0.05	0.05
No of observations	29,648	22,255	14,656	7,300
Large firms
Effect	−0.16 (1.18)	0.47 (1.90)	2.02* (1.09)	4.94* (2.46)
R²	0.03	0.02	0.03	0.03
No of observations	15,503	13,450	11,686	10,245
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

Table B4: Effect of 100 Basis Point Contractionary Shock on Share of Firms Innovating
By firm size, levels shock
	Year 0	Year 1	Year 2	Year 3
All firms
Effect	0.12 (0.26)	−0.18 (0.42)	−0.21 (0.25)	−0.39 (0.44)
R²	0.05	0.05	0.05	0.04
No of observations	45,151	35,705	26,342	17,545
SMEs
Effect	0.22 (0.38)	0.05 (0.43)	0.19 (0.35)	0.81 (0.49)
R²	0.05	0.05	0.05	0.05
No of observations	29,648	22,255	14,656	7,300
Large firms
Effect	−0.11 (0.29)	−0.37 (0.53)	−0.59* (0.27)	−1.02 (0.63)
R²	0.03	0.02	0.03	0.03
No of observations	15,503	13,450	11,686	10,245
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

Table B5: Effect of 100 Basis Point Contractionary Shock on Share of Firms Innovating
By exporter status and firm size
	Year 0	Year 1	Year 2	Year 3
SMEs
Exporters
Effect	−3.84 (1.98)	−3.29 (1.94)	−0.16 (3.92)	4.07 (3.26)
R²	0.19	0.14	0.13	0.10
No of observations	7,733	5,788	3,847	2,009
Non-exporters
Effect	−2.24 (1.60)	−6.90*** (1.21)	−2.85 (1.88)	0.99 (1.34)
R²	0.19	0.13	0.10	0.09
No of observations	21,818	16,397	10,769	5,282
Difference by exporter status significant at:	na	na	na	na
Large firms
Exporters
Effect	3.47 (2.76)	4.76 (3.06)	5.91* (2.62)	9.73* (4.92)
R²	0.20	0.11	0.08	0.06
No of observations	10,241	8,946	7,825	6,895
Non-exporters
Effect	3.65 (2.98)	−1.49 (3.30)	3.12 (2.63)	9.79* (4.52)
R²	0.18	0.09	0.07	0.06
No of observations	5,261	4,504	3,861	3,350
Difference by exporter status significant at:	na	10 per cent level	na	na
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

Table B6: Effect of 100 Basis Point US Contractionary Shock on Share of Firms Innovating
By exporter status and firm size
	Year 0	Year 1	Year 2	Year 3
SMEs
All firms
Effect	−7.00 (4.52)	−10.33** (3.80)	−9.85* (5.22)	−21.19 (16.05)
R²	0.19	0.14	0.12	0.10
No of observations	29,551	22,185	14,616	7,291
Exporters
Effect	−11.44* (5.61)	−11.76 (6.85)	−18.81** (6.92)	−16.62 (19.25)
R²	0.19	0.14	0.13	0.10
No of observations	7,733	5,788	3,847	2,009
Non-exporters
Effect	−5.48 (4.59)	−9.59** (4.58)	−6.93 (5.41)	−25.36 (18.18)
R²	0.19	0.12	0.10	0.09
No of observations	21,818	16,397	10,769	5,282
Difference by size significant at:	na	na	na	na
Large firms
All firms
Effect	−3.66 (9.19)	−11.49* (6.05)	−5.59 (5.71)	−9.62 (8.97)
R²	0.19	0.11	0.07	0.06
No of observations	15,502	13,450	11,686	10,245
Exporters
Effect	−5.36 (9.22)	−10.66 (6.44)	−5.90 (7.54)	−12.94 (10.87)
R²	0.20	0.11	0.08	0.06
No of observations	10,241	8,946	7,825	6,895
Non-exporters
Effect	−0.14 (10.20)	−14.17 (7.93)	−5.39 (4.51)	−2.67 (7.54)
R²	0.18	0.09	0.07	0.06
No of observations	5,261	4,504	3,861	3,350
Difference by size significant at:	na	na	na	na
Notes: Significance assessed using T ‐ distribution with t – n degrees of freedom as suggested by Cameron and Miller (2015) to account for small number of clusters, where t is sample length and n is number of coefficients. All regressions include controls for industry, (lag) GDP growth, (lag) inflation, (lag) growth in the exchange rate, (lag) turnover growth and (lag) employment, and lag of the shock and dependent variable. *, and * denote statistical significance at the 1, 5 and 10 per cent levels, respectively. Standard errors are shown in parentheses and are clustered at an annual level.

RDP 2024-01: Do Monetary Policy and Economic Conditions Impact Innovation? Evidence from Australian Administrative Data Appendix B: Additional Regression Results